Marine Radio Operators Handbook by Australian Maritime College

Marine Radio Operators Handbook

Radio Distress Calling

Used Only if in grave or imminent danger • MAYDAY MAYDAY MAYDAY • tHIS IS (Name of vessel and call sign - spoken 3 times) • MAYDAY > Name of vessel & call sign

> Vessel’s position in degrees & minutes of latitude and longitude or bearings & distance relative to a well known geographical feature > Nature of distress & the kind of assistance required > Any other information which may assist rescuers - number of persons on board, description of vessel, liferaft, EPIRB Allow a short period for reply. If no answer, activate your EPIRB & repeat the distress call working through all the distress frequencies. If contact is made, inform the receiver that you have activated your EPIRB. DO NOT TURN EPIRB OFF until told to do so by rescue authority. Australian Maritime Safety Authority

MARINE RADIO FREQUENCIES for small craft

DISTRESS SAFETY AND CALLING 4125 kHz

6215 kHz 8291 kHz

VHF Channel 16

Monitored by State / Territory services 24 hours 7 days a week

Monitored by State / Territory services in certain areas 24 hours 7 days a week

WEATHER FORECASTS AND WARNINGS VMW Wiluna

2056kHz

4149 kHz

6230 kHz

8113 kHz

12362 kHz

16528 kHz

VMC Charleville

2201 kHz

4426 kHz

6507 kHz

8176 kHz

12365 kHz

16546 kHz

VHF Channel 67

Available in certain areas. Refer to State / Territory marine authorities for details

Broadcast schedule

Available at: www.bom.gov.au/marine

VHF Channel 67 HF 8176 kHz

Marine Radio

Available in certain areas. Refer to State / Territory marine authorities for details Refer to State / Territory marine authorities for schedule details

Operators Handbook

2017

NAVIGATION WARNINGS

Marine Radio

Operators Handbook MRO Handbook 2017

AMC SEARCH

Commercial arm of the Australian Maritime College

AMC Search Ltd (AMCS) is the commercial arm of the Australian Maritime College. Since its inception in 1985, AMCS has grown into a highly specialised and customer focused organisation, providing maritime related training and consultancy for a wide range of international and Australian organisations. AMCS offers a wide range of short courses, both scheduled and to client’s specific requirements. AMCS markets and administers short courses on behalf of AMC which retains academic control of all courses. AMC’s mandatory short courses meet the requirements of the Australian Maritime Safety Authority (AMSA) and comply with the International Maritime Organisation’s STCW78 (as amended). Training programs, some of which can be provided on client premises, include: IALA APPROVED VESSEL TRAFFIC SERVICES • V-103/1: VTS Basic Operator Training • V-103/2: VTS Supervisor Training • V-103/4: On the Job Instructor Training • Local Port Services (LPS) DYNAMIC POSITIONING (DP) • DP Basic (Induction) • DP Advanced (Simulator) DECK OFFICER REVALIDATION GMDSS COMMUNICATIONS AND RENEWAL SEA SAFETY AND SURVIVAL • Certificate of Sea Safety Training • Certificate of Proficiency in Survival Craft • Fast Rescue Craft Operator’s Course • Crisis Management and Human Behaviour (IMO 1.29) • Crowd Management (IMO 1.28) FIRE FIGHTING • Fire Prevention and Fire Fighting • Advanced Fire Fighting AMC IS A SPECIALIST INSTITUTE OF THE UNIVERSITY OF TASMANIA

MEDICAL CARE • Medical First Aid on board Ship • Medical Care on board Ship SHIP SECURITY OFFICER OFFSHORE • Ballast Stability Class B • Mooring Operations PORT AND TERMINAL OPERATIONS • Operational and Commercial Aspects of Stevedoring and Terminal Operation • Safe Bulk Loading Practice • Ship Planners • Bulk Carrier Operations • Dockmaster Training TANKER SAFETY • Tanker Familiarisation • Combined Advanced Oil and Chemical Tanker Safety • Advanced Liquefied Gas Tanker Operations INTEGRATED MARINE SIMULATOR COURSES • Automatic Radar Plotting Aids (ARPA) • Electronic Chart Display Information System (ECDIS) • Bridge Resource Management (BRM) • High-Speed Navigation UPGRADES • Large Tonnage Vessel Upgrade • Chief Integrated Ratings

Course information, including scheduled dates, fees and content is available at: www.amcsearch.com.au

ÂŠ Australian Communications and Media Authority 2002. ISBN 978-1-86295-879-1 First published for the Postmaster-Generalâ&#x20AC;&#x2122;s Department 1969 Revised edition 1971 Published for the Department of Communications 1978 Revised editions 1981, 1984 Revised edition for the Department of Transport and Communications 1987 Reprinted April, June 1988 Reprinted 1990 Reprinted 1991 Revised edition 1992 Revised edition for the Spectrum Management Agency 1993 Revised 1993 Revised 1996 Revised edition for the Australian Communications Authority 1998 Revised Dec 1998 Reprinted June 1999 Revised April 2000 Revised edition for the Australian Maritime College 2002 Reprinted September 2003 Revised edition for the Australian Maritime College 2006 Revised 2008 Reprinted 2012 Revised 2012 Revised 2013 Reprinted 2013 Revised 2015

Reprinted 2017

This work is copyright. Apart from any use as permitted under the Copyright Act 1968, no part may be produced by any process without prior written permission from the Australian Maritime College (AMC). Requests and enquiries concerning reproduction and rights should be addressed to the Manager, Office of Maritime Communications, Australian Maritime College, Locked Bag 1394, Launceston Tasmania 7250. Produced by the Office of Maritime Communications, Australian Maritime College as the delegate of the ACMA for the purposes of issuing Marine Radio Operators Certificates of Proficiency.

AUSTRALIAN MARITIME COLLEGE

Foreword This handbook is intended for the guidance of radio operators: (a) o n Australian vessels which are compulsorily fitted with marine radiotelephony, marine radiotelephony with digital selective calling capability, and/or Inmarsat satellite communications, in accordance with State or Territory government legislation; or (b) on Australian vessels which are voluntarily fitted with marine radiotelephony, marine radiotelephony with digital selective calling capability, and/or Inmarsat satellite communications; or (c) at Limited Coast Stations, particularly those operated by marine rescue organisations. It is the recommended textbook for candidates undertaking examination for the Long Range Operator Certificate of Proficiency (LROCP) and the Short Range Operator Certificate of Proficiency (SROCP). Procedures and requirements outlined in the handbook are based on the International Radio Regulations formulated by the International Telecommunication Union (ITU), on provisions governing the use of radio transmitters in Australia laid down in the Radiocommunications Act 1992, and on radiocommunications station licence conditions set by the Australian Communications and Media Authority (ACMA). Careful observance of the procedures covered by this handbook is essential for the efficient exchange of communications in the marine radiocommunications service, particularly when the safety of life at sea is concerned. Special attention should be given to those sections dealing with distress, urgency and safety. It should be noted that no provision of this handbook, the International Radio Regulations, or the Radiocommunications Act 1992, prevents the use by a vessel in distress of any means at its disposal to attract attention, make known its position and obtain help. Similarly, no provision of this handbook, the International Radio Regulations, or the Radiocommunications Act 1992, prevents the use by vessels engaged in search and rescue operations of any means at their disposal to assist a vessel in distress. This edition of the Marine Radio Operators Handbook reďŹ&#x201A;ects the new arrangements for Maritime Communication Stations from 1 July 2002. These arrangements include substantial changes to the frequencies monitored by these stations for distress and safety. This edition also includes information regarding MASTREP, which replaces AUSREP as the ship reporting system in Australian waters. It also contains information about the Global Maritime Distress and Safety System (GMDSS) marine communications techniques which are available for use by small vessels in Australia. The system uses advanced technology and automation to ensure that search and rescue authorities, as well as ships in the vicinity of an emergency, are alerted reliably and rapidly. Both satellite and terrestrial communications form essential components of the GMDSS. Information about obtaining the Marine Satellite Communications endorsement qualification (MSCe or Satcom) for operators with Inmarsat satellite communications (compulsorily or voluntarily fitted) is available on the web at www.amc.edu.au/handbooks. The Australian Maritime College acknowledges the contribution of the ACMA, Australian Maritime Safety Authority (AMSA) and the McMurdo Group (chart image page 61).

MARINE RADIO OPERATORS HANDBOOK

CONTENTS Chapter 1 General............................................................................1

Section 18

121.5 MHz Component of the 406 MHz EPIRB .............54

Section 1

Ship Station Operators.................................................2

Section 19

The 406 MHz ePIRB ...................................................54

Use of Ship Radio Stations...........................................5

Section 20

Care and Maintenance of ePIRBs ................................56

Section 2

Revision Questions .....................................................58

Section 3 Monitoring of Radiotelephony Frequencies (Watchkeeping)...........................................................8 Section 4

Frequencies - General Information................................9

Chapter 8 Search And Rescue Transponders (SARTs) .................59

Revision Questions ....................................................11

Section 21 Search and Rescue Transponders...............................60 Revision Questions....................................................61

Chapter 2 Radio Propagation........................................................12 Section 5 Frequency Characteristics..........................................13 Revision Questions ...................................................16

Chapter 9 Search and Rescue in Australia...................................62 Section 22

Search and Rescue - General Information ..................63 Revision Questions....................................................65

Chapter 3 M aritime Communication, Coast Radio and Limited Coast Stations.................................................17 Section 6 Maritime Communications Stations.............................18

Chapter 10 Distress, Urgency And Safety Communications Using Radiotelephony................................................66

Section 7

Section 23 Priority Calls - General Information.............................67

State and Northern Territory HF (Coast Radio Stations) and VHF Stations ......................................................19

Section 8 Limited Coast Stations...............................................21 Section 9

VHF Marine Repeaters ..............................................22 Revision Questions ...................................................23

Chapter 4 Power Supplies............................................................24 Section 10 Care And Maintenance Of Batteries............................25

Section 24

Alarm Signals............................................................67

Section 25 Distress Communications...........................................68 Section 26

Urgency And Safety Signals........................................73 Revision Questions ...................................................76

Chapter 11 Operating Procedures for Routine Communications and Public Correspondence ..........78

Revision Questions....................................................29

Section 27 Routine Calling and Replying Procedures for Radiotelephony.........................................................79

Chapter 5 Marine Radiocommunications Equipment...................30

Revision Questions ...................................................81

Section 11 Types of Marine Radio Equipment...............................31 Section 12 Component Parts of Marine Radio Equipment..............32 Section 13

Transceiver Controls..................................................33

Section 14 General Care and Maintenance of Marine Radio Equipment................................................................34 Section 15

Faults in Marine Radio Equipment..............................35 Revision Questions ...................................................37

Chapter 6 Digital Selective Calling...............................................38 Section 16 General Information...................................................39 Revision Questions ....................................................50 Chapter 7 E mergency Position Indicating Radio Beacons (EPIRBs) ..........................................................52 Section 17

Emergency Position Indicating Radio Beacons (ePIRBs) ......................................................53

Chapter 12 Information For Vessels Proceeding Overseas...........82 Section 28

General Information ..................................................83

Appendices ................................................................................85 Appendix 1

Qualifications Examination Syllabi............................86

Appendix 2

Sample Format for a Radio Logbook Page...................91

Appendix 3

Frequencies for use by Ship Stations..........................92

Appendix 4 Table of Transmitting Frequencies in the VHF Maritime Mobile Band...................................97 Appendix 5

Phonetic Alphabet...................................................101

Appendix 6

Standard Marine Communication Phrases.................103

Appendix 7

Contact Details........................................................105

Appendix 8

Glossary of Terms and Abbreviations.........................106

Index

..............................................................................108 AUSTRALIAN MARITIME COLLEGE

III

MARINE RADIO OPERATORS HANDBOOK

CHAPTER 1

General

AUSTRALIAN MARITIME COLLEGE

Section 1

Ship Station Operators

1. Operators’ Qualifications 1.1 Australia is a member of the International Telecommunication Union (ITU). This body regulates radio frequency usage, and the operations and use of radiocommunications equipment on a world-wide basis. 1.2 Operators of ship stations, other than those operating exclusively in the 27 MHz marine band, must possess a certificate of proficiency issued in accordance with ITU regulations and the Australian Radiocommunications Act 1992, or a certificate considered to be of an equivalent or higher standard. 1.3 Operators on vessels that are subject to State or Territory legislation should ensure that they are qualified under that legislation. 1.4 Provided the ship radio station is under the control of a person holding a relevant certificate, persons other than the holder of the certificate may operate the equipment. 1.5 Operators of ship radio stations using equipment operating exclusively in the 27 MHz marine band are exempt from operator qualification requirements. However, in the interests of safety, ACMA strongly recommends that these operators qualify themselves with at least the Short Range Operator Certificate of Proficiency. 1.6 Operators of Limited Coast Stations using VHF and/or MF/HF marine bands are required to hold a certificate of proficiency. The minimum qualification is relevant to the equipment fitted at the station and is shown in the table on the following page. 1.7 Holders of the Restricted Radiotelephone Operators Certificate of Proficiency (RROCP), and the earlier 3rd Class Commercial Operators Certificate of Proficiency will continue to be legally qualified even though their radiocommunications equipment may incorporate digital selective calling facilities. However, such persons will need to additionally qualify for the Marine Satellite Communications endorsement if operating Inmarsat C equipment. 1.8

Operators on vessels which are compulsorily equipped with radio equipment under the provisions of the Commonwealth Navigation Act 2012, are required to hold a minimum of the Global Maritime Distress and Safety System General Operators Certificate of Proficiency, issued by the Australian Maritime Safety Authority (AMSA). Further details of this qualification may be obtained from any AMSA office.

Renaming of the Marine Radio Operators Certificates of Proficiency As of mid-2015 the names of the marine radio operator’s certificates of proficiency changed. The renaming of the MROCP and MROVCP has been changed to reflect ITU terminology and align the naming of Australian certificates with the common world practice. Marine radio certificates are now issued under the following new names: 1. Short Range Operator Certificate of Proficiency – SROCP (replaces MROVCP) 2. Long Range Operator Certificate of Proficiency – LROCP (replaces MROCP) The new terminology more clearly reflects the nature and limitations of these internationally recognised certificates and their equivalency with overseas certificates.

MARINE RADIO OPERATORS HANDBOOK

The minimum requirements for operators on vessels other than those subject to the Commonwealth navigation Act 2012 are: Operator Certificates Long Range Operator Certificate of Proficiency (current) Marine Radio Operators Certificate of Proficiency Restricted Radiotelephony Operators Certificate of Proficiency 3rd Class Commercial Operators Certificate of Proficiency

LROCP MROCP RROCP 3COCP

Short Range Operator Certificate of Proficiency (current) Marine Radio Operators VHF Certificate of Proficiency

SROCP MROVCP

*A person must be the holder of one of the above marine radiotelephony qualifications to obtain a marine satellite endorsement. Marine Satellite Communications Endorsement (current) Marine Satellite Communications Certificate of Endorsement

Equipment Carried on Vessel

MSCE MSCCE

Marine Radio Qualifications Required to Operate Marine Radio and Marine Satellite Equipment (excluding GMDSS which is a higher qualification) LROCP

MROCP

RROCP

3COCP

MROVCP

SROCP

VHF Marine Radiotelephony Equipment (with or without digital selective calling facilities)

YES or

YES

MF/HF Marine Radiotelephony Equipment (with or without digital selective calling facilities)

YES or

YES

Inmarsat C or Fleet 77 Equipment

YES or

YES

MSCE

YES and YES or

MSCCE

YES

EXAMINATION FOR THE LONG RANGE OPERATOR CERTIFICATE OF PROFICIENCY, THE SHORT RANGE OPERATOR CERTIFICATE OF PROFICIENCY AND THe MARINe SATeLLITe COMMUNICATIONS ENDORSEMENT

2.1 Currently, examination and certification services for the two certificates and the satellite endorsement are provided through the Office of Maritime Communications (OMC) at the Australian Maritime College on behalf of the Australian Communications and Media Authority. In this handbook, the Office of Maritime Communications will be referred to as the OMC, the Australian Maritime College the AMC, and the Australian Communications and Media Authority as the ACMA. 2.2 Syllabi for the two certificates are shown in Appendix 1 of this handbook. Examination questions will primarily be based on symbolised sections as follows: a) Short Range Operator Certificate of Proficiency (SROCP) b) Long Range Operator Certificate of Proficiency (LROCP) For the satellite endorsement syllabus refer to the Maritime Communications Satellite Systems and Equipment Handbook available for printing at: http://www.amc.edu.au/industry/omc/handbooks-and-revision-questions . 2.3

An examination will normally consist of a written exercise.

2.4

At the discretion of the OMC, candidates may undertake an oral rather than a written test.

2.5

Persons wishing to upgrade their qualification must contest the entire examination relevant to the desired certificate. ‘Conversion’ examinations are not available.

AUSTRALIAN MARITIME COLLEGE

CANDIDATe eLIGIBILITY AND RePLACeMeNT OF OPeRATORS CeRTIFICATeS

3.1 Current legislation does not permit the issue of a certificate of proficiency to a candidate under the age of sixteen. Candidates must be sixteen years of age before being accepted for examination. 3.2

Certificates of proficiency and endorsements will be issued to successful candidates.

3.3

All candidates are required to produce proof of identity and age at the time of examination.

3.4 If an operatorâ&#x20AC;&#x2122;s certificate or endorsement is lost, mutilated or destroyed, or a change of name has occurred, the holder may obtain a replacement by submitting a Replacement Application form (refer www.amc.edu.au/marineradio). 3.5 where issue of a replacement certificate or endorsement is required because of damage or change of name, the original certificate or endorsement should accompany the application. In the case of change of name, documentary proof of the change should be included: for example, a marriage certificate or deed poll document. 3.6 A fee is charged for the replacement of a certiďŹ cate or endorsement. 3.7 It is in the interests of candidates applying for a replacement for a lost certificate or endorsement to provide information regarding the place and approximate date of original issue.

APPLICATION FOR exAMINATION

4.1 An application to be examined for a certificate or endorsement can be made to the OMC. 4.2

examinations for the marine radio operator qualifications are conducted by appointment and may be held at any location suitable for examination purposes. Many marine rescue organisations, boating clubs and colleges of technical and further education (TAFe) conduct examinations on behalf of the OMC. In special circumstances examinations may be held at ACMA offices.

4.3

examinations for the Marine Satellite Communications endorsement cannot be conducted at an ACMA office and are only available at organisations with suitable Inmarsat equipment available for training.

4.4

examination fees are charged.

OPeRATOR TRAINING

5.1

Many marine rescue organisations, boating and fishing clubs, maritime colleges and some colleges of technical and further education (TAFe) provide training courses leading to the marine radio operator qualifications.

5.2

Some maritime and TAFe colleges provide training courses leading to the Marine Satellite Communications endorsement.

5.3

The ACMA or the OMC may be able to provide information about local training organisations.

5.4

Persons using this handbook as a study guide should note that much of its content is non-examinable. Careful reference should be made to the detailed examination syllabi shown in Appendix 1.

MARINE RADIO OPERATORS HANDBOOK

Section 2 6. 6.1

Use of Ship Radio Stations

Ship Station Licences Under the Radiocommunications Act 1992, the operation of marine radio equipment aboard any Australian vessel must be authorised by a licence.

6.2 In the case of shipboard radio equipment operating in the 27 MHz and VHF marine bands, this authorisation is provided to any person by means of a Maritime Ship Station Class Licence. The Class Licence does not have to be applied for and is free of charge. The Maritime Ship Station Class Licence also authorises the operation of ship’s radar equipment and on-board UHF marine communications equipment. 6.3 Frequencies authorised for use, technical and general requirements for the operation of 27 MHz, VHF, radar and UHF on-board marine equipment are shown in the Radiocommunications (Maritime Ship Station - 27 MHz and VHF) Class Licence 2001. Operators of this equipment are legally obliged to observe the conditions set out in this document. Copies of the Class Licence may be obtained from the ACMA’s Internet site (http://www.acma.gov.au) or from any ACMA office. 6.4

The operation of shipboard Inmarsat satellite radio terminals is authorised by another Class Licence. The Class Licence is free of charge and does not need to be issued individually.

6.5 Technical and general requirements for the operation of shipboard Inmarsat terminals are shown in the Radiocommunications (Communications with Space Object) Class Licence 1998. Operators of this equipment are legally obliged to observe the conditions set out in this document. Copies of the Class Licence may be obtained from ACMA’s Internet site (http://www.acma.gov.au) or from any ACMA regional office. 6.6

The operation of shipboard radio equipment operating in MF/HF marine bands is not authorised by a Class Licence. Individual apparatus licences, which attract a fee, are required.

6.7 Application for a MF/HF Ship Station (Class B) Licence may be made in person at any ACMA regional office. Alternatively, a completed application form together with the licence fee may be submitted by mail or through the ACMA’s on-line licensing service. 6.8

A MF/HF marine licence shows the station licensee, and the name and the call sign of the vessel. Frequencies authorised for use, technical and general requirements are detailed in the ACMA’s Radiocommunications Licence Conditions (Maritime Ship Licence) Determination. The station licensee is legally obliged to observe licence conditions set out in this document. Copies of the Determination may be obtained from the ACMA’s Internet site (http://www.acma.gov.au).

6.9

By mutual agreement, a MF/HF Ship Station (Class B) Licence may be transferred from one person or organisation to another person or organisation. However, restrictions may apply where the original licence holder is exempt from licence fees or pays a concessional licence fee. Further information and applications for transfer are available at http://www.acma.gov.au. A fee for licence transfer applies.

6.10 A MF/HF Ship Station (Class B) Licensee should contact the ACMA if: a) a new vessel with radiocommunications equipment is purchased, or b) there is a change of the licensee’s address. 6.11 Operators of shipboard radio equipment operating in the VHF and MF/HF marine bands, and operators of most Inmarsat satellite radio terminals, are required to hold appropriate personal qualifications. Details of the minimum qualification requirements are shown in paragraph 1. 6.12 Neither class licences nor a MF/HF ship station (class B) licence authorises the operation of a ‘home base’. Except in special cases, marine radio equipment in private residences will not be authorised by the ACMA.

Licensing of Other Shipboard Radiocommunications Equipment

7.1

The Radiocommunications Act 1992 requires that the possession and operation of all radio transmitters be authorised by a licence. Licences are not required for the operation of satellite navigation receivers (GPS).

7.2

Amateur band transmitting equipment installed on a vessel must be licensed separately. Licences for amateur band equipment will not be issued to any person who does not hold an appropriate amateur operator’s certificate of proficiency.

7.3 Emergency Position Indicating Radio Beacons (EPIRBs), mobile phones and Citizens Band (CB) transceivers aboard vessels are authorised by Class Licences issued under the Radiocommunications Act 1992, and do not require individual licensing.

Authority of the Master

8.1 A ship radio station and the service it provides is placed under the authority of the master, skipper, or the person responsible for the safety of the vessel.

AUSTRALIAN MARITIME COLLEGE

Inspection of Ship Stations

9.1 ACMA officers may ask that a ship radio station be made available for inspection to ascertain that licence conditions are being met. 9.2

Station licensees of vessels travelling overseas should be aware that the competent authorities in any country where the vessel may visit may ask to inspect the ship station licence and the radio qualification of the operator. Failure to produce these documents may result in an inspection by these authorities to satisfy themselves that the radio station conforms to the requirements of the International Radio Regulations. Station licensees of vessels proceeding overseas carrying 27 MHz, VHF and Inmarsat marine radio equipment should carry copies of the relevant class licences.

10. Secrecy of Communications 10.1 Under the International Radio Regulations, an operator and any other person who becomes acquainted with the contents of a radiotelegram, radiotelephone call or radiotelex call is placed under an obligation to preserve the secrecy of such information. 10.2 Secrecy restrictions do not apply to distress, urgency or safety alerts or messages, or any message that is addressed to â&#x20AC;&#x2DC;all stationsâ&#x20AC;&#x2122;.

11. Distress Calls 11.1 The obligation to accept distress alerts, calls and messages is absolute and such messages must be accepted with priority over all other radiocommunications.

12. False or Deceptive Distress, Urgency or Safety Signals 12.1 The transmission of false or deceptive distress, urgency or safety signals is strictly forbidden. Extremely severe penalties, including imprisonment, exist under the Radiocommunications Act 1992 for any person found guilty of making such a transmission.

13. Unnecessary Transmissions 13.1 Transmissions should be as brief as possible consistent with the legitimate requirement for which a station is licensed. Non essential remarks, bad language and unnecessary conversations should be avoided. 13.2 It is an offence under the Radiocommunications Act 1992 to use a transmitter in a manner that is likely to cause a reasonable person to be seriously alarmed or affronted, or for the purpose of harassing a person.

14. Avoidance of Interference 14.1 Operators should take every precaution to ensure that their transmissions will not cause harmful interference to other stations. It is important that all operators: - listen before transmitting, to ensure the frequency is not already in use; - use the minimum transmitting power necessary for reliable communications; - strictly observe the purpose for which a frequency is assigned; and - keep test signals to a minimum.

15. Documents to be Held On Board 15.1 In addition to the station licence and operatorâ&#x20AC;&#x2122;s certificate, a copy of this handbook and material suitable for use as a radio log book should be held aboard a vessel. 15.2 It is also recommended that information about the operating hours of, and frequencies monitored by, Limited Coast Stations in the areas the vessel is travelling through should be available aboard to facilitate radio communications. This information should be available from the relevant State or Territory authority or volunteer marine rescue organisation.

MARINE RADIO OPERATORS HANDBOOK

16. Log Keeping 16.1 Operators should keep a record of all distress alerts and messages transmitted or received. Particulars should include the station or stations with which the messages were exchanged, the frequencies used, and the date and times of transmission and reception. 16.2 Log keeping requirements for vessels compulsorily fitted with radio equipment under Commonwealth or State legislation may be found in the relevant regulations. 16.3 A suggested format for a radio log book page is shown in Appendix 2.

17. Ship Station Call Signs and Identities 17.1 A MF/HF ship station (class B) licence issued by the ACMA will show the official international call sign allocated to the vessel. 17.2 Each call sign is unique and is formed in one of two ways: - three letters, followed by four numbers; or - four letters. 17.3 In conformity with Australia’s international call sign allocation, the first two letters will always be AX, VZ, VH, or in the series VJ to VN. 17.4 Four letter call signs are allocated only to vessels subject to compulsory radio installation under the Navigation Act 2012 (generally commercial vessels making interstate and overseas voyages). 17.5 On request, a Maritime Mobile Service Identity (MMSI) will be issued by the Australian Maritime Safety Authority (AMSA) to a ship station licensee with an installation capable of digital selective calling techniques. See the AMSA website for more information. (https://www.amsa.gov.au/forms-and-publications/AMSA89.pdf). 17.6 Transmissions from radio equipment aboard survival craft should be identified by the use of the parent vessel’s call sign followed by two numbers (not 0 or 1). The numbers ‘22’ are normally used. 17.7 Stations operating exclusively on VHF marine bands now operate under a Class Licence and a radio call sign is not required (see paragraph 6.3). Operators should use the name of the vessel or other suitable means of identification. Vessels which were licensed prior to 1 July 2001 may continue to use the call sign issued by the then ACA or its predecessor, provided that licensee contact and vessel details remain unchanged.

18. Ship Station Identification 18.1 Transmissions without identification are forbidden. 18.2 A MF/HF ship station must be identified either by the use of the official international call sign allocated by ACMA or by the ship’s name or, preferably, by a combination of both. If using digital selective calling, the vessel’s MMSI will automatically be inserted into the transmission. 18.3 Ship stations operating exclusively on 27 MHz and/or VHF marine bands may use the vessel’s name or other suitable identification. Vessels which were licensed prior to 1 July 2001 may continue to use the call sign issued by ACMA while the ownership of the vessel, licensee contact and vessel details remain unchanged. 18.4 If transmitting radiotelephony distress, urgency or safety messages, or if involved in search and rescue operations, the utmost care must be taken to avoid confusion between vessels of the same or similar names. 18.5 If transmitting radiotelephony distress, urgency or safety messages, or if involved in search and rescue operations, the use of an official call sign is necessary to avoid confusion between vessels of the same or similar names. If no call sign is available then the full name or registered number followed by the port at which the name or registration is recorded can assist in positively identifying the vessel. If the vessel is not registered then other identification such as the trailer or parked vehicle registration number followed by the ramp location where the vehicle is parked can help to identify the owner in an emergency.

AUSTRALIAN MARITIME COLLEGE

Section 3 Monitoring of Radiotelephony Frequencies (Watchkeeping) 19. Monitoring of Radiotelephony Distress and Calling Frequencies 19.1 Ship stations are encouraged to keep maximum practicable watch on the radiotelephony distress and calling frequencies appropriate to their location and the type of marine radiocommunications equipment fitted. 19.2 Watchkeeping requirements for vessels compulsorily fitted with radio equipment under State legislation may be found in the relevant regulations. 19.3 Aural watchkeeping has been replaced by digital selective calling watchkeeping by maritime communication stations.

20. Radiotelephony Silence Periods 20.1 The international regulations no longer require silence periods to be observed on the distress and calling frequencies. Those vessels that come under the Safety of Life at Sea regulations maintain a continuous watch on VHF DSC and a listening watch on Channel 16. 20.2 It is still recommended that vessels operating on the MF/HF frequencies observe silence periods, so that operators experiencing communications difficulties on these frequencies can be heard. Operators wishing to observe silence periods should be aware that they start on the hour and half-hour and last for three minutes. 20.3 An accurate clock is also useful to record the time at which communication occurred, particularly in emergency situations. 20.4 Silence periods are not observed on the MF/HF DSC frequencies or the VHF DSC channel.

O5 O3

RADIOTELEPHONY SILENCE PERIODS

40 35

25 30

MARINE RADIO OPERATORS HANDBOOK

Section 4

Frequencies - General Information

21. Use of Frequencies 21.1 A ship station may use only the frequencies that are authorised for its particular activity (for example, pleasure, professional fishing, etc.). These frequencies are detailed in ACMAâ&#x20AC;&#x2122;s Radiocommunications Licence Conditions (Maritime Ship Licence) Determination No.1 of 1997 and the Radiocommunications (Maritime Ship Station - 27 MHz and VHF) Class Licence 2001. (See Appendix 3.) except in the case of distress, the use of any other frequency is not permitted. Offenders may be subject to penalties under the provisions of the Radiocommunications Act 1992. 21.2 It is important that frequencies are used only for the purpose for which they are assigned; for example, a frequency shown for communicating with Maritime Communication Stations or Limited Coast Stations must not be used for communicating with other vessels.

22. Control of Communications 22.1 During routine communications between a ship station and a maritime communication or limited coast station, the Maritime Communication Station or Limited Coast Station controls the working. In order that communications may be exchanged efficiently, all instructions given by Maritime Communication Station and Limited Coast Stations should be obeyed without delay. However, this does not prevent a ship station making a suggestion concerning a working frequency or other on-air operations. 22.2 Ship stations must not interfere with Maritime Communication Station or Limited Coast Station communications. 22.3 During routine communications between ship stations, the called ship station controls the subsequent exchange of communications.

23. Test Transmissions 23.1 when it is necessary for a ship station to transmit signals for testing or making technical adjustments that are likely to interfere with the working of a nearby Maritime Communication Station or Limited Coast Station, the prior consent of that station should be obtained. 23.2 All testing signals should be kept to a minimum, particularly on frequencies used for distress, urgency and safety purposes. 23.3 The requirement to minimise testing does not prevent a ship station from making a brief transmission to a local Limited Coast Station to confirm correct equipment operation before the vessel puts to sea.

24. Radiotelephony Calling and Working Frequencies 24.1 Radiotelephony frequencies assigned to ship stations, Maritime Communication Stations and Limited Coast Stations are categorised as either calling or working: - calling frequencies are used to establish communications with Maritime Communication Stations, Limited Coast Stations and other ship stations; and - working frequencies are used to exchange messages relating to the operation and movement of vessels and to conduct public correspondence communications. 24.2 All stations may establish communications with the desired station by using a radiotelephony calling frequency. Once communications have been established, communications should be transferred to a working frequency and the messages exchanged. At the conclusion of working, stations should resume monitoring the appropriate calling frequency. 24.3 The majority of radiotelephony calling frequencies are also assigned for distress, urgency and safety calling purposes. This enables ship stations to monitor a single frequency for routine calling from other stations and for safety of life at sea purposes. 24.4 Limited Coast Stations may monitor several of these dual-purpose frequencies. Maritime Communication Stations only monitor HF digital selective calling frequencies. 24.5 It is essential that calling frequencies are not used for the exchange of routine messages.

25. Radiotelephony Calling Frequencies 25.1 The main radiotelephony frequencies for establishing routine communications with an Australian Limited Coast Station or another ship are: - 2182, 12 359 and 16 537 kHz in the MF/HF marine bands; - Channels 16 and 67 in the VHF marine band.

AUSTRALIAN MARITIME COLLEGE

25.2 Ship stations wishing to attract the attention of Australian Maritime Communication Stations must use digital selective calling (DSC) equipment and dedicated HF DSC frequencies for distress, urgency and safety alerting: 4207.5, 6312, 8414.5, 12 577, and 16 804.5 kHz. 25.3 Certain other radiotelephony frequencies are monitored by some Limited Coast Stations and may be used for establishing communications. Details of these frequencies are shown in Appendix 3. 25.4 In Australia, all radiotelephony distress and calling frequencies or channels are used in the SIMPLEX mode with transmission and reception taking place on the same frequency, enabling all stations to monitor a single frequency (See paragraph 36.1.) 25.5 VHF channel 70 may be used for establishing routine communications using digital selective calling techniques. Further information may be found in paragraphs 86.1 - 86.4.

26. Radiotelephony Working Frequencies 26.1 Details of radiotelephony frequencies to be used for working with Australian Maritime Communication Stations are shown in Appendix 3. 26.2 Details of radiotelephony frequencies to be used for working with Limited Coast Stations and other vessels are shown in Appendix 3. 26.3 The frequencies used by the Bureau of Meteorology for transmission of weather forecasts and warnings should no longer be used as working frequencies, even when weather broadcasts are not being made. The weather broadcasts are now on an automatic schedule. There will not be any announcement (on a calling frequency) that the broadcast will start. There is no provision for the Bureau of Meteorology to monitor the frequency prior to the commencement of the broadcast. 26.4 Many of the frequencies designated for working with Maritime Communication Stations are allocated in pairs, with transmission and reception taking place on different frequencies; i.e. DUPLEX. (See paragraph 36.2). 26.5 All ship to shore and shore to ship working frequencies in the HF and VHF marine bands are allocated an international channel number. In the interests of brevity and accuracy, ship station operators are encouraged to refer to channel numbers rather than frequencies. Details of channel numbers may be found in the ITU radio regulations.

27. Phonetic Alphabet and Figure Code 27.1 In cases of doubtful reception or difficult conditions when passing any radiotelephony message, ship station operators should spell out words and figures using the International Phonetic Alphabet and figure code. Details may be found in Appendix 5. 27.2 Use of the phonetic alphabet is particularly important when handling radiotelephony messages concerning the safety of life at sea.

28. INFORMATION FOR MARITIME COMMUNICATION STATIONS, COAST RADIO STATIONS AND LIMITED COAST STATIONS 28.1 Ship station operators are encouraged to provide departure, positional and arrival information to a Maritime Communication Station, Coast Radio Station or Limited Coast Station operated by a marine rescue organisation. 28.2 If undertaking a lengthy voyage, a position report should be passed daily to a Maritime Communication Station, Coast Radio Station or Limited Coast Station operated by a marine rescue organisation. 28.3 This information may provide valuable assistance to search and rescue authorities should an emergency situation occur.

29. Restrictions to the Use of Radio Equipment on Ships 29.1 Ship station licences authorise the use of radio equipment aboard vessels at sea or on inland waters only. 29.2 However, if a vessel is anchored or moored, the use of the shipâ&#x20AC;&#x2122;s radio station to communicate with the nearest Maritime Communication Station, Coast Radio Station or Limited Coast Station is permitted, providing the lowest practicable transmitting power is used. 29.3 Due to the risk of explosion, radio transmissions must not be made when a vessel is loading fuel, or when loading or discharging any flammable cargo. 29.4 Some overseas communications authorities forbid the use of marine communications equipment whilst in port limits.

MARINE RADIO OPERATORS HANDBOOK

Chapter 1 General – Revision Questions SECTION 2: Use of Ship Radio Stations 6.12 Is a radio licence required for a 'home base'? 8.1

13.1 What is considered as unacceptable with regards to radio transmissions?

Under whose authority is the radio station 13.2 Is using a radio in a threatening or abusive placed under? manner acceptable?

10.1 Does secrecy or confidentiality apply to general or public correspondence?

14.1 Before transmitting how should you avoid interference to ongoing transmissions?

10.2 Does secrecy or confidentiality apply to distress, urgency or safety broadcasts?

15. 1 In addition to the station licence, what other materials are advised to be carried?

17.1 Describe a radio call sign. 17.7 Is a radio call sign issued under a VHF class licence? 18.1 Complete the following: ‘Transmission without identification is……….’ 18.5 During distress communications how should operators identify their transmission?

11.1 What priority is given to distress calls?

16.1 What information must be entered into the 18.5 Without a radio call sign how may a vessel radio log book? be identified? 12.1 What is acceptable with regards to false or deceptive distress, urgency or safety calls?

Watch 19.1 What frequencies or channels are required to be monitored during a voyage?

SECTION 4: Frequencies – General Information 21.1 What frequencies or channels are authorised for the ship station operator to use?

24.3 How are vessels able to monitor a single frequency for distress and calling purposes?

22.1 What type of station controls communications between a coast station and a ship station?

24.4 What frequencies are monitored by Maritime Communication Stations?

22.2 What do you understand with regards to ‘avoidance of interference’ on communications from coast stations? 22.3 During ship to ship calls, which station controls communications? 23.1 Prior to making a test transmission, what information should be requested from the station about to be called? 23.2 Test transmissions on distress and safety frequencies should be kept to what length? 24.1 What is the purpose of a calling frequency? What is the purpose of a working frequency? 24.2 On completion of the exchange of traffic, what frequency should be monitored?

24.5 Are calling frequencies eligible for the exchange of routine messages? 25.1 List the main radiotelephony frequencies and channels for routine calling communications.

26.5 In the interest of brevity and accuracy, how would you refer to an HF frequency for making a telephone call? A station operating on HF channel 802 would be operating in what MHz band? 27.1 Whilst experiencing communications difficulties, how would you exchange words?

28.1 What information is requested to be passed on to Limited Coast Stations, such as those operated 25.2 How are vessels able to contact Australian by rescue organisations? Maritime Communication Stations? 25.3 What frequencies are available for calling 28.2 During a lengthy voyage, how often are position reports requested? Limited Coast Stations? 29.1 Does a ship station licence authorise 25.4 On distress frequencies, what mode of the use of radio equipment in port? transmission must be used? 25.5 What VHF Channel is reserved exclusively 29.2 Your vessel is in port limits, anchored, but the public network facilities are for DSC alerting? unavailable. what steps may you take in W 26.4 What is the DUPLEX mode of order to communicate to shore? transmission? 29.3 Are normal radiocommunications safe hen would the DUPLEX mode be whilst loading fuel? selected? 29.4 Are radio transmissions permitted when the vessel is within port limits?

AUSTRALIAN MARITIME COLLEGE

CHAPTER 2

RADIO PROPAGATION

MARINE RADIO OPERATORS HANDBOOK

Section 5

Frequency Characteristics

Frequency Bands (See Appendix 3 table 15)

Amplitude One cycle of a sinusoidal waveform is shown. This occurs in one Time Period, measured in seconds. The frequency of the waveform is measured in the number of cycles which occur in one second, known as a Hertz. There are 1000 Hertz to the kHz, (kiloHertz)

There are 1,000,000 Hertz to the MHz (MegaHertz)

0.5

There are 1,000,000,000 Hertz to the GHz (GigaHertz) The radio spectrum has been divided into frequency bands. Marine radio equipment operates mostly in the Medium Frequency (MF), High Frequency (HF) and Very High Frequency (VHF) bands.

Time Period

Medium Frequency High Frequency Very High Frequency

300 – 3000 kHz (or 3 MHz) 3 – 30 MHz and 30 – 300 MHz.

30. The Ionosphere

yW av Sk

F E D

Ionosphere

Ground Wave Transmitter

Receiver Earth’s Surface MF and HF Propagation

30.1 Lying between 80 and 350 km above the earth’s surface are a series of gaseous layers known as the Ionosphere. These gaseous layers become energised or ionised by the sun’s rays, e.g. ultra-violet or x-rays. 30.2 There are many variables that affect this radiation, including the time of day, the seasons and solar flares or sunspots. 30.3 There are three ionised layers in the ionosphere. These layers are designated by the letters D, e and F. During the daytime, the ionosphere consists of the D, E, and F layers (the F layer being subdivided into the F1 and F2 layers). At night the important layers are the E and F (or F2) layers, as the D layer becomes de-ionised and less effective.

AUSTRALIAN MARITIME COLLEGE

31. Radio Propagation 31.1 electromagnetic energy emanating from a radio transmitter antenna radiates in an omnidirectional manner. The radiated energy consists of sky waves, which travel upwards, and ground waves, which travel along the surface of the earth and follow its curvature to some extent. Ground waves will generally travel further over the sea than over the land. 31.2 The useful communication range of the ground wave component depends upon the frequency of the transmission. The higher the frequency used, the shorter will be the range of the ground wave. 31.3 The sky wave component travels up at many different angles and, depending on the frequency of the transmission, may be reflected back to earth by the ionosphere.

32. Radio Propagation AT MF (300 – 3000 KHz) 32.1 During the daytime, at medium frequencies, the sky wave component is not reflected back to earth by the ionosphere. Marine radio communication equipment therefore makes use of the ground wave for communications purposes. Typical ranges are from 100 to 400 nautical miles. 32.2 At night-time, the sky wave component of the wave is reflected back to earth at a far greater distance than that covered by the ground wave, but only the ground wave can be used for reliable communications.

33. Radio Propagation AT HF (3 – 30 MHz) 33.1 During the daytime, at HF, the sky wave component of the transmitted frequency is reflected back to earth. The distance at which the reflected energy is received is determined by the frequency selected. In the HF band of frequencies, marine communications equipment offers the operator a choice of frequencies in the 4, 6, 8, 12 and 16 MHz bands. 33.2 At night-time, the HF sky wave is still reflected back to earth but at a greater distance than during the day time. A lower frequency would be required to cover the same range that a higher frequency was required for during the daytime. 33.3 Generally speaking, the greater the range or distance required for communications, the higher the frequency that must be used. Long-range communication is therefore possible using the higher frequencies in the HF band. 33.4 MF/HF marine radio equipment offers the operator the choice of frequencies in the various bands. This allows the operator to select a frequency which will be suitable for the distance over which communication is required at any time of day or season. 33.5 Less long range interference will be experienced on the lower frequencies. In tropical waters, high static levels may make communications difficult or impossible at times. The correct selection of frequency is the lowest frequency that will provide satisfactory communications with the desired station. However, this is often a matter of experience rather than textbook knowledge.

34. ropagation 34.1 During the daytime or night-time, any sky wave radio energy transmitted at VHF is not reflected back to earth. Marine communications equipment makes use of the ground wave component at VHF. Under normal conditions, the range at VHF is said to be slightly greater than the visual line of sight, and is determined by the combined height of the transmitting and receiving antennas over an all water path. Range at VHF is therefore said to be only effective for short distances. During certain atmospheric conditions, particularly during the summer months, the ground wave may be refracted round the earth’s surface for a far greater range than would normally be expected at VHF. This phenomenon is known as ‘ducting’ and should not be regarded as normal. 34.2 Radio energy at VHF, condensed into a beam, may be used to communicate from the earth’s surface to an orbiting satellite.

35. Modes of Communications 35.1 Radiotelephony is the most common mode of transmission for mariners. There are two main types: Amplitude Modulation (AM) and Frequency Modulation (FM). In both these systems the voice signal (audio) is combined with the radio frequency that is required for the transmission to produce the modulated signal. Amplitude modulation produces an upper and a lower sideband either side of a carrier frequency signal which contain identical audio information. This system, sometimes referred to as ‘Double Sideband AM’, is the form of modulation used by commercial broadcasting stations.

MARINE RADIO OPERATORS HANDBOOK

35.2 The Single Sideband Mode of Transmission and Reception: Single Sideband (SSB) is mandatory on all MF/HF marine frequencies. Marine communications equipment uses the upper sideband (USB). The single sideband mode of communication has two variants: AM compatible and SSB. 35.3 AM Compatible (H3E): The first of these two sideband modes consists of the USB plus a full strength carrier signal. This is known as the AM compatible mode, often referred to as simply AM. International regulations only require the use of AM (H3e) on 2182 kHz for distress, urgency or safety communications. H3e is known as the emission designator for this mode of transmission. Marine communications equipment with a dedicated 2182 kHz button will usually revert to the AM mode when selected. 35.4 SSB (J3E): The second of these two sideband modes is known as SSB (J3e), where J3e is the emission designator for this mode of transmission. This mode is defined as radiotelephony using amplitude modulation single sideband with suppressed carrier. It is often referred to as SSB and is used on all MF/HF marine frequencies. The transceiver operating in the SSB mode will receive both SSB and AM signals. However, the AM signal will have a background tone. The transceiver operating in the AM mode will receive the SSB signal badly garbled and unintelligible. 35.5 Digital Selective Calling (DSC): The Digital Selective Calling (DSC) mode is used on frequencies in the MF, HF and VHF bands. On the medium or high frequencies, the transmission consists of a brief burst of data, typically five to seven seconds duration, by the Narrow Band Direct Printing (NBDP) or telex mode. F1B is the emission designator for this mode of transmission. At VHF, the transmission is a short burst of data of approximately half a second duration.

36. SIMPLEX and DUPLEX Communication Modes of Operation 36.1 SIMPLEX Simplex operation makes use of a single frequency for both transmission and reception. The operator will press the talk button on the microphone in order to transmit. Releasing the button enables the operator to receive incoming signals. This also permits all stations to listen on a common frequency (such as during distress trafﬁc and All Stations calls). 36.2 DUPLEX Duplex operation is when transmission and reception take place simultaneously on two separate but paired frequencies: for example, for radiotelephone calls taking place on the public network system. Operators usually select an internationally designated channel in the HF band of frequencies for telephone calls. The ship station transceiver is programmed for transmission on frequency A and reception on frequency B. The coast radio station transceiver operating on the same international channel would therefore be programmed to receive frequency A and to transmit on frequency B. 36.3 The different transmit and receive frequencies allow ship stations fitted with the necessary facilities to transmit and receive simultaneously. Because the transmitter and the receiver are both operating at the same time, radiotelephone calls can be conducted in a similar manner to a telephone call made over the land system, with each party being able to speak and hear at the same time. Ship stations cannot communicate with each other using the Duplex mode of operation. 36.4 Most working channels in the MF/HF and VHF marine bands are duplex. The appropriate paired frequencies are pre-programmed into transceivers and selected automatically by use of the channel selector control. 36.5 The duplex filter units allowing simultaneous transmission and reception are usually only found on expensive MF/HF and VHF equipment. The use of widely separated antennas, one for transmission and another for reception, may also be required. 36.6 MF/HF and VHF ship stations without the duplex facility must use the paired frequencies alternately: that is, for transmission or reception, but not at the same time. Use of the word ‘over’ to prevent confusion and ensure efficient use of time on air is explained in paragraph 138 (See SIMPLEX 36.1).

AUSTRALIAN MARITIME COLLEGE

Chapter 2 Radio Propagation â&#x20AC;&#x201C; Revision Questions SECTION 5: Frequency Characteristics 30.1 What are the gaseous layers some 80 to 350 km above the earthâ&#x20AC;&#x2122;s surface known as? 30.2 what variables affect the ionosphere? 30.3 How many gaseous layers of the ionosphere are there during the daytime?

33.1 At HF, what determines range of transmission? W

what is the HF frequency band? (See Table 15, page 96.)

33.2 what is the effect on the communication range of HF frequencies at night-time?

31.1 Radio waves radiating from a transmitting 33.2 At MF/HF, generally speaking what antenna can be divided into which two determines range of transmission? basic types of waves? 33.2 What frequencies are used for long range 31.1 In general, what range is covered by the communications? ground wave component of radio energy? 34.1 At VHF, what section of the radiated 32.1 At MF, is the sky wave component of the energy is made use of? radiated energy returned back to earth During certain atmospheric conditions, during daylight hours? what phenomenon greatly increases what is the MF frequency band? transmission range at VHF? (See Table 15, page 96.) 32.2 What is the effect on MF frequency during night-time?

NOTES

MARINE RADIO OPERATORS HANDBOOK

35.2 What mode of communication is mandatory on marine MF and HF frequencies? 35.3 What transmission emission mode is available for distress communications on 2182 kHz? 35.4 What transmission emission mode is required on all marine MF/HF transmissions? 35.5 What transmission emission mode is used for MF/HF DSC alerts? 36.1 What transmission mode is required for distress broadcasts? Define SIMPLEX transmission 36.2 When would the DUPLEX mode of transmission be used? Define the DUPLex mode of transmission.

CHAPTER 3

maritime communication, coast radio and limited coast stations

AUSTRALIAN MARITIME COLLEGE

ommunications Important Note - The Bureau of Meteorology now transmits a range of high seas and coastal weather warnings on a combination of previously used working frequencies and a set of new frequencies. These frequencies are listed in Appendix 3. The forecasts and warnings are automatically generated and broadcast. Vessels will not be able to communicate with these stations as they will only operate as broadcast stations. Aural monitoring of other MF/HF radiotelephony distress and calling frequencies by Limited Coast Stations continues, but the coverage provided by these Limited Coast Stations may not be complete. Some weather information also continues to be available by radiotelephony from these stations. Contact the relevant State/Territory authority or your local volunteer marine rescue organisation to find out information about Limited Coast Stations in your area. Note - Unless otherwise specified, the term ‘Limited Coast Stations’ will be used to refer to both the coast radio stations operated by the State/Territory marine authorities and other Limited Coast Stations.

37. Maritime Communication Station Services 37.1 Australian Maritime Communication Stations are operated by Kordia Solutions Ltd. The Kordia Network Control Centre is co-located with the Australian Rescue Co-ordination Centre (RCC) operated by Australian Search and Rescue (AusSAR) in Canberra. Search and Rescue (SAR) and safety of life at sea services are performed by the RCC on behalf of the Australian Maritime Safety Authority (AMSA). 37.2 A Maritime Communication Station is a station on land established for the purpose of communicating with vessels at sea. Australian Maritime Communication Stations provide the following services to vessels: - search and rescue (SAR) operations in conjunction with the Rescue Co-ordination Centre (RCC) in Canberra (RCC Australia); - weather forecasts and warnings for coastal waters and high seas areas from the Bureau of Meteorology, transmitted automatically; and - continuous automated watch of HF digital selective calling (DSC) frequencies for distress calls for the purpose of safety of life at sea.

38. Location of Maritime Communication Stations 38.1 Under the current contract with Kordia, radiocommunications to vessels at sea are provided by two Maritime Communication Stations - wiluna (WA) and Charleville (Qld). The network is designed to sense the power of a transmission and respond from the appropriate station. The two stations are centrally controlled from the Network Control Centre (NCC) in Canberra.

39. Identification of Maritime Communication Stations 39.1 Maritime Communication Stations can be contacted via a digital selective calling service, which is identified by a nine digit code known as a Maritime Mobile Service Identity (MMSI). The MMSI for both Australian Maritime Communication Stations is 005030001. 39.2 After establishing contact by digital selective calling, Australian Maritime Communication Stations will switch to a radiotelephone channel and respond with the call sign ‘RCC Australia’. 39.3 Maritime Communication Stations may also respond with the use of their official radiotelephony call sign, ‘RCC Australia, VIC (Victor India Charlie)’.

40. Monitoring of Frequencies by Maritime Communication Stations (Watchkeeping) 40.1 Collectively, the two Maritime Communication Stations provide a continuous watch on the HF digital selective calling frequencies reserved for distress, urgency and safety. See paragraph 83.1. 40.2 Maritime Communication Stations do not operate in the 27 MHz marine band. Potential users should check if Limited Coast Stations in their local area are monitoring frequencies in this band before relying on it for communication.

MARINE RADIO OPERATORS HANDBOOK

40.3 maritime Communication Stations do not provide aural monitoring of the international radiotelephony distress and calling frequencies in the 2, 4, 6, 8, 12 and 16 mhz bands (2182, 4125, 6215, 8291, 12 290 and 16 420 khz) or the VhF marine band (VhF channel 16). potential users should read Section 7 for more information and check if Limited Coast Stations in their local area are monitoring these frequencies before relying on them for communication. 40.4 maritime Communication Stations do not provide mF digital selective calling monitoring in the 2 mhz band (2187.5 khz). potential users should check if Limited Coast Stations in their local area are monitoring this frequency before relying on it for communication.

41. Emergency Medical Advice 41.1 in urgent medical cases, a digital selective calling (dSC) urgency alert may be used to establish communications with the Maritime Communication Stations. 41.2 australian Maritime Communication Stations have formal arrangements with health authorities and will relay medical advice to and from vessels at sea in an emergency. This service is free of charge.

Section 7

State and Northern Territory HF (Coast Radio Stations) and VHF Stations

Important Note - Potential users should seek current advice from the relevant State/Territory authority about the operation of these services. the nine hF stations listed in this section are licensed as Limited Coast Stations. these stations may be referred to elsewhere in this handbook as Coast radio Stations. The VHF only stations operated by (or for) the State and Northern Territory marine authorities are also licensed as Limited Coast Stations. both types of station as well as other Limited Coast Stations are referred to collectively as Limited Coast Stations.

42. Services provided by the State and Northern Territory Governments 42.1 State and Northern Territory governments provide a range of maritime safety radio services. These services are provided on selected High Frequency (hF) frequencies along with Very high Frequency (VhF) Channels 16 and 67 in certain coastal areas.

43. Coast Radio Stations: High Frequency (HF) Maritime Distress and Safety Service 43.1 hF radio distress and safety services are provided to all coastal areas throughout australia with coverage extending to within 200 nautical miles seaward. 43.2 These services are provided through a network of nine HF stations located at Perth, Port Hedland, Darwin, Cairns, Gladstone, Sydney, Melbourne, Adelaide and Hobart. These HF stations will operate using the following identities: COAST RADIO CAIRNS;

COAST RADIO ADELAIDE;

COAST RADIO GLADSTONE;

COAST RADIO PERTH;

COAST RADIO SYDNEY;

COAST RADIO HEDLAND; and

COAST RADIO MELBOURNE;

COAST RADIO DARWIN.

COAST RADIO HOBART;

AUSTRALIAN MARITIME COLLEGE

COAST STATIONS HF NETWORK

RCC AUSTRALIA Continuous Automated Watch on HF DSC Frequencies: 4207.5 kHz 6312.0 kHz 8414.5 kHz 12577.0 kHz 16804.5 kHz

Continuous Watch on Voice Distress Frequencies: 4125 kHz 6215 kHz 8291 kHz

Automatic broadcasts of weather forecasts and warnings for coastal and high seas areas.

Other services may be provided, eg, VHF. Check information provided by State or NT Marine Authorities.

MCSs at Wiluna and Charleville MMSI: 005030001 (for both stations) Callsign: RCC Australia, V.I.C. (for both stations)

Navigation warnings broadcast on 8176 kHz

Intended coverage: coastal areas extending to 200 nm to seaward from the coastline.

Intended coverage: coastal and ocean areas extending to the limits of Australia's Search and Rescue Region. Phone: +61 2 6230 6811 Fax: +61 2 6230 6868 Email: rcc@amsa.gov.au

43.3 Services provided by these stations include 24 hour listening watches on 4125 kHz, 6215 kHz and 8291 kHz for distress and safety situations and the broadcast of navigation warnings on 8176 kHz. *Note: Coast Radio Stations are no longer required to constantly monitor 2182 kHz. 43.4 Vessel operators should note that the 4125 and 6215 kHz radiotelephony distress, urgency, safety and routine calling frequencies are supplementary to 2182 kHz. 8291 kHz is for distress and urgency communications. 8291 kHz is used for announcing safety traffic prior to transmitting the safety traffic on a working frequency. It is important to restrict radio traffic on these frequencies to distress, urgency and safety calls. This does not mean that the operator cannot use 4125 and 6215 kHz for general calling, but the operator should avoid using those frequencies for that purpose, where possible. The operator must not use 8291 kHz for routine or general calling. Radio checks or calls of a general nature should be directed to volunteer marine rescue groups or other service providers. 43.5 the HF distress and safety service is a national network delivered uniformly by each state and the Northern Territory. The network approach ensures high levels of radio service availability, thus providing confidence that a vessel in distress will be able to contact alternative HF stations during periods of atmospheric or solar disturbance that may limit HF communications from vessels at sea to any particular station. 43.6 Navigation warnings will be broadcast on 8176 kHz in accordance with a schedule commencing 3 minutes prior to the hour (UTC). Navigation warning broadcast schedules can be obtained from the State/NT marine authorities.

MARINE RADIO OPERATORS HANDBOOK

44. Very High Frequency (VHF) Maritime Distress and Safety Service 44.1 VHF radio distress and safety services include 24 hour monitoring of VHF Channel 16 for distress, urgency and safety traffic and regular broadcasts of weather information on VHF Channel 67. 44.2 VHF radio distress and safety services on Channels 16 and 67 are provided in the following coastal areas: - Queensland - Sea areas adjacent to Fraser Island with continuous coverage through to the Tweed Coast area, along with sea areas adjacent to Townsville; - New South Wales - Sea areas adjacent to Newcastle, with continuous coastal coverage through to the Nowra area; - Victoria - The Port Phillip Bay / Western Port Bay area and adjacent sea areas; - South Australia - Sea area Ceduna to Discovery Bay and Gulf waters; - Tasmania - Sea areas surrounding Tasmania and adjacent to Victoria; - Western Australia - Sea areas adjacent to Perth; and - Northern Territory - Sea areas adjacent to Darwin 44.3 Vessel operators should note that VHF Channel 16 is for distress, urgency, safety and routine calling. It is important to restrict radio traffic on VHF Channel 16 to distress, urgency and safety calls. This does not mean that operators cannot use VHF Channel 16 for routine calls, but where possible working or on demand channels should be used. 44.4 Vessel operators should note that VHF Channel 13 is used for ship to ship maritime safety information (See Appendix 4).

Section 8

Limited Coast Stations

45. Services Provided by Limited Coast Stations 45.1 The service provided by Limited Coast Stations is restricted to communications concerning the safety, movements and operations of vessels in their vicinity. This service may include communications relating to fishing or other commercial operations, club events, the broadcast of weather, navigational information, and Search and Rescue. Use of services other than distress may be limited to members of organisations linked to the Limited Coast Station. 45.2 Limited Coast Stations are not permitted to handle public correspondence to or from destinations ashore. 45.3 Limited Coast Stations offer a service to vessels in the MF/HF, 27 MHz and VHF marine bands. Details of frequencies assigned to ship radio stations to communicate with Limited Coast Stations are shown in Appendix 3.

46. Categories of Limited Coast Station 46.1 Limited Coast Stations are stations on land established for the purpose of communicating with vessels at sea. Such stations generally fall into one of the following categories: - stations serving the professional fishing industry; - stations established by the operators of small commercial vessels such as charter vessels, tugs, etc; - stations established by boating and fishing clubs to provide a service for their members; - stations established by port or harbour management authorities to co-ordinate the movements of vessels within and near a port; or - stations established by recognised marine rescue organisations to supplement the safety of life at sea service offered by Coast Radio Stations and Maritime Communication Stations.

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47. HOURS OF OPeRATION FOR LIMITeD COAST STATIONS 47.1 There are no fixed hours for the radio service provided by Limited Coast Stations and many do not offer a continuous service. Hours of operation are determined by local requirements or, in some cases, by State Government legislation. 47.2 In the interests of safety, ship radio station operators are encouraged to familiarise themselves with local Limited Coast Stations, in particular those offering a marine rescue service, regarding hours of operation and frequencies monitored.

48. Identification of Limited Coast Stations 48.1 Limited Coast Stations operating in the MF and HF marine bands should identify themselves by use of their name and the official call sign allocated to them by ACMA. 48.2 Limited Coast Stations operating in the VHF marine bands may use their official call sign and/or other approved identification such as the organisation’s name. Examples: Queensland Tug and Salvage, VKQ 445 Moreton Bay Boat Club, Sandringham Coast Guard, etc. 48.3 Limited Coast Stations offering a digital selective calling service are identified by a nine digit code known as a Maritime Mobile Service Identity (MMSI).

Section 9 VHF Marine Repeaters 49. Principle of Operation 49.1 VHF communications range depends mainly on the height of the antennas of the transmitting and receiving stations. By using VHF marine repeater stations, the range of ship to ship, ship to shore and shore to ship communications can be significantly increased. 49.2 VHF marine repeaters are unmanned shore installations usually located at geographically high points. They are designed to transmit and receive simultaneously and will retransmit or ‘repeat’ all signals received. The retransmitted signals can be received by any station listening on the repeater channel. 49.3 Limited Coast Stations operated by marine rescue organisations routinely monitor VHF repeater channels operating in their area. 49.4 Not all coastal areas of Australia are served by VHF marine repeaters.

50. VHF Marine Repeater Channels 50.1 VHF marine repeaters operate in the DUPLex mode on channels 21, 22, 80, 81 or 82. 50.2 For their own safety, boat owners should ensure that they are familiar with the location and operating channel of their local repeater. 50.3 Digital selective calling alerts using VHF are conﬁned to channel 70 and will not operate through repeaters.

51. Use of VHF Marine Repeaters 51.1 In most cases VHF marine repeaters are installed and maintained by marine rescue organisations as a service to mariners and are available for use by all licensed VHF ship stations. However, in order to minimise congestion, if direct ship to ship or ship to shore communications are possible on a non-repeater channel, this must be used in preference. 51.2 Repeater channels must not be used as ‘chatter channels’. Communications must be restricted to those concerning the movements of vessels and safety of vessels and persons. To discourage lengthy conversations, repeaters will incorporate an automatic time restriction of approximately thirty seconds. 51.3 If not apparent by monitoring, a ship station can gain an indication of its ability to access a repeater by momentarily pressing the microphone button. If a brief (approximately one second) burst or ‘tail’ of noise is heard from the loudspeaker when the button is released, then the vessel is activating the repeater. If a 'tail' is not heard, it is probable that the vessel is out of range of the repeater. 51.4 Operators using VHF equipment equipped with an ‘International/Aus’ or ‘USA’ channel switch should note that it is essential that the switch be in the ‘International/Aus’ position to access repeaters. (See paragraph 73.1)

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ommunication tations Section 6: Maritime Communications Stations 37.2 What services are provided by Maritime Communications Stations?

39.3 What is the radiotelephony callsign for RCC Australia?

38.1 Where are the Australian Maritime Communications Stations located?

40.1 What watchkeeping services do Australian 40.4 Do Maritime Communications Stations Maritime Communications Stations monitor MF 2187.5 kHz DSC? provide? 41.2 Do Maritime Communications Stations 40.3 Do Maritime Communications Stations provide free medical advice? monitor the MF/HF radiotelephony distress frequencies?

39.1 How are Maritime Communications Stations identiﬁed? 39.2 How are the Australian Maritime Communications Stations contacted?

40.3 Do Maritime Communications Stations monitor VHF Ch70?

tations TIONS 42.1 What service is provided by Coast Radio Stations?

43.2 What radiotelephony frequencies are monitored by Coast Radio Stations?

44.1 What services are provided by Coast Radio Stations on VHF Ch16?

43.1 Within what range or distance from the Australian coast do the Coast Radio Stations provide a distress and safety service?

43.3 What HF frequency is used for the broadcast of navigational warnings?

44.1 What VHF channel is used for the regular broadcast of weather information on VHF?

43.2 How many Coast Radio Stations provide a distress and safety communications service around the Australian coast?

43.4 What radiotelephony frequencies are supplementary to 2182 and 8291 kHz and may be used for routine calling?

44.3 VHF Ch 16 is intended for what type of communications? 44.4 What VHF channel is reserved for ship to ship maritime safety communications?

tations 45.1 What services are provided by a Limited Coast Station?

46.1 What is the purpose of a Limited Coast Station?

45.2 Can Limited Coast Stations handle public correspondence trafﬁc?

46.1 What type of stations could be described as Limited Coast Radio Station?

48.1 How are Limited Coast Stations identiﬁed? 48.3 How is a Limited Coast Station identiﬁed if it offers a Digital Selective Calling Service (DSC)?

45.3 In what frequency bands do Limited Coast 47.1 Generally speaking, what are the working hours of Limited Coast Stations? Stations provide facilities?

rs 49.1 Name one method by which the range of a shore-based VHF station can be increased. 50.1 List the VHF channels available for marine repeater.

50.3 Would a DSC service be available on a Marine VHF repeater channel?

51.2 What is the purpose of automatic time restrictions on marine VHF repeaters?

51.1 Should you use a VHF repeater channel if direct communications are possible using another channel?

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CHAPTER 4

POWER SUPPLIES

MARINE RADIO OPERATORS HANDBOOK

Section 10 Care and Maintenance of Batteries 52. Location of Batteries 52.1 The location of a battery supplying marine radio equipment should be chosen to ensure that, as far as practicable, the battery is: - protected from the elements; - readily accessible for routine maintenance; - located reasonably close to the transceiver; - located as high in the vessel as practicable; - well ventilated to dissipate the hydrogen gas produced (if located within a wheelhouse or other compartment, venting to the outside may be necessary); - not located with other items of equipment that could, in heavy weather, fall across the battery and cause short-circuiting; and - not located in the same compartment as a different type of battery, for example, alkaline cells.

53. Construction of Lead Acid Cells 53.1 Lead acid cells have a voltage of 2 volts per cell, regardless of size. Larger size cells will supply higher current than smaller cells, or the same current for longer periods. The ability of a cell to produce current for a period of time is known as the cell’s capacity and is usually measured in ampere-hours (Ah) or, with batteries designed for motor vehicle use, in ‘cold cranking amps’ (CCA). 53.2 A chemical combination of lead and lead peroxide plates and the sulphuric acid in the electrolyte (the liquid solution within the cell), produces a voltage difference between the plates. This voltage difference allows a current to flow through any load, such as a radio, connected across the battery terminals and is called direct-current or ‘dc’. 53.3 When the acid in the electrolyte or the material in the plates is used up, the voltage no longer exists and current cannot flow. At this point, the cell is said to be discharged or ‘flat’. 53.4 This situation is reversible by passing a current in the opposite direction. This process reverses the chemical reactions in the cell and is known as charging.

54 Connection of Lead Acid Cells 54.1 Cells may be connected in series, that is, the positive terminal of one cell to the negative terminal of another, to produce higher voltages. Three cells connected in series will give a battery of 3 x 2 volts = 6 volts; six cells connected in series will give a battery of 6 x 2 volts = 12 volts. 54.2 Most modern lead-acid batteries are supplied in 6 or 12 volt combinations and may themselves be connected in series to provide the required output voltage; for example, two 12 volt batteries connected in series will produce a voltage of 2 x 12 volts = 24 volts. 54.3 Connection of lead-acid batteries in parallel, that is, positive terminal to positive terminal, negative terminal to negative terminal, will produce the same output voltage as a single battery, but the ability to supply current (capacity) will have been increased. For example, two batteries each supplying 12 volts with a capacity of 60 ampere-hours, when connected in parallel, will provide a voltage output of 12 volts with a capacity of 120 ampere-hours. Positive Negative

Negative Positive

Series Connection

Parallel Connection

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55. Essential Battery Maintenance 55.1 The functioning of radio equipment is dependent on power supplied by the battery. If it is to provide adequate performance in the event of an emergency, regular and careful maintenance is required. 55.2 A batteryâ&#x20AC;&#x2122;s service life also depends on the manner in which it is treated. 55.3 To ensure the best performance from a battery it is important that a battery: - is kept clean, dry and free from terminal corrosion; - has the electrolyte kept at the correct level; and - is kept correctly charged.

56. Battery Cleanliness 56.1 A battery top should be kept clean. A dirty battery top may hold spilt electrolyte on its surface thereby providing a path for the electrical current to leak away. It is important to keep the outside surfaces of a battery dry and free of contamination. 56.2 Corrosion forming on terminal clamps may seriously affect, or even prevent, the ability of the battery to supply current. Corrosion will be evident by the formation of a white-green powder between the battery terminals and the terminal clamps. In this situation, the terminal clamp should be removed and both it and the terminal post cleaned. 56.3 To minimise the likelihood of corrosion, terminal posts and clamps should be lightly smeared with Vaselineâ&#x201E;˘ or petroleum jelly.

57. Electrolyte Level 57.1 The level of electrolyte inside a battery is important. As a result of the chemical action inside a battery, water is lost. This should be replaced with distilled or demineralised water. 57.2 Seawater must not be used under any circumstances. 57.3 The level of the electrolyte should be maintained at approximately 10 mm above the plates unless otherwise specified by the manufacturer. 57.4 If the electrolyte level is too high, it may overflow during charging, providing an unwanted discharge path. If the electrolyte is too low, the plates are exposed to the air and permanent damage and loss of capacity may result. 57.5 It may be noticed that a battery that is nearing the end of its useful life will require more frequent topping-up than has been previously necessary. 57.6 Low-maintenance batteries will require infrequent topping-up. Maintenance-free batteries may require none at all.

58. Correct Charging 58.1 To provide the best service, a battery must be correctly charged. Both overcharging and undercharging can seriously affect its performance. 58.2 On small vessels the usual means of charging the radio battery will be an alternator or generator attached to the vesselâ&#x20AC;&#x2122;s engine. An associated regulator, which reduces the charging current as necessary, should prevent overcharging. 58.3 Vessels that are used frequently (say, several times each week) should have no problem maintaining a fully charged radio battery. However, on vessels that are used relatively infrequently (once every few weeks), it is likely that during storage even a battery that starts as fully charged will self-discharge and go flat. 58.4 For safety reasons, it is important that the vessel owner is able to determine the general condition of a battery and its ability to supply current over a period of time (its capacity). An indication of the level of charge in a battery may be obtained by either: - measuring the specific gravity of the electrolyte; or - measuring the on-load terminal voltage.

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59. Measuring the Specific Gravity 59.1 The specific gravity (SG), also called the relative density, of the electrolyte (the liquid inside the battery) varies proportionally with the amount of charge in the battery. It is highest when the battery is fully charged and lowest when the battery is fully discharged or flat. It follows that the amount of charge in a battery can be determined by measuring the specific gravity of the electrolyte. 59.2 A simple, inexpensive device called a hydrometer is used to measure specific gravity.

Rubber Bulb

1.150 1.200 1.250 1.300

R E C H A R G E F A I R G O O D

1.1

1.2

Hollow glass ďŹ&#x201A;oat Glass Barrel Scale

1.3

Electrolyte being measured Weight to hold float erect Rubber hose

The Hydrometer

59.3 In general, for a fully charged battery, the specific gravity should measure about 1.250. Half charge will be indicated by a reading of 1.200 and fully discharged by 1.150. All cells in a battery should indicate a similar specific gravity. A variation of more than about 0.025 will indicate a faulty cell and the battery should be replaced. 59.4 Specific gravity readings should not be taken immediately after topping-up a cell, as the added water will float towards the top of the cell and give a false reading. Charging for thirty minutes or more after topping-up will mix the electrolyte and allow accurate readings. 59.5 Batteries which have cells where the specific gravity readings fail to rise, or respond poorly to adequate charging, should be replaced.

60. Measuring the On-Load Terminal Voltage 60.1 Measurement of the terminal voltage when a battery is supplying current to a load, such as a radio, will also provide an indication of the amount of charge in a battery. This measurement is known as the on-load terminal voltage. 60.2 For a 12-volt battery, the on-load terminal voltage should not fall below approximately 11.4 volts while transmitting. If the voltage does fall significantly below this figure, the battery requires charging. If, after charging, the on-load terminal voltage still falls significantly below 11.4 volts, it is an indication of a faulty cell and the battery should be replaced. 60.3 Measuring of the off-load (that is, when the battery is idle) terminal voltage of a battery is a poor indication of its condition.

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61. Loss of Capacity 61.1 A battery will suffer a gradual loss of capacity during its life. This is inevitable and the battery should be replaced when the capacity loss becomes significant. 61.2 Many lead-acid batteries have a commercial life of only two to three years. 61.3 However, the useful life of a battery can be considerably shortened by: - operating a battery in a low state of charge for long periods; - allowing a battery to stand in a discharged state for long periods; - leaving a charged battery for long periods without periodic charging; and - overcharging.

62. Battery Hazards 62.1 There are two hazards associated with lead-acid batteries that ship station operators should be aware of: - the risk of explosion; and - the risk of chemical burns. 62.2 As a result of the chemical process occurring within the cells of a battery during charging, hydrogen gas is produced. when mixed with air, this can form a highly explosive mixture which can be ignited by a naked flame, a lighted cigarette, or a spark. The spark caused by breaking or making an electrical connection in the vicinity of the charging battery may be sufficient to ignite the hydrogen-air mixture. Batteries should be located as close to the radio equipment as possible, and placed in a well ventilated container or locker. 62.3 If using metal tools to work on battery connections, extreme care must be taken to ensure that terminals are not short-circuited. 62.4 The electrolyte in battery cells contains Sulphuric Acid. It is sufficiently concentrated, particularly just after charging, to damage eyes, skin or clothes if spilt or splashed. Immediate and prolonged application of running water is recommended to minimise its effect. 62.5 It is recommended that eye protection, gloves, etc. be worn when a person is carrying out maintenance on batteries. Batteries should not be topped-up whilst on charge.

63. Maintenance Free Batteries 63.1 Maintenance free lead-acid or gel type batteries are becoming increasingly available to mariners. Users of these types of batteries are recommended to follow the manufacturersâ&#x20AC;&#x2122; guidelines in ascertaining the condition of the battery before replacement. On vessels where it is mandatory to carry an independent emergency means of electrical supply for communications equipment, it may also be a requirement to replace maintenance free batteries after a short operational period of 1 year.

NOTES

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Chapter 4 Power Supplies – Revision Questions Section 10: Care and Maintenance of Batteries 52.1 Where should the battery supplying marine radio equipment be located?

56.1 Why should battery tops be kept physically clean?

53.1 What is the ability of a battery to supply current known as?

56.2 What can be the result of corrosion on battery terminals?

53.2 What materials make up the cell plates of 56.3 How can you minimise corrosion on lead-acid batteries? battery terminals? 53.3 Describe the basic physical process that results in a “ﬂat” or discharged battery.

57.1 What is used to top up the battery electrolyte in a lead-acid battery?

53.4 If you reverse the chemical reaction by passing current in the opposite direction, what happens to the battery condition? 54.1 How many cells constitute the minimum necessary for a 12V lead-acid battery?

57.3 What is the recommended electrolyte level in a lead-acid battery?

54.1 Describe batteries connected in SERIES. 54.2 Why might one want to connect batteries in SERIES? 54.3 Describe batteries connected in PARALLEL. W

What is the effect of connecting batteries in PARALLEL?

58.1 How is the battery maintained in order to provide the best service? 58.4 List 2 (two) methods of checking the battery condition. 59.1 What do you understand by the term “SG” in relation to battery electrolyte? 59.2 What instrument is used to measure the SG of a battery cell. 59.3 In general, what is the SG of a fully charged cell?

60.3 Is it useful to test the ‘off-load’ voltage, when the battery is in the idle condition? 61.3 How can the useful life of a battery be shortened? 62.1 List 2 (two) major safety hazards with lead-acid batteries. 62.2 When choosing the location of a battery installation, what should you take into consideration? 62.2 What type of gas is emitted from a lead-acid battery during the charging process? 62.3 What precautions must be taken in order to prevent the short circuit of battery terminals? 62.4 What acid is contained in the electrolyte of a lead-acid battery? 62.5 What precautions are recommended in order to prevent acid splash during battery Maintenance?

55.3 List 3 (three) ways to ensure optimum battery performance.

NOTES

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CHAPTER 5

MARINE RADIOCOMMUNICATIONS EQUIPMENT

MARINE RADIO OPERATORS HANDBOOK

Section 11 Types of Marine Radio Equipment 64. Choice of Marine Radio Equipment 64.1 Three different types of marine radiocommunications equipment are available in Australia. The type best suited to any vessel must depend on: - the level of communications service required by the owner; and, more importantly, - the ability of the equipment to provide an adequate level of safety communications in the vessel’s area of operation.

65. Types of Marine Radiocommunications Equipment 65.1 The three types of marine radiocommunications equipment available in Australia are: - 1. equipment operating in the international MF and HF marine bands; - 2. equipment operating in the 27 MHz marine band (usually referred to as ‘27 Meg marine’); and - 3. equipment operating in the international VHF marine band. 65.2 each type has its own advantages and disadvantages. Due to the increasing usage of digital selective calling, it is important that this feature is considered when choosing marine radiocommunications equipment. MF/HF and VHF marine radio equipment may have digital selective calling capability in addition to radiotelephony.

66. MF/HF Marine Radio Equipment 66.1 MF/HF marine equipment offers: - a safety service provided by Limited Coast Stations; - the advantages of being able to change frequency bands to provide communications over the desired range, and to provide access to a radiotelephone service; - a communications range of many thousands of kilometres, and worldwide, given the correct choice of frequency band; but - the disadvantages of high cost, complex installation, greater operator expertise, and of being subject to atmospheric and ignition interference noise. 66.2 Because it does not suffer the range limitations of 27 MHz and VHF marine equipment, MF/HF marine equipment is the only system recommended for vessels undertaking lengthy coastal or overseas voyages. 66.3 MF/HF marine radio equipment fitted with digital selective calling may offer a single-button distress facility and automated watchkeeping (see chapter 6). In particular, digital selective calling can allow the use of MF/HF marine radio equipment to communicate with a wide variety of stations and services including the foreign coast stations mentioned in Chapter 12.

67. nt 67.1 27 MHz marine equipment offers: - a communications range, under favourable conditions, of between 10 and 50 km (5.4 and 27 nautical miles); - a safety service provided by Limited Coast Stations operated by marine rescue organisations; - the advantages of being cheap and easy to install; but - the disadvantages of being subject to interference from atmospheric and ignition noise (and on occasions, from distant radio stations), and of not providing access to a radiotelephone service; and - not being compatible with large vessels communicating under the GMDSS system.

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68. VHF Marine Radio Equipment 68.1 VHF marine equipment offers: - a communications range between vessels of up to 20 km (10.8 nautical miles) and between vessel and shore of 50 km (27 nautical miles), and occasionally significantly greater; - a safety service provided by Limited Coast Stations operated by marine rescue and other organisations; - the advantages of being relatively inexpensive, of providing the highest quality signal, of suffering least from interference caused by atmospheric or ignition sources, and of providing access to a shore telephone service; but - the disadvantage of suffering blind spots behind cliffs, sand hills and heavy vegetation. 68.2 VHF marine equipment is suitable for small vessels remaining relatively close to the coast and within range of Limited Coast Stations operating on VHF channels. 68.3 VHF marine radio equipment fitted with digital selective calling may offer a single-button distress facility and automated watchkeeping (see chapter 6).

Section 12 Component Parts of Marine Radio Equipment 69. The Major Parts of Radio Equipment 69.1 Marine radio equipment, whether operating in the MF/HF, 27 MHz or VHF bands, is made up of three major parts: - the power supply; - the transmitter and the receiver (transceiver); and - the antenna or aerial. 69.2 each part is dependent on the others. A fault in any one of the parts will not allow the equipment to function correctly.

70. The Power Supply 70.1 The power supply has to provide electrical energy to the transmitter and the receiver to enable them to perform their functions. 70.2 The most convenient form of power supply for small vessels is the lead-acid battery. 70.3 Fuses located in the wiring between the battery and the transceiver protect the vessel and equipment against damage should a malfunction occur.

71. The Transmitter and the Receiver (Transceiver) 71.1 The function of the transmitter is to turn voice (audio) signals into radio signals so they can travel over very long distances. This is achieved by converting the voice signals spoken into the microphone into high powered radio frequency energy which is passed to the antenna and radiated into space. 71.2 The function of the receiver is to select only those radio frequency signals which are required by the operator, and to amplify them. These signals are then converted back into voice signals and reproduced by a loudspeaker. 71.3 It is usual with marine radio equipment for the transmitter and receiver to be combined in a single unit called a transceiver. 71.4 On MF/HF transceivers, to achieve effective communications, it is essential to provide a radio â&#x20AC;&#x2DC;earthâ&#x20AC;&#x2122; to the water surrounding the vessel. Usually, this is achieved by running a heavy wire or, preferably, a copper strip from the radio earth terminal of the transceiver to either a metal plate on the underside of the hull or, in the case of a vessel constructed from metal, directly to part of the metallic structure. On fibreglass vessels, a satisfactory radio earth may be achieved by connecting the transceiver to a metallic plate within the layers of the hull.

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72. The Antenna 72.1 The antenna has two functions: - during transmission, to radiate into space the radio frequency energy generated by the transmitter; - during reception, to gather radio frequency energy from space and pass it to the receiver. 72.2 The antenna, therefore, will be connected to either the transmitter or the receiver, depending on whether transmission or reception is taking place. 72.3 The changeover is affected by the press-to-talk button on the microphone or handset. when pressed, the transmitter is connected to the antenna. when released, the antenna is reconnected to the receiver.

Section 13 Transceiver Controls 73. Transceiver Controls 73.1 This section details the functions of important operator controls which may be found on marine radio equipment. Not all will be found on each type of equipment. Transceiver controls may be identified differently by individual manufacturers but will have the same purpose. Marine VHF:

On/Off and Volume Control. Often these functions are combined into a single control. It is used to turn the equipment on or off, and to adjust the level of signals coming from the loudspeaker. Squelch Control. This control allows the operator to stop the constant and annoying internally generated background roar from the receiver in the absence of an incoming signal. On VHF marine equipment it is usually an adjustable control. The correct setting is found by turning the control clockwise until the noise stops, but no further. If the control is adjusted beyond this point, the receiver will be desensitised and may not receive weak signals. Channel Selector. This control is used to select the channel on which transmission or reception is required. Dual Watch (DW). This control will be found on the majority of VHF equipment. On operation it will permit the operator to keep listening watch on a working channel and Channel 16. This is NOT to be confused with scanning VHF channels. Power Selector. This control varies the power of the transmitted signal. International regulations restrict the output power of Marine VHF to 25 Watts maximum. On VHF marine equipment it may be marked ‘25w/1w’ (25 Watts or 1 Watt) or ‘high/low’. The use of more power than is required to communicate satisfactorily is a breach of the International Radio Regulations, may cause unnecessary interference and drains the battery supplying the equipment at a faster rate. International/USA Control. This control may be found on some VHF marine equipment. It is provided by the manufacturer to permit communications with stations in the USA which do not conform to the international VHF channel plan. It is important that this control is kept in the ‘international’ position at all times unless in the coastal waters of the USA. Some manufacturers of marine VHF supplied to Australian operators my have ‘International’ substituted by ‘Aus’. Marine MF/HF:

Transceiver On/Off Control. Generally speaking, the on/off control enables power to both the transmitter and receiver. Some transceivers may also have a separate transmitter on/off control enabling receiver operation with the transmitter in a standby condition. RF Gain Control. This control will only be found on some MF/HF and 27 MHz transceivers. It is used to vary the strength of received radio signals and has an effect similar to the volume control. However, except when receiving unusually strong signals, it should be kept close to maximum and the volume control used to adjust the audio signal to a comfortable level. AM/SSB Emission Control. (on some MF/HF equipment, this control may be marked H3e/J3e). This control will be found on most MF/HF transceivers and on those 27 MHz transceivers with a single sideband option. It controls the mode of transmission and reception. See paragraphs 35.1 to 35.4 for further information. Clarifier. This control will be found on some MF/HF transceivers and those 27 MHz transceivers which are fitted with a single sideband option. It provides a means of fine-tuning incoming single sideband signals that sound distorted or ’off station’. It has no effect on transmitted signals.

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On SSB transceivers not fitted with a clarifier control, another method of fine-tuning incoming signals will be provided. Mute Control. This allows the operator to switch off annoying background atmospheric or radio interference, while permitting the operator to hear a close-by wanted radio station. The level of muting is pre-set and is switched either on or off. noise Limiter. (NOISE BLANKER). This control may be switched on to minimise the effect of loud static or ignition interference on received signals. It should be used with care as it may also desensitise the receiver to wanted signals. Antenna or Aerial Tuning Unit (ATU). This unit will be found only with MF/HF equipment and may be separate from or incorporated with the transceiver. An ATU is necessary to adjust the ‘electrical’ length of the antenna to ensure that maximum transfer of power from the transmitter can take place on different frequency bands. ATUs may tune automatically or require manual adjustment. Operators should ensure the equipment is tuned whenever the transmitter frequency is changed. Radiotelephony Alarm Signal Generating Device (ASGD). This control is found only on some MF/HF transceivers. Operation causes the radiotelephony alarm signal to be transmitted. A test function may also be provided to permit the function to be tested without transmission. Microphone Press-to-Talk Control. This spring-loaded control is located on the microphone or handset. When pressed, it allows the transmission of signals. When released, the equipment is returned to the receive mode. 73.2 It is likely that marine equipment manufacturers will offer controls other than those detailed here. It is important that operators familiarise themselves with the function and effect of all controls. This is particularly important with equipment capable of digital selective calling (DSC).

Section 14 General Care and Maintenance of Marine Radio Equipment 74. Care of Transceivers 74.1 Radio equipment manufactured for marine use is designed for harsh environmental conditions. However, transceivers should always be protected from rain and spray by being positioned inside a deckhouse or cabin. They should be securely fastened to the vessel to prevent damage in heavy weather. 74.2 After use, a microphone associated with a transceiver should always be replaced in its holder or bracket. For a variety of reasons, failure to do this can result in the transmitter being activated through inadvertent pressure on the microphone press-to-talk switch and without the knowledge of the operator. As a consequence, all background noises, including conversations made in the vicinity of the transceiver, are transmitted. Use of the frequency by other nearby stations cannot take place until the station responsible has been located and the problem corrected. 74.3 It is normal practice to locate fuses in the leads connecting the transceiver to the battery supplying the power. The purpose of these fuses is to ‘blow’ should the transceiver malfunction and start to draw a current in excess of the fuse rating. By doing this, the fuses protect the equipment from serious damage and the possibility of fire. 74.4 Vessel owners should be aware that, on occasions, a power supply fuse will blow when the transceiver is not malfunctioning and for no apparent reason. It is recommended that a supply of fuses of the manufacturer’s recommended value be carried on board for such circumstances. However, if the replacement fuse also blows, this is a warning of a serious problem. At this stage, a vessel operator should consider whether to continue the voyage or trip. Use of higher rating fuses, silver paper or pieces of wire may result in expensive damage and, possibly, fire.

75. Care of Antennas 75.1 Antennas used in conjunction with MF/HF equipment may be of the long wire or vertical whip type. 75.2 Antennas used with 27 MHz and VHF marine equipment are normally short vertical whip types which are usually mounted as high up as possible, at the top of a mast for example. 75.3 whip antennas are manufactured specifically for the VHF or MF/HF marine bands and are not interchangeable. 75.4 Insulators used with antennas should be periodically inspected for cracking or deterioration and replaced if necessary. Salt build-up on insulators will reduce their efficiency and should be regularly cleaned off with fresh water (taking care to ensure that the equipment is turned off and fuses removed beforehand). Insulators should never be painted.

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75.5 Ultra-violet radiation will cause fibre-glassed whip antennas to deteriorate after many years of service to a point where moisture can penetrate the layers. This will seriously affect radiation efficiency and replacement or re-fibre-glassing will be necessary. 75.6 On yachts, the practice of insulating a backstay will provide a reasonably efficient long-wire antenna. However, it must be considered that, should the yacht be dismasted, the antenna will also be lost. Where a backstay is used, it is recommended that yachts carry a spare whip antenna, which can be quickly mounted and connected.

Section 15 Faults in Marine Radio Equipment 76. General 76.1 Regular inspection and maintenance of the antenna, transceiver and battery power supply will minimise the likelihood of faults occurring at sea. 76.2 However, the owners of small vessels should be prepared to deal with minor faults on their marine radio equipment. 76.3 Faults can be usually divided into three categories: - faults occurring on the antenna system; - faults occurring in the transceiver; and - faults occurring with the battery power supply.

77. Antenna System Faults 77.1 Antenna system faults may include: - poor or broken connections in the antenna or radio earth system; - the antenna broken or short-circuited, or a fracture inside a whip antenna; and - broken, deteriorated or contaminated insulators. 77.2 A poor or loose connection between the transceiver and the antenna will affect both transmitted and received signals. Received signals will be intermittent and the loudspeaker will ‘crackle’. Other stations may report broken transmitted signals. With MF/HF equipment, normal tuning positions on the antenna tuning unit (ATU) may vary. 77.3 A completely broken connection between transceiver and antenna will result in receiver hiss, but few or no signals. Transmission will not be possible. 77.4 an antenna which is short-circuited to a vessel’s metal hull or superstructure is likely to produce similar results. 77.5 On vessels equipped with mF/HF equipment, faults occurring on the radio earthing system, although relatively uncommon, may cause transmitting problems. The most likely faults are breaks in the metallic connections at the transceiver, antenna tuning unit (ATU) or at the radio earth plate itself. On rare occasions a radio earth plate may become detached from the hull. 77.6 Radio earthing problems will usually be evident by abnormal or changing ATU tuning positions. Often a faulty (or non-existent) radio earth may cause the metallic parts of the transceiver and ATU to become ‘live’ during transmission. A sharp, burning sensation may be felt when in direct contact with these parts, which should be avoided.

78. Transceiver Faults 78.1 A transceiver fault is usually obvious and probably will require specialist attention. A faulty microphone cord may prevent transmission, but not affect reception.

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79. Power Supply Faults 79.1 Power supply faults may include: - loose or corroded battery terminals; - a discharged or defective battery; - blown fuses; and - loose or frayed connecting cables. 79.2 Loose battery connections will be evident by intermittent operation of the receiver and transmitter, and flickering dial lights or channel display. 79.3 A battery which is defective or close to discharged may be able to supply sufficient current to operate the receiver but not the transmitter. Should the transmitter fail to operate and dial lights or channel display dim significantly when the transmit button is operated, the battery should be suspected. Corrosion at the battery terminals may cause similar symptoms. 79.4 Blown fuses will mean that the equipment will fail to operate in any way. Frayed power supply cables touching together or to metal parts of the vessel are a frequent cause of blown fuses.

NOTES

MARINE RADIO OPERATORS HANDBOOK

ommunication stions Section 11: Types of Marine Radio Equipment 65.1 Marine communications equipment operates on which frequency bands?

66.2 What communications system is recommended for mariners undertaking lengthy coastal or overseas voyages?

66.1 What are the advantages of MF/HF marine 68.1 What are the disadvantages of marine equipment? VHF?

SECTION 12: Component Parts of Marine Radio Equipment 69.1 Marine radio equipment is made up of how many major parts? 69.2 Why is each major part important? 70.3 What is the function of the equipment fuse/s?

71.3 A transmitter and a receiver, when combined into one unit is called a ....................? 72.1 What are the functions of the antenna?

SECTION 13: Transceiver Controls 73.1 List 6 of the controls commonly found on VHF transceivers.

What is the recommended transmit power What is the purpose of the Antenna Tuning setting? Unit (ATU)?

What is the purpose of the Squelch control?

73.1 List the major controls commonly found on MF/HF transceivers.

What mode is required for all marine radiotelephony frequencies?

What mode is required for radiotelephony distress transmission on 2182 kHz?

What is the Mute control?

What mode is required for a routine call on 2182 kHz?

what VHF channels are monitored with the Dual watch control activated?

What is the maximum power setting for marine VHF?

SECTION 14: General Care and Maintenance of Marine Radio Equipment 74.2 Once transmission has ceased, where should the microphone be placed? 74.3 What is the function of a fuse located in the connecting leads between the battery and a transceiver? 74.4 What is the general recommendation as to the type and rating of fuses and their replacements?

74.4 Who recommends the correct rating of radio equipment fuses and their spares? If a replacement fuse blows (ruptures), what does this indicate to you? 75.1 List two (2) types of antennas used for MF/HF on a ship installation. 75.2 What type of antenna is commonly used for marine VHF installations?

75.5 What can slowly and gradually damage the fibreglass whip antenna insulation properties of a vertical whip? 75.6 What is a potential disadvantage of yachts using a wire backstay antenna for MF/HF? What is recommended to be carried as a spare antenna?

SECTION15: Faults in Marine Equipment 77.1 List 3 (three) places in an antenna installation where faults can occur. 77.2 If received signals sound “broken”, what could be the cause?

77.6 What symptoms can result in the transceiver if the earth connection has been broken?

79.2 What might cause you to suspect a loose battery connection to the transceiver?

79.3 If the battery condition is close to 78.1 What is the main effect of a broken discharged, how might this become microphone cable? apparent? 77.3 What symptoms could result with the loss of the entire antenna? 79.1 In a radio power supply installation, where 79.4 What is the effect of a blown fuse on are faults likely to occur? transceiver operation? 77.4 What would the result of an antenna being “short-circuited” to the vessel’s hull?

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CHAPTER 6

DIGITAL SELECTIVE CALLING

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Section 16 General Information 80. Introduction 80.1 The Global Maritime Distress and Safety System (GMDSS) has meant the introduction of a variety of automated radiocommunications technologies. One of these is known as digital selective calling or DSC. This technique has been used for several years by large trading vessels. It is expected that its use will gradually become commonplace by small vessels and eventually may replace radiotelephony techniques for initial distress, urgency and safety calls on the MF/HF marine and VHF bands. with time, traditional labour-intensive aural watchkeeping by ships and Limited Coast Stations may change to automated DSC electronic watchkeeping, as the Maritime Communication Stations have done. 80.2

Although Maritime Communication Stations provide a service in the HF marine band, the use of MF/HF DSC by small vessels in Australia is still in its infancy. Many Limited Coast Stations do not support this form of communication for small vessels. DSC on VHF is becoming more popular. However, normal radiotelephony procedures are likely to be the primary means of initiating priority calls to and from small vessels for some years.

80.3

Maritime Communication Stations no longer monitor the MF and VHF radiotelephony bands. Therefore, HF radiotelephony equipment fitted with DSC is recommended above other options.

80.4 While the main use of DSC by small vessels will be for distress, urgency and safety purposes, the technique may also be used for routine calling. 80.5 DSC is a semi-automated means of establishing initial contact between stations. Once this contact has been established, standard radiotelephony procedures are used for subsequent communications (see Appendix 6). DSC can be used to initiate ship to ship, ship to shore, and shore to ship communications. Information transmitted by DSC is generally known as a DSC Alert. 80.6 A DSC Alert is a brief burst (typically seven seconds on MF/HF, and 0.5 second on VHF) of digitised information transmitted from one station to alert another station or stations, and to provide some basic information. 80.7 DSC Alerts are transmitted on MF/HF and VHF marine frequencies specifically reserved for this type of transmission. The DSC Alert indicates the identity of the calling station and the purpose of the call. 80.8 The way in which the transmitted DSC Alert is encoded by the initiating station selects which station or stations will decode the information. whilst all stations listening on the DSC frequency will receive the alert, only the station(s) selected by the transmitting station will actually decode and have the message available. This will be signalled by an audible and/or visual alarm to alert the operator. 80.9

DSC Alerts bearing the distress priority will be decoded by all stations receiving the alert.

80.10 Programming of a DSC message prior to transmission is performed manually by an operator using the DSC receiver controller front panel controls. Received information is decoded and made available in alphanumeric form on a liquid crystal or fluorescent display incorporated in the equipment. 80.11 The greatest advantage of DSC is the automation of the transmission and reception of initial distress, urgency and safety alerts. A single button-push by an operator could initiate such a distress alert, whilst the necessity for ship and shore operators to manually maintain a listening watch on distress and calling frequencies is removed. 80.12 Importantly, DSC used in small vessels will enable communications compatibility between large and small vessels. The International Maritime Organisation (IMO) has strongly recommended that recreational and other small vessels equip with GMDSS compatible equipment. DSC communications fulfils this requirement and will permit direct ship to ship alerting regardless of the size of the ship. However, in recognition that DSC will take some years to fully penetrate the small vessel market, the IMO has extended compulsory VHF channel 16 radiotelephony watchkeeping on the bridge of large trading vessels indefinitely. Compulsory watchkeeping on 2182 kHz on such vessels was discontinued in early 1999. 80.13 Vessels proceeding overseas should note that DSC facilities are well developed in many parts of the world and listening watches on radiotelephony distress and calling frequencies may have been discontinued by some countries. 80.14 With the gradual change to DSC, the problem of hoax distress calls is likely to be eliminated. It is impossible to transmit a DSC alert without electronically identifying the initiating vessel.

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81. DSC-Capable Equipment 81.1 Small vessel MF/HF transceivers with DSC capability and VHF transceivers with DSC facilities meeting Australian standards are available, but may be of more limited use. eventually it is expected that DSC will be common in all small vessel marine MF/HF and VHF transceivers. Some manufacturers may provide kits for adding DSC capability to existing MF/HF and VHF radiotelephony-only transceivers. 81.2 W whilst DSC controllers for large vessels are capable of a full range of DSC services, those intended for the recreational and small vessel market generally have fewer options. However, all contain the ability to use DSC for distress alerting, distress and routine call acknowledgement, and all-stations and single-station alerting. The ability to transmit position information, either from a GPS receiver interface or from manual entry, is also available. 81.3 Search and rescue authorities strongly recommend connection of a ship station DSC controller to a GPS receiver to ensure that accurate and current position information is automatically transmitted in the case of a Distress Alert. 81.4 Some MF/HF controllers may offer the option of sequentially scanning all MF/HF DSC frequencies for alerts. 81.5 Whilst DSC operational procedures are not difficult, and in most cases simply parallel standard radiotelephony procedures, operators of DSCcapable equipment must ensure that they are entirely familiar with the manufacturer’s instructions concerning controls and programming, particularly those concerning transmission and reception of priority calls. 81.6

Radiotelephony-only MF/HF and VHF transceivers are not capable of encoding or decoding DSC Alerts.

81.7 DSC should not be confused with the proprietary selective calling systems (selcal) presently available on some MF/HF marine transceivers. These systems are not compatible with international DSC signalling standards. 81.8

DSC MOB (man overboard) - DSC equipment send DSC alerts that include vessel’s MMSI, its position (obtained from GPS or by manual input) as well as the nature of the emergency that the user can select from a pre-defined list. One of the options on the list is MOB, therefore a dedicated VHF DSC transmitter sending MOB DSC alert can act as a DSC MOB device.

82. DSC Identification 82.1 To use DSC techniques, a MF/HF or VHF DSC controller must be permanently programmed with a unique nine digit identification number known as a Maritime Mobile Service Identity (MMSI). This can be regarded as the electronic equivalent of a radiotelephony call sign and uniquely identifies that station. 82.2 The MMSI is automatically included in all DSC transmissions from a station and electronically identifies that station to the receiving station(s). The MMSI also acts as an electronic filter whilst the DSC is operating in the watchkeeping mode to ensure that only routine DSC Alerts intended for that station are actually decoded and displayed. The filter is deactivated when any DSC Alert carrying a distress priority indicator is received, as these messages are implicitly addressed to all stations. Similarly, DSC urgency and safety alerts which are not specificially addressed to a particular station will be received by all stations that are within radio range and keeping a DSC watch.

82.3

Three of the nine digits of a MMSI identify the country of origin. In the case of a Maritime Communication Station or Limited Coast Station, these digits indicate the country of location, and in the case of a ship station, the country of registration. The remaining six digits uniquely identify the station itself. The three digits identifying the country of origin are known as Maritime Identification Digits or MIDs. Australia’s MID is 503 with these figures forming the first three digits for ship stations, and third to fifth digits for Maritime Communication Stations or Limited Coast Stations.

82.4

An Australian ship station MMSI will be in the form 503xxxxxx where x is any ﬁgure from 0 to 9.

82.5

An Australian Coast Station MMSI will be in the form 00503xxxx where the first two figures are zeros and x is any figure from 0 to 9. The MMSI for both Australian Maritime Communication Stations is 005030001.

82.6

At present, any person purchasing a MF/HF or VHF transceiver with DSC capability and wishing to use the option must obtain a MMSI which is issued by AMSA. This must then be programmed into the transceiver. See the AMSA website for more information (https:// www.amsa.gov.au/forms-and-publications/AMSA89.pdf).

MARINE RADIO OPERATORS HANDBOOK

MMSI format

NOTES

DSC transceivers

Note: x or y may be any ﬁgure 0 through 9

Ship stations

503xxxxxx

① Maritime Survivor Locating Systems (AS/NZS 4869.2)

Type of Station DSC transceivers

Handheld Portable VHF DSC (Australia only)

8503xxxxx

Group of ship stations

0503xxxxx

Coast station

00503xxxx

Maritime Survivor Locating Systems Transmitters ①

5038xxxxx (Australia only)

Automatic Identification Systems (AIS) AIS Class A/B transceivers

503xxxxxx or 503xxx000

AIS Base Stations

00503xxxx

Physical AIS aids to navigation (AtoN) ②

995031xxx

Virtual AIS aids to navigation (AtoN) ③

995036xxx

AIS on craft associated with parent ship ④

98503xxxx

AIS-SARTs (AIS-Search and Rescue Transmitters) ⑤

972xxyyyy

AIS on SAR aircraft ⑥

111503xxx

② AIS ﬁtted to physical Aids to Navigation (AtoN) such as floating buoys and beacons. ③ AIS base stations can broadcast a non-physical “virtual” AtoN at a particular location when no physical AtoN exists. ④ AIS on workboats or other vessels deployed from a parent vessel. ⑤ AIS-SARTs are survival craft SAR-locating devices which

⑥ AIS on search and rescue aircraft (SAR) is a variant of AIS speciﬁcally for SAR. AIS can also be used for safety-related purposes on non-SAR aircraft (such as marine pilot-transfer helicopters).

82.7 A full international list of MIDs appears in Appendix 43 of the Radio Regulations published by the International Telecommunication Union.

83. Frequencies for DSC Distress, Urgency and Safety Alerts 83.1 Frequencies have been internationally allocated in the MF/HF and VHF marine bands for DSC distress, urgency and safety alerts. In each case there is a radiotelephony frequency directly associated with the DSC frequency for communications subsequent to the DSC alert. Only the HF DSC frequencies indicated with an asterisk (*), are monitored by Australian Maritime Communication Stations wiluna and Charleville. The other DSC frequencies may not be monitored in your area. The DSC and associated radiotelephony frequencies are:

DSC frequency & associated radiotelephony frequency: DSC

Radiotelephony

2187.5 kHz

2182 kHz

4207.5 kHz*

4125 kHz

6312.0 kHz*

6215 kHz

8414.5 kHz*

8291 kHz

12577.0 kHz*

12290 kHz

16804.5 kHz*

16420 kHz

VHF Ch 70

VHF Ch 16

83.2 The MF/HF DSC frequencies indicated above are reserved exclusively for DSC alerts associated with distress, urgency and safety messages. 83.3 Marine VHF channel 70 may additionally be used for routine station-to-station DSC alerts. 83.4 DSC is not used in the 27 MHz marine band, and Australian Maritime Communication Stations no longer monitor the MF and VHF bands. 83.5 Unless the frequency/channel is specifically indicated in the DSC alert, radiotelephony communications should follow on the associated radiotelephony distress and calling frequency, for example, on 2182 kHz after a DSC alert on 2187.5 kHz, or on VHF channel 16 after a DSC alert on VHF channel 70. 83.6 Some DSC equipment will automatically change frequency/channel on reception of an alert. 83.7 Radiotelephony transmissions are prohibited on the MF/HF DSC frequencies and the VHF channel allocated for DSC.

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84. Frequencies for Routine DSC Alerts 84.1 DSC techniques may also be used by ship stations for the purposes of setting up commercial (public correspondence) communications. Frequencies have been internationally allocated for these purposes. 84.2 DSC equipment allows a ship station to select a particular shore station (by its MMSI) and to programme in a desired telephone number. The burst of data transmitted enables fully automated contact between the vessel and the shore telephone subscriber. 84.3 DSC facilities for public correspondence are not currently provided in Australia. 84.4 routine ship to ship VHF Dsc alerts can be made only on channel 70 and will require the sender to know and programme in the MMsi of the vessel to be called.

85. Watchkeeping on DSC Distress, Urgency and Safety Frequencies 85.1 Australian Maritime Communication Stations maintain a continuous watch only on the HF DSC frequencies identiďŹ ed in 83.1 for distress, urgency and safety alerts. 85.2 Maritime Communication Stations do not provide watchkeeping on MF (2187.5 kHz) or on VHF channel 70. 85.3 As DSC-capable equipment penetrates the small vessel market it is expected that Limited Coast Stations operated by volunteer marine organisations may provide some DSC watchkeeping on MF/HF and VHF for distress, urgency and safety alerts. This is likely to be in addition to traditional loudspeaker watchkeeping on radiotelephony frequencies and channels. 85.4 Large trading vessels maintain a continuous watch on VHF channel 70, 2187.5 kHz, 8414.5 kHz and one other HF DSC frequency appropriate to the time of day and position of the ship. Compulsory watchkeeping by these vessels on 2182 kHz has been discontinued but watchkeeping on VHF channel 16 has been extended. 85.5 small vessels with Dsc capability may scan the Dsc frequencies appropriate to the type of radio equipment carried and their area of operation. However, it must be kept in mind that it will be many years before DSC capability is universal in small vessel equipment. 85.6 Because of the large distances that radio signals can travel, distress alerts from all over the world may be received by stations scanning the higher HF DSC frequencies. Once such an alert is received a station has an obligation to continue its involvement until it can be certain that it has no part to play. Ships and Limited Coast Stations may therefore wish to limit their DSC scanning to, for example, 8 MHz during the day, and 2 and 4 MHz during hours of darkness. 85.7 there is a high probability that a distress alert received on VHF channel 70 or on 2187.5 kHz will be local and it is recommended that these frequencies are monitored if a DSC facility is ďŹ tted.

86. Information Contained in a DSC Alert 86.1 A DSC Alert may contain all or some of the following information as digitised data: - the identity of the calling station (MMSI); - the station being called (a specific station or all stations); - the priority of the alert: distress, urgency, safety or routine; and - the position of the calling station and an indication of when the position was last updated. 86.2 The alert may also contain data indicating the frequency or channel on which subsequent communications are to be conducted. Normally, but not necessarily, this is the associated radiotelephony frequency/channel (see paragraph 83.1). However, if frequency/channel information is not contained in the alert, it is always the associated radiotelephony frequency or channel. 86.3 Position information can be inserted automatically by a connection between the DSC equipment and a GPS receiver, or by manual entry. If no automatic input or manual update is available, position the distress and time of update information will default to 9999999999 and 8888 respectively. 86.4 Priority DSC alerts (distress, urgency and safety) are the same as their corresponding priority voice communications with respect to definitions, authority to transmit, and obligations to acknowledge (see Chapter 10).

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87. DSC Alert Formats 87.1 The international DSC system provides for the following types of alerts: - distress alert - these calls are implicitly addressed to all stations. The alert contains the vessel’s MMSI, position information and its validity, and possibly an indication of the nature of the distress; - distress alert acknowledgement - normally only sent by Maritime Communication Stations and Limited Coast Stations in response to a distress alert. May be used by ship stations only under certain circumstances; - distress alert relay - normally only sent by Maritime Communication Stations and Limited Coast Stations. May be used by ship stations only under certain circumstances; - all stations (all ships) - used to alert all stations that an urgency or safety broadcast will follow and; - selective (single station) - used to alert a particular station to an urgency or safety message to follow. Some small vessel equipment may not permit the inclusion of the urgency or safety priority. This call is also used to alert another station to a routine call. The MMSI of the desired station must always be known and manually entered into the transceiver. The format of the MMSI indicates the type of station being called. 87.2 It is essential that operators of DSC-capable equipment are familiar with the particular alert options provided on the transceiver in use. It should be noted that the ‘all station’ format includes Maritime Communication Stations and Limited Coast Stations. Similarly the ‘selective’ format is used to address a particular Maritime Communication Station, Limited Coast Station or a ship station. 87.3 Some small vessel DSC-capable transceivers may not provide a distress alert relay format.

88. DSC Distress Alert Procedures 88.1 A distress alert from a vessel may be transmitted only on the authority of the master, skipper, or the person responsible for the safety of that vessel. It has absolute priority over all other transmissions and indicates that the vessel or person using it is threatened by grave and imminent danger and requests immediate assistance. All stations which receive a distress alert must immediately cease all transmissions capable of interfering with distress communications. 88.2 The distress alert should include the vessel’s last known position and an indication of when it was last updated. 88.3 Distress position information will normally be included automatically from an interface with satellite positioning equipment such as GPS. Some DSCs may permit position information to be inserted manually. Some DSCs may also offer the option of selecting from a menu and transmitting the nature of distress, for example, ‘on fire’, ‘collision’. 88.4 Once selected and initiated, a DSC distress alert will continue to be automatically repeated until terminated by the operator, or when a DSC distress alert acknowledgement generated by another station is received and decoded by the distressed vessel. 88.5 The DSC distress alert from a vessel is transmitted as follows: - select the appropriate MF/HF or VHF DSC controller; - select the appropriate distress option; - i.e. hold down the distress button or; - if time permits, edit the distress alert by keying in: - position information (not necessary with a GPS interface); - nature of distress (from the standard menu if provided); - mode for subsequent communications; either radiotelephony or telex. Choose radiotelephony; - select whether the alert will be transmitted on a single distress frequency or all the distress frequencies. The VHF DSC distress alert is transmitted on channel 70 only; - press the distress button to transmit the alert; - at the MF/HF or VHF transceiver, ensure the appropriate radiotelephony, distress frequency or VHF channel 16 is selected; - if time permits, the two tone radiotelephony alarm signal should be transmitted on the appropriate MF/HF radiotelephony distress frequency; - transmit the distress call and message as described in paragraphs 125 - 126 of this handbook. 88.6 Whilst these procedures may appear time-consuming, it is possible that all the vital information for the distress alert can be transmitted by a single button push. In a worst-case scenario where any further radio transmissions are not possible, the distressed vessel can be reasonably sure of having broadcast a distress alert containing its identity and its position.

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88.7 All of the information transmitted in a DSC distress alert is decoded and displayed on other DSC-capable receivers scanning the frequency/ channel and is accompanied by an audible alarm to alert the operator. The broadcast of the radiotelephony distress call and message on a radiotelephony frequency/channel further alerts and advises stations of the distress situation. Steps to transmit a DSC distress alert and subsequent distress call and message.

Select DSC Distress Channel

Initiate DSC Distress Alert

Change to Associated Radiotelephony channel

Transmit Radiotelephony Distress Call and Message

89. ACKNOwLeDGEMeNT OF ReCeIPT OF A DSC DISTReSS ALeRT ON 2187.5 KHz OR VHF CHANNeL 70 89.1 Ship stations receiving a distress alert from another vessel on 2187.5 kHz or VHF channel 70 should take note of the contents and immediately listen on 2182 kHz or VHF Channel 16 for the MAYDAY message that should follow. 89.2 If the MAYDAY message is received, and the receiving ship is able to provide assistance, then a radiotelephony acknowledgement (ReCeIVeD MAYDAY, see paragraph 130) should be sent to the distressed vessel on 2182 kHz or VHF channel 16, and an appropriate Maritime Communication Station or Limited Coast Station advised. 89.3 If the receiving ship is not able to provide assistance, and other stations are heard indicating involvement in the distress situation, then no acknowledgement should be sent. 89.4 In situations where a ship station has received a DSC distress alert on 2187.5 kHz or VHF channel 70 and a) no MAYDAY message has been heard on 2182 kHz or VHF channel 16 within 5 minutes; b) no other station is heard communicating with the distressed vessel; and c) the DSC distress alert continues to be received; then the ship which received the DSC distress alert should transmit a radiotelephony acknowledgement, substituting the distressed vesselâ&#x20AC;&#x2122;s MMSI for its name and call sign, if necessary. Immediately following this, the receiving ship must contact an appropriate Maritime Communication Station or Limited Coast Station and fully advise it of the situation. 89.5 In situations where a ship station has received a DSC distress alert on 2187.5 kHz or VHF channel 70 and no MAYDAY message has been heard on 2182 kHz or VHF channel 16 within 5 minutes; and a) no other station is heard communicating with the distressed vessel; and b) the DSC distress alert is not continuing then no acknowledgement should be sent. The receiving ship should immediately contact an appropriate Maritime Communication Station or Limited Coast Station and fully advise it of the situation.

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Actions by ships upon reception of a DSC Distress Alert on VHF channel 70 or 2187.5 kHz.

DSC Distress Alert is received

Listen on VHF Channel 16 or 2182 kHz for 5 minutes

Note: In situations where your own vessel is unable to assist but other stations are not heard communicating with the vessel in distress, then a coast or Limited Coast Station must be advised immediately.

Is MAYDAY message heard?

YES

Enter details in radio log

Are other stations communicating with the distressed vessel?

YES

Is own vessel able to assist?

YES

Is the DSC distress alert continuing?

YES

Acknowledge alert by radiotelephony to distressed vessel on VHF 16 or 2182 kHz

Inform Maritime Communication or Limited Coast Station

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90. z 90.1 Ship stations receiving a DSC distress alert from another vessel on 4207.5, 6312, 8414.5, 12577 or 16804.5 kHz should take note of the contents and immediately listen on the associated radiotelephony frequency for the MAYDAY message that should follow. 90.2 If the MAYDAY message is received and the receiving ship is able to provide assistance, then an appropriate Maritime Communication Station or Limited Coast Station should be contacted with an offer to provide that assistance. 90.3 If the receiving ship is not able to provide assistance, and other stations are heard indicating involvement in the distress situation, then no further action need be taken. 90.4 In situations where a ship station has received a DSC distress alert on 4207.5, 6312, 8414.5, 12577 or 16804.5 kHz and a) no MAYDAY message has been heard on the associated radiotelephony channel within 5 minutes; and b) no other station is heard communicating with the distressed vessel; then the receiving ship should transmit a DSC distress alert relay to an appropriate Maritime Communication Station or Limited Coast Station.

Actions by ships upon reception of a DSC distress alert on 4207.5, 6312, 8414.5, 12577 or 16804.5 kHz

DSC Distress Alert is received

Listen on associated Radiotelephony frequency for 5 minutes

Note 1: In situations where your own vessel is unable to assist but other stations are not heard communicating with the vessel in distress then a Coast or Limited Coast Station must be advised immediately. Note 2: See caution in paragraph 91.6.

Is MAYDAY message heard?

YES

Are other stations communicating with the distressed vessel?

Transmit DSC distress alert relay to Maritime Communication and Limited Coast Station

YES

Is own vessel able to assist?

YES

Contact Maritime Communication or Limited Coast Station to offer assistance

NO Enter details in radio log

90.5 It should be noted that some large trading vessels have the capability, and may elect, to conduct communications subsequent to a DSC distress alert by telex over radio (also known as narrowband direct printing or NBDP) on a frequency dedicated to this use. This will usually be apparent to a ship or Limited Coast Station by reference to the final piece of DSC information received and displayed. If this reads J3e then the vessel will be using radiotelephony for subsequent traffic. If it reads F1B then the vessel will be using telex over radio

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91. lay 91.1 Maritime Communication Stations, after having received and acknowledged a DSC distress alert, will normally retransmit the information as a DSC distress alert relay. 91.2 Ship stations should normally consider transmitting a DSC distress alert relay only when a distress alert has been received on 4207.5, 6312, 8414.5, 12577 or 16804.5 kHz and no other station is heard communicating with the distressed vessel on the associated radiotelephony channel. The DSC distress alert relay must be addressed to an appropriate Maritime Communication Station or Limited Coast Station. The distress alert relay must not be addressed to ‘all ships’. 91.3 Ship stations receiving a DSC distress alert on either 2187.5 kHz or VHF Channel 70 should not transmit a DSC distress alert relay. Instead, a radiotelephony acknowledgement should be made to the distressed vessel on 2182 kHz or VHF channel 16, and the nearest Maritime Communication Station or Limited Coast Station should be informed. 91.4 Ship stations may transmit a DSC distress alert relay in situations where a distress alert has not been received. However, this is restricted to situations where it is learnt that another vessel in distress is not able to transmit the distress alert and the master of the ship not in distress considers that further help is necessary. In this case the DSC distress alert relay should be addressed to 'all ships' or, preferably, addressed to an appropriate Maritime Communication Station or Limited Coast Station. 91.5 Some small vessel DSCs may not provide a DSC distress alert relay facility. In these situations a MAYDAY RELAY message on the associated radiotelephony frequency may be substituted and every endeavour made to inform a Maritime Communication Station or Limited Coast Station. In the situation detailed in paragraph 91.2, the MAYDAY RELAY message should be transmitted on a radiotelephony frequency or channel considered appropriate to the situation. A MMSI may be used in cases where a vessel’s name and call sign are not known. 91.6 Operators should exercise careful judgement in relaying DSC distress alerts received on the higher frequencies as these could be received from and by vessels at distances of thousands of miles. Indiscriminate relaying will merely increase the area that stations are alerted without performing any useful function.

92. lay 92.1 Where considered appropriate, ship stations receiving a DSC distress alert relay from another station should acknowledge receipt by radiotelephony on the associated radiotelephony frequency/channel using the procedures detailed in paragraph 130 of this handbook.

93. Cancellation of an Inadvertent DSC Distress Alert 93.1 Unlike radiotelephony procedures, it is possible to inadvertently initiate a DSC distress alert. Should this occur then it is essential that the initiating station carry out the following procedures: - immediately switch off the DSC unit and transceiver in question (this will cancel any automatic repeats of the DSC distress alert transmission which would normally continue until a DSC acknowledgement is received); then - switch the transceiver back on and select the radiotelephony frequency/channel associated with the DSC frequency/channel on which the inadvertent alert was transmitted; then - broadcast an ‘all stations’ radiotelephony message giving the vessel’s name, call sign and MMSI, and cancel the distress alert, giving an approximate time of the inadvertent transmission. If the inadvertent DSC distress alert was transmitted on several frequencies, it is necessary to broadcast cancellations on all associated radiotelephony frequencies. 93.2 If for some reason these procedures cannot be carried out then the station must use other means to advise authorities that the alert was accidental. 93.3 Failure to appropriately advise authorities may result in the distress alert being treated as genuine and lead to a waste of valuable search and rescue resources. A ship station operator will not be penalised for reporting an inadvertent distress alert.

94. Transmission of a DSC Urgency Alert 94.1 A DSC urgency alert may be transmitted only with the authority of the master or skipper, or the person responsible for the safety of the vessel. It indicates that the station has a very urgent message to transmit concerning the safety of a vessel or aircraft, or the safety of a person.

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94.2 The transmission of a DSC urgency alert by Maritime Communication Stations, Limited Coast Stations and ship stations is carried out in the following manner: - the DSC urgency alert on a DSC frequency/channel; followed by - the transmission of the urgency call and message on the indicated working radiotelephony frequency/channel using radiotelephony procedures. 94.3 The DSC urgency alert is carried out by: - selecting the appropriate MF/HF or VHF DSC controller; - selecting the ‘all ships’ or ‘selective’ call format; - selecting the urgency priority; - setting the DSC controller to the working frequency for subsequent communications; - setting the DSC controller to the appropriate DSC distress, urgency or safety frequency (2187.5 kHz or VHF channel 70) and; - transmitting the DSC urgency alert. 94.4 The transmission of the urgency call and message should follow immediately on the associated radiotelephony frequency/channel using the radiotelephony procedures detailed in paragraph 134 of this handbook. 94.5 Stations receiving a DSC urgency alert should not acknowledge receipt but simply tune their transceiver to the associated radiotelephony frequency/channel and await the radiotelephony transmission. Steps to transmit a DSC urgency alert and subsequent urgency call and message.

Select DSC Distress Channel

Initiate DSC Urgency Alert

Change to Associated Radiotelephony channel

Transmit Radiotelephony Urgency Call and Message

95. Transmission of a DSC Safety Alert 95.1 The transmission of a DSC safety alert indicates that the station has a message to transmit concerning an important navigational or weather warning. 95.2 The transmission of a DSC safety alert by Maritime Communication Stations, Limited Coast Stations and ship stations is carried out in the following manner: - the DSC safety alert on a DSC distress or safety frequency/channel; followed by - the radiotelephony announcement on the associated radiotelephony frequency/channel that a safety message will follow on a working frequency/channel; followed by - the transmission of the safety call and message on a radiotelephony working frequency/channel. 95.3 The DSC safety alert is carried out by: - selecting the appropriate MF/HF or VHF DSC controller; - selecting the ‘all ships’ or ‘selective’ call format; - selecting the safety priority; - setting the DSC controller to the working frequency for subsequent communications; - setting the DSC controller to the appropriate DSC distress, urgency or safety frequency (2187.5 kHz or VHF channel 70); and - transmitting the DSC safety alert. radiotelephony announcement that a safety message will follow on a working frequency may follow immediately on the associated The radiotelephony distress or safety frequency/channel using the procedures detailed in paragraph 135 of this handbook. The radiotelephony working frequency/channel may be indicated in the safety alert. 95.5 The transmission of the safety call and message should follow immediately on the chosen radiotelephony working frequency/channel using the procedures detailed in paragraph 135 of this handbook.

MARINE RADIO OPERATORS HANDBOOK

95.6 Stations receiving a DSC safety alert should not acknowledge receipt but simply tune their transceiver to the associated radiotelephony frequency/channel and await the radiotelephony announcement. 95.7 Should the initiating station wish that the safety alert is received only by a particular station, then the â&#x20AC;&#x2DC;single stationâ&#x20AC;&#x2122; call format should be selected. In this case the MMSI of the station must be known and programmed into the transceiver. Steps to transmit a DSC safety alert and subsequent safety call and message.

Select DSC Distress Channel

Initiate DSC Safety Alert

Change to Associated Radiotelephony channel

Transmit Radiotelephony Safety Call and Announce Message follows on Working channel

Change to Working Channel

OR Change to Working Channel

Transmit Radiotelephony Safety Call and Message

AUSTRALIAN MARITIME COLLEGE

Chapter 6 Digital Selective Calling – Revision Questions SECTION 16: DSC - General Information 80.4 Digital Selective Calling (DSC) is primarily 83.3 Are routine DSC alerts permitted on the used for what priority messages? VHF DSC channel?

88.7 How are you alerted to the fact that your DSC equipment has decoded a distress alert? 80.5 What is the basic definition of DSC? 83.5 After a distress priority alert on the 2 should you do next after receiving 89.1 What (or 4, 6, 8, 12 or 16) MHz DSC 80.6 Describe the digitised burst of data by either an MF or VHF alert? frequency, what R/T frequency should be DSC used for subsequent communications? 89.2 How would you acknowledge an MF or 80.7 What information is always indicated in VHF DSC distress alert? 83.7 May radiotelephone conversations take the DSC alert? place on DSC frequencies or channels? 89.3 You have received a DSC distress alert 80.8 How would received and decoded DSC and acknowledgements from other 84.4 What VHF DSC channel is available for signals be indicated? vessels, but you are not in the vicinity routine ship to ship alerting? or able to assist; are you required to 80.9 What stations decode DSC distress 85.1 what VHF DSC channel, if any, is acknowledge? alerts? monitored by Australian Maritime 89.4 You have received a DSC distress alert, 80.10 How is the decoded DSC information Communications Stations? and acknowledgements from other displayed? 85.2 what DSC frequency or VHF channel is vessels are not being received. The alert 80.12 Is it still necessary to maintain a listening not monitored by Australian Maritime is then repeated; what would you do watch on Ch16? Communications Stations? next? 80.12 What is the DSC designed to replace? 85.7 What DSC systems are recommended 89.5 You have received a DSC distress alert, for reception of close-by alerts? 80.14 Why are hoax calls expected to and acknowledgements from other decrease? vessels are not received. 86.1 What information may be included in the DSC alert? 81.2 What type of DSC alerting is available for The alert is not then repeated; what all vessels? 86.2 What information regarding subsequent would you do next? communications may also be included 81.3 Safety authorities recommend what 90.1 A DSC distress alert is received on a in the DSC? method of automatic position information DSC HF frequency; what would you for DSC equipment? 86.3 what method is recommended for do next? automatically updating the DSC position 82.1 How is a DSC-equipped station 90.2 The distress message is then received information? identified? by radiotelephony; what should you 87.1 List ﬁve types of DSC alerts. do next? 82.2 What information is included in all DSC alerts? 82.2 To whom are urgency and safety alerts addressed to?

What types of DSC-equipped station are likely to decode a ‘selective’ alert?

82.3 How do you identify the country of registration of a vessel making a DSC alert?

88.1 On whose sole authority may a DSC distress alert be sent?

82.4 How do you identify an Australian ship’s MMSI?

88.2 What information should be included in a DSC distress alert?

82.5

88.3 How can DSC equipment have position information updated?

How do you identify an Australian Coast Station’s MMSI?

82.6 What authority issues Australian MMSI numbers?

88.4 What happens to a DSC distress alert if it is not acknowledged?

83.1 What is the 2 MHz DSC distress frequency?

88.5

What is the VHF DSC distress channel? 83.2 Are routine DSC alerts permitted on the MF/HF DSC distress, urgency and safety frequencies?

87.2 What types of DSC-equipped stations are likely to decode an ‘all ships' alert?

MARINE RADIO OPERATORS HANDBOOK

Describe the sequence for the transmission of a DSC distress alert

88.6 What vital information is included in the ‘push button’ distress alert?

90.3 If you are unable to assist, but other vessels are heard assisting, then what are you permitted to do? 90.4

If, after receiving a DSC distress alert, no MAYDAY message has been received and nothing else is heard, what can then be sent to the nearest marine coast radio station?

90.5 A DSC distress alert showing that NBDP or F1B is the mode for subsequent communications indicates what? 91.1 What priority signal is usually used by Maritime Communications Stations to rebroadcast a received DSC distress alert? 91.2 To whom are ships’ DSC distress alert relay messages addressed? 91.3 Do ships usually transmit DSC distress alert relays on 2187.5 kHz or VHF Ch70?

91.3

You have received a DSC distress alert on 2187.5 kHz or VHF Ch70. By which method would you perform a distress relay if required? would you advise a coast station of that distress alert

91.4

A ship sending a DSC distress alert on behalf of a vessel which has not been able to send its own distress alert should address the relay to whom?

91.5 Small vessels without a DSC distress alert relay facility should advise other stations by what method? 91.6 What problems may occur if DSC distress alert relays are transmitted on the higher HF frequencies? 92.1 By what method should DSC distress alert relays be acknowledged?

93.1

What steps must you take in order to 94.5 How would you acknowledge a DSC urgency alert? cancel an accidental DSC distress alert?

93.2 What steps must you take if you are unable to cancel an accidental DSC distress alert? 94.1 Whose sole authority is required before sending a DSC urgency alert? 94.1 What does the DSC urgency alert indicate? 94.2 What is the DSC urgency alert sequence? 94.3 List the steps used on the equipment, in order to transmit the DSC urgency alert. 94.4 What frequencies or channels are used for the subsequent broadcast of the urgency message?

95.1 what does the DSC safety alert indicate? 95.2 what is the DSC safety alert sequence? 95.2 what frequencies or channels are used for the subsequent broadcast of a safety message? 95.3 List the sequence for sending a DSC safety alert 95.4 What essential information may be included in the DSC safety alert? 95.5 On what frequencies or channels would the safety message be transmitted on? 95.6 Do ship stations normally acknowledge a DSC safety alert? 95.6 What should ship stations do after receiving a DSC safety alert?

NOTES

AUSTRALIAN MARITIME COLLEGE

CHAPTER 7

EMERGENCY POSITION INDICATING RADIO BEACONS (EPIRBs)

MARINE RADIO OPERATORS HANDBOOK

Section 17 Emergency Position Indicating Radio Beacons (EPIRBs) note - 121.5 MHz distress beacons should no longer be offered for sale without the seller advising you that they will no longer be licenced for distress alerting. Please advise AMSA if you are offered a 121.5 MHz distress beacon without an appropriate warning.

96. General Information 96.1

An EPIRB is a small, self-contained, battery-operated radio transmitter which is both watertight and buoyant. Radio Regulations state that the EPIRB battery should be capable of supplying power to the EPIRB for a minimum of 48 hours.

96.2

The essential purpose of an EPIRB is to assist in determining the geographical location of survivors in search and rescue operations.

96.3

An EPIRB should not be carried as an alternative to an approved marine radio transceiver. It should be considered as a supplement rather than a replacement.

96.4

Commonwealth and State legislation compel many vessels to carry EPIRBs. However, the importance of carrying a suitable EPIRB aboard every vessel proceeding more than a few miles offshore, or making a coastal or overseas voyage, cannot be too highly emphasised.

96.5

Activation of most EPIRBs is a simple two step action. However, owners should familiarise themselves with the manufacturer's instructions.

96.6

Once activated, the EPIRB should be capable of operating for a minimum of 48 hours, and it should not be switched off until you are told to do so by a rescue authority, or until rescue is completed.

96.7

Individual radiocommunications licences are not required for EPIRBs: they are authorised under a Class Licence. However, in respect of 406 MHz type beacons, it is essential that they are registered with the Rescue Co-ordination Centre in Canberra (RCC Australia). RCC Australia is operated by the Australian Maritime Safety Authority and registration is free. See paragraph 106.

96.8

Emergency locator transmitters (ELTs), designed for aircraft use, are neither suitable nor recommended for shipboard use.

96.9

Personal EPIRBs are available which are designed to be attached to a lifejacket, carried in a pocket, or worn around the neck. Due to lack of ballast, this type of EPIRB will not ﬂoat upright and, for proper operation, must be kept in an upright position by the user. Personal EPIRBs should not be confused with Personal Locator Beacons (PLBs) which are designed for land use and may not be suitable for use in a marine environment.

97. Types of EPIRB 97.1

There is now only one type of approved EPIRB available for marine use. It operates on a frequency of 406.025, 406.028, or 406.037 MHz, with the addition of 121.5 MHz transmitted for aircraft homing (usually referred to as a 406 MHz EPIRB).

97.2

Once activated, the 406 MHz EPIRB is capable of being detected and located by aircraft and a specialised satellite-aided system known as COSPAS-SARSAT.

98. The COSPAS-SARSAT International Satellite System 98.1 The COSPAS-SARSAT system is a satellite-aided search and rescue system designed to locate activated EPIRBs transmitting on 406.025, 406.028 or 406.037 MHz. 98.2

The system is intended to serve all organisations with a responsibility for search and rescue operations worldwide. The received EPIRB is regarded as a distress alert.

99. Geostationary Earth Orbiting Satellites (GEOS) 99.1 Under the COSPAS-SARSAT System there are five satellites in fixed stationary orbit some 36,000 km above the equator. These satellites provide near worldwide coverage, from approx. 70° North to 70° South. Signals from an activated EPIRB are relayed from the GEOS to its relevant Local User Terminal on earth.

AUSTRALIAN MARITIME COLLEGE

100. Low Earth Orbiting Satellites (LEOS) 100.1 The LEO satellites are located some 1,000 km above the earth’s surface, taking approx. 100 minutes to complete a polar orbit. The viewing range or ‘footprint’ of the orbiting satellite is 2000 km either side of its track over the earth’s surface. 100.2 The COSPAS-SARSAT LEOS constellation is four satellites which provide a typical waiting time of less than one hour at mid-latitudes. At least one of these satellites is within ‘line-of-sight’ of any point on the Earth’s surface at a maximum interval of approximately three hours. The average interval is considerably less. 100.3 Many countries have ground receiving facilities, known as Local User Terminals or LUTs, to receive information relayed by the satellites from activated EPIRBs. 100.4 Australia has established LEO LUTs at Bundaberg, Qld and Albany, WA. These terminals are linked directly by landline to the COSPASSARSAT Mission Control Centre at RCC Australia in Canberra. 100.5 A GEO LUT for the southwest Paciﬁc region is situated at Wellington, New Zealand. This terminal is operated by the NZ Civil Aviation Authority, and is also directly linked to the RCC Australia in Canberra.

SECTIOn 18 121.5 MHz COMPONeNT OF THe 406 MHz ePIRB 101. Detection and Location by Aircraft 101.1 Military, civil international and some domestic aircraft on major air routes maintain a listening watch on the aeronautical distress frequency of 121.5 MHz. The distance that such an aircraft is likely to detect an activated ePIRB depends entirely on the height of the aircraft. A high flying passenger jet aircraft would probably hear the signal at a radius of about 330 km (180 nautical miles), while a smaller aircraft flying at medium altitudes would hear the signal within about 185 km (100 nautical miles). 101.2 An aircraft hearing an activated EPIRB will immediately make a report to aviation authorities who, in turn, will pass this information to the RCC. An approximate position estimate of the activated EPIRB can be made by plotting the ‘first heard’ and ‘last heard’ positions. 101.3 Once a general search area has been established, military or civilian aircraft with specialised direction-finding equipment will be used for the task of localising the EPIRB. Survivors should use all appropriate visual signals to attract the attention of searching aircraft during the final stages.

102. DeTeCTION AND LOCATION BY SATeLLITe 102.1 Satellites of the COSPAS-SARSAT system no longer monitor the 121.5 MHz EPIRB frequency.

SECTIOn 19 THe 406 MHz ePIRB 103. Methods of Detection and Location 103.1 The 406 MHz ePIRB radiates signals on a frequency of 406.025, 406.028 or 406.037 MHz. Those 406 MHz ePIRBs manufactured to Australian specifications will additionally radiate signals on 121.5 MHz for aircraft homing purposes. Australian 406 MHz EPIRBs can be detected and located by two methods: - by aircraft within range listening on the civil aeronautical distress frequency of 121.5 MHz; and - by the COSPAS-SARSAT satellite system.

MARINE RADIO OPERATORS HANDBOOK

104. Detection and Location by Aircraft 104.1 The method of detection and location of the 121.5 MHz signal component of a 406 MHz EPIRB by aircraft is the same as that described in paragraph 101.1 - 101.3.

105. Detection and Location by Satellite 105.1 Signals radiating from an activated 406 MHz EPIRB will be detected by satellites of the COSPAS-SARSAT system and relayed back to Earth. The 406 MHz beacon transmits a 5 watt burst of data of approximately 0.5 seconds duration every 50 seconds. This data indicates the identity of the beacon. (See paragraph 106) 105.2 Because signals from a 406 MHz EPIRB are in a digitised form, they can also be stored in the satellite’s memory. As the satellite’s path brings the ePIRB and the LUT into view, the ePIRB information is passed directly to the LUT in what is termed 'real time' mode. However, if the LUT is not in the satellite's footprint, information, including the time of first detection, is retrieved from the satellite’s memory and relayed down to the LUT when it does come into view. This information is processed and passed to a rescue co-ordination centre, providing both an alert and a position. 105.3 A 406.025 MHz EPIRB can generally be located by the satellite system to a radius of better than 5 km (2.7 nautical miles). 406.028 MHz with frequent GPS position updating can give a position accuracy to within 30 metres of a beacon. Final location of the distress scene can be carried out by aircraft ‘homing’ on the 121.5 MHz component of the EPIRB signal. 105.4 Because of the satellite’s ability to memorise signals from a 406 MHz EPIRB, an activated 406 MHz EPIRB can be detected and located at any place on the Earth’s surface. 105.5 It is strongly recommended that all vessels making a voyage from Australia to any destination carry a 406 MHz EPIRB. 105.6 406 MHz ePIRBs have numerous advantages over the older 121.5 MHz types. These advantages include: - the ability to be located more accurately; - identification of the owner/operator enables search and rescue authorities to obtain more intelligence before initiating a response; - the latest generation of beacons have the capability of detection by geostationary satellites enabling near instantaneous detection; and - newer generation beacons already have the capability of transmitting position data memorised from an interface with satellite navigation receivers (GPS).

ntification 106.1 Every 406 MHz EPIRB has a unique identity code which is transmitted as part of its signal and which also indicates the country of registration. This code is programmed into the beacon by the supplier before it is offered for purchase. 106.2 As a result, local user terminals anywhere in the world receiving a distress alert and location from an activated 406 MHz ePIRB can also identify the vessel in distress and the beacon’s country of registration. 106.3 If this system is to work successfully, and for their own safety, it is essential that purchasers of 406 MHz EPIRBs complete the registration form provided by the supplier and mail it to RCC Australia in Canberra or register their beacon online. The completion of this registration process will ensure that the RCC is equipped with information vital to a successful rescue mission. 106.4 It is just as important that purchasers of second-hand 406 MHz EPIRBs also provide their details to the RCC.

107. Activation s 107.1 406 MHz beacons are available in two types: - those that require manual activation; and - those that can be activated manually or will float-free and activate automatically should a vessel sink. 107.2 The manual activation type may offer an electronic menu of distress situations. Selection by an operator prior to activation will provide the rescue co-ordination centre with an identification of the vessel’s type of distress, as well as its identity and country of origin. 107.3 Vessels compulsorily fitted with 406 MHz EPIRBs under Commonwealth legislation must carry the float-free type.

AUSTRALIAN MARITIME COLLEGE

108. The GPIRB 108.1 EPIRBs now operating on 406.028, 406.037 or 406.040 MHz are being manufactured with a GPS receiver already inbuilt. These EPIRBs are being referred to as 'GPIRBs'. Once the ePIRB has been activated the GPS receiver will commence to download GPS data and within approximately five minutes will be transmitting the activated ePIRBs geographical position information.

Section 20 Care and Maintenance of EPIRBs 109. Servicing 109.1 Vessels fitted with 406 MHz EPIRBs under Commonwealth and State legislation should refer to the relevant regulations concerning performance verification tests and battery replacement. 109.2 Boat owners voluntarily carrying ePIRBs should refer to the owner’s manual concerning recommended servicing and battery replacement. 109.3 An EPIRB should only be tested strictly in accordance with the manufacturer’s instructions for self-testing.

s 110.1 Many EPIRBs are supplied with a bulkhead mounting bracket. It is recommended that this be used to stow an EPIRB in a place where it is both readily visible and accessible for use in an emergency. 110.2 If an inflatable life raft is carried on board, consideration should be given to stowage of an EPIRB inside the raft. 110.3 The float-free type of 406 MHz EPIRB should be carefully located and mounted to ensure that it is not fouled by the vessel’s superstructure should the vessel sink and the beacon be released.

ctivation 111.1 every year valuable government and search and rescue resources are wasted in locating ePIRBs that have been activated inadvertently or maliciously. Most cases of accidental transmission result from unsuitable storage, or failure to totally disable an old model EPIRB before disposal. Theft and subsequent malicious activation of EPIRBs is an increasing problem and owners should take every care to minimise opportunities for beacons to be stolen. The need to treat EPIRBs responsibly cannot be too highly emphasised. 111.2 To minimise the possibilities of accidental activation, EPIRB owners are urged to pay careful attention to: - the need to avoid the stowage of EPIRBs in lockers with other equipment or objects that may subject the beacon activation switch to pressure (vessel movement should be considered); - the need to avoid the stowage of EPIRBs in places where they may lie in water or be subject to occasional high water pressure such as from a hose (the entry of water into the circuitry through deteriorating watertight seals may activate the beacon); - the need to dispose of unwanted EPIRBs responsibly. Check with AMSA or your local marine authority for recommended drop-off sites; - the need to ensure that an EPIRB will not be activated through physical movement or shock during any form of transport away from a vessel; - the need to educate other persons aboard a boat regarding the consequences of activation; - the need to prevent interference with the beacon by children; and - the fact that a ﬂoat-free EPIRB that has been ‘armed’ will activate immediately on removal from its cradle (transportation away from the cradle should be made in the ‘safe’ or ‘off’ condition).

MARINE RADIO OPERATORS HANDBOOK

111.3 Should an EPIRB owner suspect that it has been activated inadvertently, this information MUST immediately be passed to RCC Australia in Canberra by telephone on 1800 641 792 (24 hour number). If accidental activation is discovered whilst at sea, this information should immediately be passed to a Maritime Communication Station, another vessel, or a Limited Coast Station for on-forwarding to the RCC Australia. the case of a genuinely accidental activation of an EPIRB, an owner or operator need have no fear of being penalised by search and rescue In authorities.

NOTES

AUSTRALIAN MARITIME COLLEGE

ndicating stions SECTION 17: Emergency Position Indicating s 96.1 What is the basic description of an EPIRB?

99.1 What is the viewing range of the fixed orbit satellites?

96.2 What is the essential purpose of an EPIRB?

99.1 How many satellites are there in fixed orbit of the COSPAS-SARSAT system?

96.4 What are the general carriage requirements for ePIRBs?

99.1 At what height are the fixed orbiting satellites?

96.6 When may the activated EPIRB be switched off?

100.1 At approximately what height are the Low Earth Orbiting satellites?

96.7 Is a separate licence required for an EPIRB?

100.1 What type of orbit path do LEO satellites take?

97.1

What type of EPIRB is approved for marine use?

100.1 What is the orbit duration of a LEO satellite?

98.1

what is the COSPAS-SARSAT system?

100.1 What is the viewing range or ‘footprint’ of the LEO satellite?

100.2 What is the maximum interval whereby an orbiting COSPAS-SARSAT satellite would be within ‘line of sight’ of any point of the Earth’s surface? 100.3 What are ground receiving facilities able to receive COSPAS-SARSAT satellite information known as? 100.4 Where in Australia are ground receiving facilities for COSPAS-SARSAT satellite information located? 100.5 Where is the additional ground receiving facility located that is also connected to RCC Australia (Canberra)?

SeCTION 18: 121.5 MHz COMPONENT OF THE 406 MHz ePIRB 101.1 what type of station detects signals radiating from the 121.5 MHz EPIRB?

101.1 what determines the reception range by aircraft of a 121.5 MHz EPIRB?

SeCTION 19: THe 406 MHz ePIRB 103.1 A signal emanating from a 406 MHz EPIRB can be detected and located by what method? 104.1 How are 406 MHz EPIRBs located by aircraft? 105.1 Describe the signal transmitted from a 406 MHz EPIRB. 105.2 What happens to the 406 MHz burst of data should the LUT not be in the COSPAS-SARSAT satellite footprint at the time the data is received from the EPIRB?

105.3 What is the position accuracy of a detected 406 MHz EPIRB? 105.4 What is the coverage of the 406 MHz EPIRB? 106.1 what information is programmed into the 406 MHz ePIRB? 106.2 What information is available to rescue authorities when they receive a signal from a registered EPIRB?

106.3 For Australian registered vessels, where should EPIRB registry information be lodged? 107.1 How are EPIRBs activated? 107.3 What type of EPIRB must be carried by vessels that come under Commonwealth legislation?

SeCTION 20: CARe AND MAINTeNANCe OF ePIRBs 109.3 Generally speaking, what are the rules governing EPIRB testing?

MARINE RADIO OPERATORS HANDBOOK

111.1 Generally speaking, what are the rules governing an owner’s responsibility for an EPIRB?

111.3 What must a boat owner do once the EPIRB has been inadvertently activated?

CHAPTER 8

SEARCH AND RESCUE TRANSPONDERS (SARTs)

AUSTRALIAN MARITIME COLLEGE

Section 21 Search and Rescue Transponders ral 112.1 A Search and Rescue Transponder or SART is a battery-powered portable device, which may be used by a survival craft to indicate its position to searching aircraft and vessels. The SART operates in the 9.3 to 9.5 GHz band and will respond only to radar equipment operating on those frequencies (X Band, 3 Centimetre radar). The SART will not respond to 3 GHz (S band) radar. The SART should operate in the standby mode for a minimum of 96 hours with, a further eight hours of transmission. 112.2 Positioning of the SART

Vessel heading should be mounted due North

12 Mile Range

Under no circumstances should the SART be placed in the water. The SART at least one metre above the water line. When in the survival craft, survivors should position the SART as high as possible with the aid of an oar orHeading the lifeboat mast. Some manufacturers line will supply the SART with a short telescopic type mast of approximately one metre in length. 112.3 SART Operation Once switched on, the SART will scan the X Band of radar frequencies. When a ‘seeking radar’ is detected, the SART will commence to transmit on the entire X Band, thus enabling all vessels in the vicinity to receive an indication of the SART transmission. On detecting signals from distant radar equipment, an activated SART will generate a signal which will be displayed on the receiving radar screen as twelve blips, extending in a line, approx 5 to 8 nautical miles outward from the SART’s position, along its line of bearing. This unique radar signal is easily recognised and the rescue vessel or aircraft can locate the survivors. An interrogated SART will provide proof to survivors that they have been detected by means of an audible alarm and/or ﬂashing light. 112.4 Location Distances A SART should respond to a ship’s radar with a scanner height of 15 metres at a distance of at least 5 nautical miles. 112.5 Location Errors Once locked on to a ‘seeking radar’, there will be a slight delay in the changeover from the SARTs standby or receive mode to transmit mode. This slight delay may cause a small position error of up to 150 metres on the radar screen of the blip associated with the position of the SART. Subsequent radar sweeps will conﬁrm the actual location of the SART.

Vessel heading due North

12 Mile Range Heading line

SART indication as seen on a marine radar on a bearing of 045°T. (Radar Display set to North Up)

Vessel altered MARINE course towards the SART

12 Mile Range

RADIO OPERATORS HANDBOOK

Vessel altered course towards the SART

12 Mile Range

SART Image on a marine radar once the vessel has altered course to head towards the SART position

112.6 AIS-SART Deployment of an AIS-SART is similar to a traditional SART. Designed to operate from a survival craft, it should be mounted at least one metre above the water line. AIS-SARTs are encoded (by the manufacturer) with a unique nine digit identification code beginning with 970-, very similar to a DSC MMSI. AIS-SARTs can be manually activated or deactivated, automatic activation may also be provided. Once activated the AIS-SART transmits continually for a minimum of 96 hours. AIS-SARTs transmit AIS messages that indicate the GPS position, safety information and serialised identity number, a sequence of eight messages a minute is transmitted. Four messages are transmitted on AIS channel 1 (161.975 MHz) and four on AIS channel 2 (162.025 MHz), this will maximise the period an AIS-SART will be visible to other vessel’s AIS receivers. The AIS-SART is detected only by AIS vessels within range. The transmitted information can be displayed on a chart plotter or Electronic Chart Display and Information System (ECDIS) if they are interfaced with an AIS receiver. AIS equipment receiving the AIS-SART signal are able to display the range and bearing to the AIS-SART. Vessel’s AIS systems will recognise the 970 prefix as a SART, and display the target as a circle containing a cross with solid lines (IMO agreed symbol). The ECDIS software will display the symbol in red, see image below.

112.7 AIS-MOB (Man Overboard) A small portable AIS-SART (Personal Locator Beacon - PLB) with a built-in GPS (See paragraph 112.6) which transmits an emergency AIS-SART sentence (MOB and position) which triggers an alarm on all AIS enables chart plotters / PC’s within range (typically four miles). Upon activation, all nearby vessels equipped with AIS receivers, will be notified with messages appearing on their AIS device and connected ECDIS systems. Updated in real time, the GPS provides an accurate position of the AIS-SART.

Chapter 8 Search and Rescue Transponders stions SECTION 21: Search and Rescue Transponders 112.1 What is the general description of a SART?

112.2 when in a survival craft, how should the SART be positioned?

112.4 what is the minimum location distance of an activated SART?

112.1 What type of marine radar is capable of detecting a SART?

112.3 In the standby mode, what is the SART doing?

112.5 which part of the SART signal, as seen on the radar, is the SART itself?

112.1 For how long should the SART operate in 112.3 what indication is there on a marine radar of an activated SART? the standby mode? 112.1 For how long should the SART transmit, once activated?

112.3 How would survivors be alerted to the fact that their SART has been activated?

112.6what vessels detect an AIS-SART? 112.6 what is the IMO symbol for an AIS-SART? 112.7 What is an AIS-MOB? AUSTRALIAN MARITIME COLLEGE

CHAPTER 9

SEARCH AND RESCUE IN AUSTRALIA

MARINE RADIO OPERATORS HANDBOOK

Section 22 Search and Rescue - General Information (See AMSA.gov.au) 113. The Modernised Australian Ship Tracking and Reporting System (MASTREP) 113.1 The Modernised Australian Ship Tracking and Reporting System (MASTREP) is a Ship Reporting System designed to contribute to safety of life at sea and is operated by the Australian Maritime Safety Authority (AMSA) through the Rescue Coordination Centre (RCC) Australia in Canberra. Participation in MASTREP is mandatory for certain vessels but others are encouraged to participate. 113.2 The International Convention on Maritime Search and Rescue (SAR) was opened for signature in 1979 and, by becoming a signatory to the SAR Convention, Australia has accepted SAR responsibility for the Australian Search and Rescue Region (SRR), shown below. The MASTReP system is used to track the location of vessels in the SRR and allows Australia to meet its obligations under Chapter 5 of the Annex to the SAR Convention as it relates to Ship Reporting Systems. 113.3 MASTReP provides positional data on vessels transiting Australia’s region via AIS technology, which ensures that only the closest vessels are requested to assist in a SAR incident, reducing the need for vessels to steam long distances from their intended voyage plan. The Search and Rescue Officers conducting such operations in the Australian region routinely use this facet of MASTReP. Given the expansiveness of Australia’s Search and Rescue Region, merchant ships are often the only resources available that can quickly respond to an incident. 113.4 Note that State and Territory police forces are responsible for search and rescue on inland waterways, within port limits, and coastal waters to the limits of State and Territory jurisdiction, which extends to 3 nautical miles from the coast.

Australian Search and Rescue Region

114. Concept of Operations 114.1 MASTREP uses Position Reports, which must be transmitted by AIS in accordance with the International Convention for the Safety of Life at Sea (SOLAS), Chapter 5, Regulation 19.2.4 114.2 Position reporting is automated and the data is fed into the system using AIS, either collected terrestrially or by satellite. Positional data is updated at time intervals of between five minutes and five hours depending on the location and source. There is no requirement in MASTReP to transmit Sail Plans (SP), Deviation Reports (DR) or Final Reports (FR). No positive SAR watch is maintained in MASTREP. MASTREP is a passive ship reporting system and does not involve shore to vessel communications.

115. Participation 115.1 The Commonwealth of Australia Navigation Act 2012 and Marine Orders Part 63 makes the provision of Position Reports mandatory for certain vessels. The following vessels must report to MASTREP: 1. foreign vessels, from the arrival at their ﬁrst port in Australia until their departure from their ﬁnal port in Australia; and 2. all regulated Australian vessels whilst in the MASTREP area.

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116. Voluntary Participation 116.1 Vessels participating in MASTREP transmit positional data to RCC Australia. This enables vessels in the vicinity of search and rescue incidents to be determined. To assist AMSA in achieving its purpose, masters are strongly encouraged to report to MASTReP voluntarily even where it is not mandated. Such participation will enhance the safety of all vessels operating in the Australian SRR. Domestic commercial vessels fitted with Global Maritime Distress and Safety System (GMDSS) and AIS technology are also encouraged to participate in the system.

117. Automatic Identification System (AIS) 117.1 AIS is a shipboard transponder system that makes it possible to monitor ships from other ships and from shore based stations. Ships equipped with AIS will continuously transmit their position, course, speed and other relevant data via dedicated VHF channels. Other equipped AIS ships will receive the vesselâ&#x20AC;&#x2122;s information, which can be displayed on Radar (ARPA) or electronic Charts. 117.2 AIS transponders operate on a VHF Channel 87B (AIS 1) and 88B (AIS2). 117.3 Currently the focus for this system is on larger vessels subject to the Navigation Act 2012. In the longer term this system might be useful for small vessels. It may be used to support or enhance reporting systems like REEFREP - which tracks vessels in the region of the Great Barrier Reef.

NOTES

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Chapter 9 Search and Rescue in Australia Revision Questions SECTION 22: Search and Rescue â&#x20AC;&#x201C; General Information 113.1 Australian Search and Rescue is a division of what authority?

113.2 What is the area of responsibility of Australian Search and Rescue?

113.1 What system is used to track the movement of vessels in Australian waters?

113.4 What authority is responsible for coastal search and rescue?

117.2 What VHF channels are used by the AIS system?

NOTES

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CHAPTER 10

DISTReSS, URGeNCY AND SAFeTY COMMUNICATIONS USING RADIOTeLePHONY

MARINE RADIO OPERATORS HANDBOOK

Section 23 Priority Calls - General Information 118 General Information 118.1 National and international systems exist to provide prompt and effective search and rescue assistance to ships in distress. By complying with procedures in this chapter, ship station operators can ensure that these systems continue to work effectively for the benefit of all mariners. 118.2 For inshore boating emergencies, State and Territory Police Forces, using the resources of recognised volunteer marine rescue organisations as well as their own Water Police, co-ordinate most inshore boating emergencies. 118.3 All radiotelephony distress, urgency and safety calls and messages should be spoken slowly and clearly. The phonetic alphabet and figure code should be used if necessary. Use of the Standard Marine Communications Phrases is recommended in the case of language difficulties. Details may be found in Appendices 5 and 6. 118.4 In order that signals may be received by the maximum number of stations, the compatible transmission mode of AM (marked as H3E on some transceivers) must be selected for the broadcast of distress, urgency or safety messages on 2182 kHz. Vessels operating in the GMDSS System will select SSB (marked as J3E on some transceivers) for radiotelephony distress communications after reception of a distress alert by DSC. 118.5 The transmission of false or deceptive distress, urgency or safety messages is strictly forbidden. Extremely severe penalties, including imprisonment, exist under the Radiocommunications Act 1992, for any person found guilty of making such a transmission.

Section 24 Alarm Signals Important note - As a consequence of the complete introduction of the GMDSS in 1999, the radiotelephony alarm signal was replaced by digital selective calling techniques, and large trading vessels no longer carry transmission facilities for it. However MF/HF transceivers with a radiotelephony alarm signal generator are still in use on many small vessels. In view of this and the signal’s readily recognisable characteristic, the signal will continue to be a useful procedure for small vessels for a number of years.

119. The Radiotelephony Alarm Signal 119.1 The radiotelephony alarm signal consists of two audio frequency tones, one high, one low, transmitted alternately. This produces a distinctive warbling sound easily distinguished, even in poor reception conditions. 119.2 The purpose of the signal is to attract the attention of operators to the message which is to follow. 119.3 Operators of MF/HF ship station radio equipment with the facility to transmit the radiotelephony alarm signal should, if time permits, use it to precede a distress call and message. 119.4 The radiotelephony alarm signal may also be used by ship stations to precede an urgency message concerning the loss of a person or persons overboard, or when grave and imminent danger is threatening a person or persons. Its use under these circumstances must be restricted to circumstances when the assistance of other vessels is required and cannot be obtained by use of the urgency signal alone. 119.5 In order to attract the attention of the maximum number of ship stations, Limited Coast Stations and Maritime Communication Stations may use the radiotelephony alarm signal to precede distress relay calls and messages. 119.6 Limited Coast Stations and Maritime Communication Stations may also use the radiotelephony alarm signal to precede a safety message concerning an urgent cyclone warning. 119.7 The radiotelephony alarm signal transmitted by a Maritime Communication Station will be followed by a single low tone lasting for ten seconds. This identiﬁes the transmission as that from a Maritime Communication Station.

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120. The Navigational Warning Signal 120.1 The navigational warning signal consists of a single audio tone of 2200 Hertz interrupted to give a sequence of alternate tone dashes and spaces each of duration one quarter of a second. The signal may be transmitted continuously by a coast station for a period of fifteen seconds to attract the attention of stations to a vital navigational warning which will follow. 120.2 The navigational warning signal is not generally used by Australian Maritime Communication Stations or Limited Coast Stations.

Section 25 Distress Communications 121. Definition and Priority of Distress 121.1 A distress call has absolute priority over all other transmissions and indicates that the vessel or person using it is threatened by grave and imminent danger and requests immediate assistance. All stations which hear a distress call must immediately cease all transmissions capable of interfering with distress communications, and must continue to listen on the frequency on which the distress call was received. A distress call is broadcast to all stations. 121.2 The obligation to accept distress calls and messages is absolute and must be accepted with priority over all other radiocommunications.

122. Authority to Transmit Distress calls and Messages 122.1 A radiotelephony alarm signal, a distress call and a distress message from a vessel may be transmitted only on the authority of the master or skipper, or the person responsible for the safety of that vessel.

123. Frequencies for Distress 123.1 International frequencies for distress calls by radiotelephony are: - 2182, 4125, 6215, 8291, 12 290, 16 420 kHz in the MF/HF marine bands; and Channel 16 in the VHF marine band. See Appendix 3. 123.2 In Australian waters, the following additional radiotelephony distress frequencies have been allocated: - Channel 67 in the VHF band (supplementary to Channel 16); - 27.88 MHz (channel 88) in the 27 MHz marine band; and - 27.86 MHz (channel 86) in the 27 MHz marine band (supplementary to channel 88). 123.3 The distress frequencies in the 27 MHz marine band are monitored by the majority of Limited Coast Stations operated by marine rescue groups. 123.4 In the interests of safety, boat owners should ensure that their equipment has the distress frequencies necessary to communicate with Limited Coast Stations in their area of operation. Contact the relevant State/Territory authority or your local volunteer marine rescue organisation to find out information about limited coast stations in your area. 123.5 The distress frequencies listed in paragraphs 123.1 and 123.2 are not monitored by Maritime Communication Stations. Maritime Communication Stations only provide a continuous watch on the HF digital selective calling frequencies reserved for distress, urgency and safety. International DSC frequencies for distress are: 4207.5; 6312; 8414.5; 12 577; and 16 804.5 kHz. See paragraph 83.1 for more information. 123.6 The frequencies used by the Bureau of Meteorology to provide automatically generated radiotelephony broadcasts of routine weather forecasts and weather warnings through the Maritime Communication Stations are not monitored.

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124. The Distress Signal 124.1 The radiotelephony distress signal consists of the word ‘MAYDAY’. 124.2 This signal indicates that a vessel, aircraft or person is threatened by grave and imminent danger and requests immediate assistance. It does not extend to situations where immediate assistance is sought on behalf of a person, for example, in a medical emergency. The urgency signal should be used in these situations. 124.3 The distress signal must not be used under any other circumstances. 124.4 Misuse of the distress signal could result in attention being diverted away from a situation which really requires immediate assistance.

125. The Distress Call 125.1 The radiotelephony distress call consists of: - the distress signal MAYDAY, spoken three times; - the words THIS IS; - the name and call sign of the vessel in distress, spoken three times; - the MMSI (if a DSC alert has been sent).

126. The Distress Message 126.1 The distress message, which follows the distress call, consists of: - the distress signal MAYDAY; - the name and call sign of the vessel in distress; - the MMSI (if a DSC altert has been sent) - particulars of its position; - the nature of the distress and the kind of assistance required; - any other information which may facilitate rescue. 126.2 The distress call and message may be repeated as often as necessary, especially during silence periods, until an answer is received. 126.3 If no answer is received on distress frequencies, the message should be repeated on any other available frequency where attention might be attracted.

Example of a complete distress call and message: Radiotelephony alarm signal (if facility fitted) Distress call Distress signal (x3)

MAYDAY, MAYDAY, MAYDAY

Words “this is”

THIS IS

Station calling (x3) SCAMP VL2345 SCAMP VL2345 SCAMP VL2345 Distress message Distress signal

MAYDAY

Name/MMSI

SCAMP VL2345

Position

50 NAUTICAL MILES DUE EAST FROM POINT DANGER

Nature of distress SINKING RAPIDLY AFTER STRIKING SUBMERGED OBJECT. ESTIMATE FURTHER 15 MINUTES AFLOAT Other information

TWENTY METRE MOTOR CRUISER RED HULL WHITE SUPERSTRUCTURE 4 PERSONS ONBOARD EPIRB ACTIVATED OVER.

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127. Distress Position Information 127.1 Position information in a distress message should normally be stated in one of three ways: - latitude and longitude (degrees and minutes, and decimal points of a minute if necessary, North or South, east or west); or - true bearing and distance (the unit of distance should always be specified, for example, nautical miles or kilometres) from a known geographical point (for example 045 degrees true from Point Danger, 24 nautical miles); or - a precise geographical location (for example, in the case of a vessel running aground). 127.2 Where latitude and longitude are not used, care must be taken to ensure that the position given cannot be confused with any other place or geographical point. 127.3 If afloat and drifting, the rate and direction of drift could be stated in the distress message.

128. Distress Traffic 128.1 Distress traffic consists of all communications relating to the immediate assistance required by the vessel in distress, including search and rescue and on-scene communications. The distress signal MAYDAY should be used to precede each call and message.

129. Obligation to Acknowledge Receipt of a Distress Message 129.1 Ship stations that receive a distress message from another vessel which is, beyond any possible doubt, in their vicinity, should immediately acknowledge receipt. 129.2 However, in areas where reliable communications with a Limited Coast Station or Maritime Communication Station is practicable, ship stations should defer this acknowledgement for a short interval to allow the Limited Coast Station or Maritime Communication Station to acknowledge receipt. 129.3 Ship stations which receive a distress message from another vessel which, beyond any possible doubt, is not in their vicinity should defer their acknowledgement to allow vessels nearer to the distressed vessel to acknowledge without interference. 129.4 Ship stations which receive a distress message from another vessel which, beyond any possible doubt, is a long distance away, need not acknowledge receipt unless this distress message has not been acknowledged by any other station. 129.5 when a ship station hears a distress message which has not been acknowledged by other stations, but is not itself in a position to provide assistance, it should acknowledge the call and then take steps to attract the attention of a Maritime Communication Station, Limited Coast Station or vessels which might be able to assist. Details of how this should be done may be found in paragraph 133 (transmission of a distress message by a station not itself in distress).

130. ACKNOWLEDGEMENT OF RECEIPT OF A DISTRESS MESSAGE 130.1 Acknowledgement of receipt of a distress message by a vessel, Limited Coast Station or Maritime Communication Station is made in the following way: - the distress signal MAYDAY; - the name and call sign of the station sending the distress message, spoken three times; - the words THIS IS; - the name and call sign of the station acknowledging receipt, spoken three times; - the word RECEIVED; - the distress signal MAYDAY. 130.2 As soon as possible after this acknowledgement a ship station should transmit the following information: - its position; - the speed at which it is proceeding and the approximate time it will take to reach the distress scene.

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EXAMPLE OF ACKnOWLEDGEMEnT OF RECEIPT OF A DISTRESS MESSAGE BY A SHIP STATIOn (TRAnSMITTED In RESPOnSE TO THE DISTRESS CALL AnD MESSAGE In THE EXAMPLE GIVEn In PARAGRAPH 126): Distress traffic

MAYDAY

Distress vessel (x3)

SCAMP VL2345, SCAMP VL2345, SCAMP VL2345

The words “this is”

THIS IS

Station calling (x3)

PRONTO VZN6789, PRONTO VZN6789, PRONTO VZN6789

The acknowledgement

RECEIVED MAYDAY IN POSITION 35 NAUTICAL MILES EAST FROM POINT DANGER PROCEEDING AT 15 KNOTS ESTIMATE AT YOUR POSITION IN ONE HOUR OVER.

131. Control of Distress Traffic 131.1 Control of distress traffic is the responsibility of the vessel in distress. However, this station may delegate the control of distress traffic to another vessel, a Maritime Communication Station or Limited Coast Station. 131.2 The vessel in control of distress traffic may impose silence on any or all stations interfering with distress traffic by sending the instruction SEELONCE MAYDAY. 131.3 This instruction must not be used by any station other than the vessel in distress, or the station controlling distress traffic. 131.4 Any station which has knowledge of distress traffic and cannot provide assistance should continue to monitor the traffic until such time that it is obvious that assistance is being provided. 131.5 Any station which is aware of distress traffic, and is not taking part in it, is forbidden to transmit on any frequency which is being used for that traffic. 131.6 Ship stations not involved in the exchange of distress traffic may, while continuing to monitor the situation, resume normal radio service when distress traffic is well established and on the condition that distress traffic frequencies are not used and no interference is caused to distress traffic.

132. Resumption of Normal Working 132.1 When distress traffic has ceased on a frequency that has been used for distress traffic, the station that has been controlling that traffic should transmit a message addressed to all stations indicating that normal working may be resumed. 132.2 The message to announce resumption of normal working should take the following form: - the distress signal MAYDAY; - the call ALL STATIONS, spoken three times; - the words THIS IS; - the name and call sign of the station sending the message, spoken three times; - the time the message originated; - the name and call sign of the vessel which was in distress; - the words SEELONCE FEENEE.

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133. TRANSMISSION OF A DISTReSS MeSSAGe BY A STATION NOT ITSeLF IN DISTReSS 133.1 A ship station, a Maritime Communication Station or a Limited Coast Station which learns that a vessel is in distress may transmit a distress message on behalf of that vessel when: (a) the vessel in distress cannot itself transmit a distress message; or (b) the master or skipper of the vessel not in distress, or the person responsible for a Maritime Communication Station, or Limited Coast Station, considers that further help is necessary; or (c) a lthough not in a position to provide assistance, it has heard a distress message which has not been acknowledged (see paragraph 130). 133.2 When a distress message is transmitted by a station not in distress, it is essential that this fact be made clear. Failure to follow the correct radio procedures could cause confusion and delays or, in the worst case, assistance to be directed to the wrong vessel. 133.3 A distress call transmitted by a vessel, Maritime Communication Station or Limited Coast Station not itself in distress should take the following form: the signal MAYDAY RELAY, spoken three times; the words THIS IS; the name and call sign of the station making the transmission, spoken three times. 133.4 In the circumstances outlined in (a) and (b) of paragraph 133.1, this transmission should be immediately followed by a suitable message in which the position and circumstances of the distressed vessel are provided. 133.5 If the transmission is made by a vessel arriving at a distress scene to find rescue is beyond its resources, then the transmission should be followed by a message outlining these circumstances and providing the relay vessel’s own position. In the circumstance outlined in paragraph 133.1(c), the transmission should be followed by a repeat of the original distress message. 133.6 If facilities are available, the radiotelephony alarm signal should precede the transmission.

Example of a call and message transmitted by a ship station under circumstance 133.1(c) on behalf of vessel “Seadog” VNW6789: Radiotelephony alarm signal (if facility fitted) Mayday relay signal (x 3)

MAYDAY RELAY, MAYDAY RELAY, MAYDAY RELAY

The words “this is”

THIS IS

Station calling (x 3)

MISTY VLW3456, MISTY VLW3456, MISTY VLW3456

The Mayday message MAYDAY SEADOG VNW6789 POSITION 50 NAUTICAL MILES NORTHWEST FROM CAPE INSCRIPTION ON FIRE AND ABANDONING INTO LIFERAFT 2 PERSONS ON BOARD OVER.

Example of message transmitted by a Coast Radio Station under circumstance 133.1(b): Radiotelephony alarm signal (if facility fitted) Mayday relay signal (x 3)

MAYDAY RELAY, MAYDAY RELAY, MAYDAY RELAY

The words “this is”

THIS IS

Calling Station (x 3)

COAST RADIO SYDNEY, COAST RADIO SYDNEY, COAST RADIO SYDNEY

The Mayday relay message MAYDAY RELAY UNIDENTIFIED DISTRESS MESSAGE HAS BEEN RECEIVED AND RED FLARES HAVE BEEN SIGHTED TO SEAWARD OF BEECROFT HEAD ALL VESSELS IN THE AREA INVESTIGATE AND REPORT OVER.

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Section 26 Urgency and Safety Signals 134. The Urgency Signal 134.1 The urgency signal consists of the words PAN PAN. It has priority over all other communications except those concerned with distress. 134.2 Use of the urgency signal indicates that the station sending it has a very urgent message to transmit concerning the safety of a vessel, aircraft, or person. 134.3 The urgency signal may only be sent on the authority of the master or skipper, or person responsible for the safety of a vessel. 134.4 All stations that hear an urgency signal must take care not to interfere with the message that follows. 134.5 The urgency signal and message are normally sent on one or more of the distress frequencies. However, transmission of the message following the urgency signal should be transferred to a working frequency or channel if: - it is lengthy or it concerns an urgent medical case; or - after the initial broadcast on the distress frequency(s) it needs to be frequently repeated (this generally applies only to Maritime Communication Stations). 134.6 Urgency messages may be addressed to all stations or to a particular station. If addressed to all stations, the originating station must cancel the message when action is no longer necessary.

Example of an urgency call and message sent by a Limited Coast Station: Urgency call Urgency signal (x3)

PAN PAN, PAN PAN, PAN PAN

Station called (x3)

ALL STATIONS, ALL STATIONS, ALL STATIONS

Words “this is”

THIS IS

Station calling (x3)

OCEAN RESCUE LAKES ENTRANCE OCEAN RESCUE LAKES ENTRANCE OCEAN RESCUE LAKES ENTRANCE

Urgency message

FIFTEEN METRE YACHT STANDFAST REPORTED OVERDUE ON VOYAGE FROM PORT MACQUARIE TO HOBART LAST RADIO CONTACT 4th JUNE IN POSITION 30 NAUTICAL MILES TO SEAWARD FROM CAPE HOWE DESCRIPTION WHITE HULL BLUE SAILS THREE PERSONS ON BOARD ALL VESSELS KEEP SHARP LOOKOUT AND REPORT ANY SIGHTING OUT.

Example of an urgency call and message sent by a ship station: Urgency call Urgency signal (x3)

PAN PAN, PAN PAN, PAN PAN

Station called (x3)

ALL STATIONS, ALL STATIONS, ALL STATIONS

Words “this is”

THIS IS

Station calling (x3)

HAWK VL2345, HAWK VL2345, HAWK VL2345

Urgency message

30 NAUTICAL MILES DUE WEST FROM CAPE DORA LOST PROPELLER ESTIMATE DRIFTING SOUTHWEST AT 3 KNOTS REQUIRE TOW URGENTLY OVER.

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135. The Safety Signal 135.1 The safety signal consists of the word SECURITE (pronounced SAY-CURE-E-TAY). 135.2 It indicates that the station using it is about to transmit a message concerning an important navigational or weather warning. It should not be used to precede routine weather forecasts. 135.3 Ship stations hearing the safety signal should continue to listen until they are satisfied that it does not concern them. They must not make any transmission that is likely to interfere with the message.

136. Safety Communications 136.1 The safety signal and a call to all stations should normally be made on a distress channel or frequency. However, the safety message that follows should be made on a working frequency or channel.

Example of a safety call and message transmitted by a Coast Radio Station: Safety call Safety signal (x3)

SAY-CURE-E-TAY, SAY-CURE-E-TAY, SAY-CURE-E-TAY

Station called (x3)

ALL STATIONS, ALL STATIONS, ALL STATIONS

Words “this is”

THIS IS

Station calling (x3)

COAST RADIO DARWIN, COAST RADIO DARWIN, COAST RADIO DARWIN

Change of frequency

GALE WARNING - LISTEN ON 2201

Repeat safety call

(Coast Station changes to 2201 & calls again)

Safety signal (x3)

SAY-CURE-E-TAY, SAY-CURE-E-TAY, SAY-CURE-E-TAY

Station called (x1)

ALL STATIONS

Words “this is”

THIS IS

Station calling (x1)

COAST RADIO DARWIN

Safety Message DALY RIVER TO TORRES STRAIT NORTHEASTERLY WINDS IN EXCESS OF 30 KNOTS ARE EXPECTED TO PERSIST FOR NEXT TWENTY FOUR HOURS OUT.

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Example of safety call and message transmitted by a ship station: Safety call Safety signal (x3)

SAY-CURE-E-TAY, SAY-CURE-E-TAY, SAY-CURE-E-TAY

Station called (x3)

ALL STATIONS, ALL STATIONS, ALL STATIONS

Words “this is”

THIS IS

Station calling (x3)

SEAFOX VL9876, SEAFOX VL9876, SEAFOX VL9876

Change of frequency

NAVIGATIONAL WARNING - LISTEN ON 2524 (Ship station changes to 2524 kHz and calls again)

Safety signal (x3)

SAY-CURE-E-TAY, SAY-CURE-E-TAY, SAY-CURE-E-TAY

Station called (x1)

ALL STATIONS

Words “this is”

THIS IS

Station calling (x1)

SEAFOX VL9876

Safety Message POSITION 030 DEGREES 12 NAUTICAL MILES FROM CAPE ARNHEM SHIPPING CONTAINER FLOATING JUST BELOW SURFACE DANGER TO NAVIGATION OUT. 136.2 A Limited Coast Station wishing to attract the attention of all ship stations prior to the broadcast of a routine weather forecast or traffic list may make an announcement to all ships on a calling channel or frequency, indicating the working channel or frequency that the forecast or traffic list will be broadcast on.

Example of a broadcast to all ships announcing the weather forecast or traffic list transmitted by a Coast Radio Station: Traffic or Weather call

ALL SHIPS, spoken not more than three times;

Words “this is”

THIS IS

Station calling (x3)

COAST RADIO HOBART, spoken not more than three times;

Call details

LISTEN FOR WEATHER FORECAST AND TRAFFIC LIST ON 2201.

137. BROADCASTS OF WEATHER INFORMATION OR NAVIGATIONAL WARNINGS FROM STATIONS OTHeR THAN BUReAU OF MeTeOROLOGY OPeRATeD MARINe RADIO STATIONS note: The broadcast of weather bulletins via Maritime Communication Stations is now done automatically. There is no provision for the Bureau of Meteorology to monitor the frequencies prior to the broadcasts of weather information. The information regarding the Bureau of Meteorology weather transmissions is noted in the Introduction to Chapter 3 and the transmission frequencies are listed in Appendix 3. 137.1 A Maritime Communication Station may make announcements prior to the broadcast of navigational or weather information similar to those described in paragraph 136.

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CHAPTER 10 DISTReSS, URGeNCY AND SAFeTY COMMUNICATIONS USING RADIOTeLePHONY ReVISION QUeSTIONS SECTION 23: Priority Calls - General information 118.1 What systems are in place in order to ensure prompt and efﬁcient rescue procedures? 118.2 During distress, urgency or safety radiotelephony communications, what are some ways of avoiding confusion and misunderstandings?

118.3 What compatible radiotelephony mode is required for the broadcast of distress, urgency or safety communications on 2182 kHz?

118.4 Complete the following: “The transmission of false or deceptive distress, urgency or safety calls is .......................”

SECTION 24: Alarm Signals 119.1 How would you recognise the radiotelephony alarm signal? 119.2 What is the purpose of the radiotelephony alarm signal? 119.3 When should the radiotelphony alarm signal be transmitted?

119.4 What type of message may also be preceded by the radiotelephony alarm signal? 119.5 Other than ship stations, what type of station may also use the alarm signal?

119.7 How would you identify an alarm signal transmitted from: (a) a ship station; (b) a coast station?

119.6 What signal is recommended to precede a safety message concerning a cyclone warning?

SECTION 25: Distress Communications 121.1 What priority is given to the distress signal? To whom is the distress call addressed? 121.2 What must you do after receiving a distress call?

126.2 What are the rules concerning repetition of distress calls?

122.1 By whose authority alone may you transmit a distress call?

126.3 If an acknowledgement is not received for your station’s distress message, what should you do next?

123.1 What are the radiotelephony distress frequencies in the 2, 4, 6, 8, 12 and 16 MHz bands?

127.1 What is the primary way of stating the position information in a distress message?

What is the VHF distress channel? 123.5 What are the International DSC distress frequencies in the 2, 4, 6, 8, 12 and 16 MHz bands? What is VHF DSC channel? 124.1 What is the radiotelephony distress signal? 124.2 What does the radiotelephony distress signal indicate? 124.3 When may the radiotelephony distress signal be used? 124.4 What possible implication could result if the distress signal is misused?

125.1 Describe the distress call. 126.1 Describe the distress message.

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129.3 What action would you take with regards to acknowledging the distress alert when you are not very close to a vessel in distress? 129.5 What action would you take with regards to the distress communication when you are not able to assist a vessel in distress?

129.5 What action would you take when you receive a distress message which has not been acknowledged by another station? 127.2 What is possible problem with giving your position using geographic locations 130.1 What expression/s are used to rather than latitude and longitude? acknowledge a distress message, by radiotelephony? 127.3 What additional information may be included in the distress message? 130.2 What information should be included with the distress acknowledgement? 128.1 What word commences distress trafﬁc? 129.1 What must you do on reception of a distress message for a vessel that is in your vicinity?

131.1 Which station controls distress trafﬁc?

131.2 What expression is used by the station in control of distress trafﬁc to impose silence on the frequency or channel 129.2 What action would you take with regards being used for distress communications? to acknowledging the distress message when you are in reliable range of a coast 131.3 May other stations involved in distress station when you receive a distress communications use the expression message? SEELONCE MAYDAY?

131.4 If a station has knowledge of a distress situation and is unable to assist, what must it continue to do? 131.5 If distress communication is taking place on a speciďŹ c frequency or channel, may you continue to use that frequency for other calls? 131.6 If you are unable to assist in the distress situation are you permitted to resume normal communications?

132.2 What expression is used by the station controlling the distress situation to announce resumption of normal communications on the distress frequency or channel? 133.1 What priority message is used when transmitting a distress message on behalf of another station?

133.4 You are about to initiate the transmission of a distress call and message on behalf of another vessel. Describe the sequence. 133.5 Having received a distress message from another vessel, relaying that message to other stations.

133.3 Describe the call for a distress message sent on behalf of another station.

SECTION 26: Urgency and Safety Signals 134.1 What is the radiotelephony urgency signal? 134.5 What frequency may be used to transmit 135.2 What type of message is preceded by the urgency message? the safety signal? 134.1 What priority is given to the urgency call? 134.2 DeďŹ ne the urgency signal. 134.3 On whose sole authority may the urgency signal be transmitted? 134.4 A station hearing an urgency call must take what precautions?

134.5 The urgency message is long and concerns medical advice, what frequency should be used? 134.6 To whom may the urgency signal be addressed?

135.3 What must you do after hearing the announcement of a safety message? 136.1 What frequencies or channels may be used for the broadcast of safety messages?

135.1 What is the radiotelephony safety signal?

NOTES

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CHAPTER 11

OPERATING PROCEDURES FOR ROUTINE COMMUNICATIONS AND PUBLIC CORRESPONDENCE

MARINE RADIO OPERATORS HANDBOOK

Section 27 Routine Calling and Replying Procedures for Radiotelephony 138. Calling Procedures 138.1 As a general rule, it rests with the ship station to call and establish communications with a Maritime Communication Station or Limited Coast station. However, a Maritime Communication Station or Limited Coast Station wishing to communicate with a ship station may call that vessel if it believes that it is within range and is keeping watch. 138.2 A ship station wishing to contact another station must first select a frequency or channel being monitored by that station. 138.3 Before transmitting, the operator should listen for a period long enough to be satisfied that harmful interference will not be caused to communications already in progress. 138.4 When establishing routine communications by Mf/hf radiotelephony, the initial call should be made in the following manner: - the name and/or call sign or other identification of the station being called, spoken not more than three times; - the words THIS IS; and - the name and/or call sign or other identification of the station calling, spoken not more than three times. 138.5 This call should immediately be followed with the purpose of the call, the working frequency that is suggested for the exchange of messages and the word ‘OVER’ (an invitation for the other station to respond).

Example: FREMANTLE SEA RESCUE, FREMANTLE SEA RESCUE, FREMANTLE SEA RESCUE This is SPINDRIFT VLW1234, SPINDRIFT VLW1234, SPINDRIFT VLW1234 POSITION REPORT SUGGEST CHANGE TO 2524 OVER. 138.6 When using radiotelephony channels in the Vhf marine band and communications conditions are good, the first part of a routine call may be abbreviated to: - the name and/or call sign etc. of station being called, spoken once; - the words THIS IS; - the name and/or call sign etc. of station calling, spoken twice.

Example: SANDRINGHAM COAST GUARD This is For example: SAUCY SUE VLV4567, SAUCY SUE VLV4567 POSITION REPORT SUGGEST CHANGE TO CHANNEL 73 OVER. 138.7 On all bands, once contact is established, station names and/or call signs should be spoken once only. ‘THIS IS SAUCY SUE’ 138.8 Reverse calling, for example: ‘TEMPEST VLS5678 CALLING FREMANTLE SEA RESCUE’, should not be used.

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139. Replying to Calls 139.1 A station replying to a radiotelephony call should use the following procedure: - the identification of the station which called, spoken not more than three times; - the words THIS IS; and - the name and/or radiotelephony call sign of the station replying, spoken not more than three times.

Example: SPINDRIFT, SPINDRIFT, SPINDRIFT VLw1234 This is FReMANTLe SeA ReSCUe, FReMANTLe SeA ReSCUe, FReMANTLe SeA ReSCUe RECEIVED* CHANGe TO 2524. *Received is the official response but 'Romeo' is commonly accepted as the official substitute. 139.2 Procedures for replying to radiotelephony calls made on VHF marine bands may be abbreviated in a similar manner to those described in the calling procedures. 139.3 The reply should be immediately followed by an indication that the replying station will also change to the working frequency suggested by the calling station. 139.4 At this point both stations should adjust their radio equipment to transmit and receive on the agreed working frequency (or frequencies) and, after making sure that the frequency (or frequencies) is not occupied by other stations, re-establish communications. 139.5 It is normal practice for the station which made the initial call on the calling frequency to also make the initial call on the working frequency. Once communications have been re-established, the exchange of messages may proceed.

140. Signal For End of Work 140.1 The end of the exchange of radiotelephony messages on the working frequency should be indicated by both stations, by adding the word ‘OUT’. 140.2 Both stations should then resume monitoring of the appropriate distress and calling frequency.

141. Difficulties in Establishing Communications by Radiotelephony 141.1 If a vessel, Maritime Communication Station or Limited Coast Station is unable to communicate with a calling station immediately, it should reply to a call followed by, ‘wait…… minutes’. 141.2 Maritime Communication Stations or Limited Coast Stations that are busy with other ship stations may respond to a call from a vessel with, ‘your turn is number …..’. 141.3 When a station receives a call without being certain that the call is intended for it, it should not reply until that call has been repeated and understood. 141.4 When a station receives a call which is intended for it, but is uncertain of the identification of the calling station, it should reply immediately asking for a repetition of the call sign or other identification of the calling station.

ating 142.1 If no immediate reply is received to the initial routine call, wait two minutes and repeat the call. After two calls wait a further three minutes before calling again. At this point it may be necessary to call another station or to consider whether the station called is in range. Restrictions with regard to repetition of calls do not apply to distress or urgency calls.

MARINE RADIO OPERATORS HANDBOOK

CHAPTER 11 OPeRATING PROCeDUReS FOR ROUTINe stions Section 27: Routine Calling and Replying Procedures for Radiotelephony 138.1 As a general rule, what station would initiate a radiotelephony call? 138.2 What information must a station have in order to contact another station? 138.3 What must an operator do before actually calling another station? 138.4 What is the correct sequence for initiating a routine call on MF/HF frequencies? 138.5 What word must be transmitted indicating an invitation to respond? 138.6 What is the abbreviated method of routine calling on VHF?

138.7 What is the recommended method of identiﬁcation once communication has been established?

141.1 A station unable to communicate with a calling station immediately should instead reply with “..............................”.

138.8 The incorrect calling sequence: “TEMPEST VLS5678 TO FREMANTLE SEA RESCUE” should be corrected to .......................?

141.2 A station which is busy with other communications may respond in which way?

139.1 Describe how a station replies to an initial routine call.

141.3 If a station operator is unsure if their station is being called, what should they do next?

139.3 What information should be included in a 141.4 If a station operator being called is reply to an initial routine call? unable to identify the caller, what should they do next? 140.1 What word should be transmitted 142.1 If you do not receive a reply to your routine indicating an end of communications? call, what should you do?

NOTES

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CHAPTER 12

INFORMATION FOR VESSELS PROCEEDING OVERSEAS

MARINE RADIO OPERATORS HANDBOOK

Section 27 General Information 143. Inspection of Radio Stations 143.1 The owners and operators of vessels proceeding overseas need to be aware that the International Radio Regulations give a signatory nation the right to inspect a ship station visiting any of that nationâ&#x20AC;&#x2122;s ports. 143.2 Authorities in such countries may require the person responsible for the station to produce a valid radio station licence issued by the country in which the vessel is registered. Relevant operators certificates of proficiency must also be produced if required. 143.3 The operators of Australian vessels undertaking overseas voyages must ensure they are able to meet these requirements. Copies of class licences should be carried if relevant. If equipment operating on Amateur radio bands is carried on board, a valid Amateur station licence and an appropriate Amateur certificate of proficiency must be available for inspection. 143.4 Failure to produce these documents may result in authorities carrying out an inspection of the radio station. If irregularities are found, further action may be taken, including an advice to the Australian Government. 143.5 Owners of vessels considering an overseas voyage are reminded of the need to register their vessel with the Australian Register of Ships before leaving. Registration provides owners with official proof of ownership and a nationality for their vessel. A registration certificate is required by law when dealing with overseas authorities and it is mandatory to complete Australian Customs formalities on leaving and reentering the country. 143.6 Any office of the Australian Maritime Safety Authority will provide details of vessel registration.

144. Accounting Authority Identification Code (AAIC) 144.1 International Radio Regulations give foreign administrations the right to collect charges for public correspondence radio communications from the licensee of the ship station. 144.2 A vessel using a foreign coast station for passing public correspondence (written) or making radiotelephone calls to any destination, must be registered with an AAIC. This is an internationally recognised way of providing the coast station with: - a reasonable assurance that payment will be made; and - the name and address of the organisation which will make payment. 144.3 Ship stations wishing to pass paid radiocommunications through any foreign coast station should be prepared to quote an AAIC. Failure to do so is likely to result in the coast station refusing to accept the call or message. 144.4 AAICs have been issued by the ACMA to a number of private enterprises concerned with marine communications. Details of these organisations have been provided by the ACMA to the International Telecommunications Union (ITU), who, in turn, advise all member nations. 144.5 A full list of organisations holding an Australian AAIC may be found in the List of Ship Stations published by the ITU. 144.6 The licensees of vessels wishing to pass paid traffic through foreign coast stations must make the necessary financial arrangements with one of these organisations to ensure prompt payment of accounts arriving from overseas administrations. On completion of these arrangements, the organisation will authorise the ship station licensee to use its AAIC. ACMA offices can provide details of Australian organisations offering this service.

145. Details of Foreign Coast Stations 145.1 Details of foreign coast and land stations providing services to ship radio stations may be found in volumes published by the ITU or the British Admiralty. 145.2 ITU publications of interest to ship station operators include: - the List of Coast Stations, which contains particulars of coast stations and Inmarsat Land earth Stations throughout the world; and - the List of Special Service and Radiodetermination Stations, which contains particulars of coast and land stations broadcasting weather forecasts, navigational warnings and time signals, radio beacons and other specialised services. 145.3 ITU publications are updated at regular intervals by supplements and are available from the International Telecommunications Union, General Secretariat, Sales Service, Place des Nations, CH-1211 Geneva 20, Switzerland. Telephone + 41 22 730 6141 email: sales@itu.int website: www.itu.int

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145.4 The British Admiralty List of Radio Signals is also published in a number of volumes. Those of likely interest to small vessels proceeding overseas are: - Volume 1, parts 1 and 2, which contains particulars of coast stations and Inmarsat Land Earth Stations throughout the world, radio quarantine reporting, ship reporting systems, pollution reports etc; - Volume 2, which contains particulars of radio beacons throughout the world which are suitable for navigation by vessels carrying direction finding equipment, radar beacons, time signals and electronic navigation systems; - Volume 3, which contains particulars of coast and land stations providing weather and navigational bulletins; - Volume 5, which contains particulars of the GMDSS System, SAR, etc; and - Volume 6, parts 1 and 2, which contains particulars of radio communications services operated by port authorities and pilotage services. 145.5 British Admiralty volumes are updated weekly through Australian Notices to Mariners published by the RAN Hydrographic Service. They are generally available from retail outlets specialising in marine publications and navigational charts.

146. Medical Advice 146.1 Coast stations operated by most foreign administrations have arrangements to provide medical advice to vessels at sea. In most cases, the exchange of messages and the advice is provided free of charge. 146.2 In very urgent circumstances, use of the radiotelephony urgency signal or DSC urgency alert is justified.

147. Foreign Ship-Reporting Systems 147.1 The Automated Mutual-Assistance Vessel Rescue System (AMVER) operated by the United States Coast Guard (USCG) provides an aid to search and rescue in all offshore areas of the world. Yachts, fishing vessels and other small vessels proceeding on offshore voyages of longer than twenty-four hours are eligible to participate. Further information is available from the AMVER Maritime Relations, USCG Battery Park Building, New York NY, USA 10004-1499. Telephone + 1 212 668 7762 Fax + 1 212 668 7684 Internet http://www.uscg.mil

148. Time Signals 148.1 Accurate time signals suitable for navigational purposes are still available on the frequencies: 5000, 10 000, 15 000 and 20 000 kHz from various land stations in other parts of the world. Full details of foreign stations broadcasting time signals may be found in the appropriate volumes detailed in paragraphs 145.1 - 145.5.

NOTES

MARINE RADIO OPERATORS HANDBOOK

appendices

AUSTRALIAN MARITIME COLLEGE

APPEnDIX 1 Qualifications Examination Syllabi

EXAMINATION SYLLABUS FOR THE LONG RANGE OPERATOR CERTIFICATE OF PROFICIENCY (LROCP) A candidate will be required to: 1. Demonstrate a practical knowledge of GMDSS sub-systems and equipment which is appropriate to vessels operating in Australian waters on which a radio installation is not compulsory under international agreements. Specifically, MF/HF and VHF radiotelephony equipment with digital selective calling (DSC) facilities and emergency position indicating radio beacons of the 406 MHz type. 2. Demonstrate an ability to use MF/HF and VHF radiotelephony and digital selective calling (DSC) operating procedures, particularly those relating to distress, urgency and safety. 3. Demonstrate an understanding of simple maintenance practices required to keep the marine radio equipment specified in (1) in good working order, including the repair of minor faults. 4. Demonstrate an understanding of the regulations applicable to ship stations equipped with radiotelephony and digital selective calling facilities. 5. Demonstrate a basic knowledge of the Australian marine search and rescue system.

Chapter 1 – GEnERAL SECTION 2 - USE OF SHIP RADIO STATIONS Ship Station Licences (6) Authority of the Master (8) Secrecy of Communications (10) Distress Calls (11) False or Deceptive Distress, Urgency or Safety Signals (12) Unnecessary Transmissions (13) Avoidance of Interference (14) Documents to be Held On Board (15) Log Keeping (16) Ship Station Call Signs and Identities (17) Ship Station Identification (18)

SECTION 3 - MONITORING OF RADIOTELEPHONY FREQUENCIES (WATCHKEEPING) Monitoring of Radiotelephony Distress and Calling Frequencies (19)

SECTIOn 4 - FREQUEnCIES - GENERAL INFORMATION Use of frequencies (21) Control of Communications (22) Test Transmissions (23) Radiotelephony Calling and working Frequencies (24) Radiotelephony Calling Frequencies (25) Radiotelephony working Frequencies (26) Phonetic Alphabet and Figure Code (27) Information for Maritime Communication, Coast Radio and Limited Coast Stations (28) Restrictions to the use of Radio equipment on Ships (29)

Chapter 2 – RADIO PROPAGATION SECTION 5 - FREQUENCY CHARACTERISTICS The Ionosphere (30) Radio Propagation (31) Propagation at MF (32) Propagation at HF (33) Propagation at VHF (34) Modes of Communication (35) Simplex and Duplex (36)

Chapter 3 – COAST STATIONS SECTION 6 - MARINE COMMUNICATION STATIONS Maritime Communication Station Services (37) Location of Maritime Communication Stations (38) Identification of Maritime Communication Stations (39) Monitoring of Frequencies by Maritime Communication Stations (40) Emergency Medical Advice (41)

SECTION 7 - STATE AND NORTHERN TERRITORY HF (COAST RADIO) AND VHF STATIONS Services provided (42) Coast Radio Stations (HF) Maritime Distress and Safety Service (43) VHF Maritime Distress and Safety Service (44)

SECTION 8 - LIMITED COAST STATIONS Services Provided (45) Categories of Limited Coast Station (46) Hours of Operation (47) Identification of Limited Coast Stations (48)

SECTION 9 - VHF MARINE REPEATERS Principle of Operation (49) VHF Marine Repeater Channels (50) Use of VHF Marine Repeaters (51)

MARINE RADIO OPERATORS HANDBOOK

Chapter 4 – POWER SUPPLIES SECTION 10 - CARE AND MAINTENANCE OF LEAD ACID BATTERIES Location of Batteries (52) Construction of Lead Acid Cells (53) Connection of Lead Acid Cells (54) Essential Battery Maintenance (55) Battery Cleanliness (56) Electrolyte Level (57) Correct Charging (58) Measuring the Specific Gravity (59) Measuring the On-Load Terminal Voltage (60) Loss of Capacity (61) Battery Hazards (62)

Chapter 5 – MARINE COMMUNICATIONS EQUIPMENT SECTION 11 - TYPES OF MARINE RADIOCOMMUNICATIONS EQUIPMENT Types of Marine Radio Equipment (65) MF/HF Marine Radio Equipment (66) VHF Marine Radio Equipment (68))

SECTION 12 - COMPONENT PARTS OF MARINE RADIO EQUIPEMENT The Major Parts of Radio Equipment (69) The Power Supply (70) The Transmitter and the Receiver (71) The Antenna (72)

SECTION 13 - TRANSCEIVER CONTROLS Transceiver Controls (73)

SECTION 14 - GENERAL CARE AND MAINTENANCE OF MARINE RADIO EQUIPMENT Care of Transceivers (74) Care of Antenna (75)

SECTION 15 - FAULTS IN MARINE RADIO EQUIPMENT Antenna System Faults (77) Transceiver Faults (78) Power Supply Faults (79)

Chapter 6 – DIGITAL SELECTIVE CALLING SECTIOn 16 – DSC – GEnERAL InFORMATIOn Introduction (80) DSC-Capable equipment (81) DSC Identification (82) Frequencies for DSC Distress, Urgency and Safety Alerts (83) Frequencies for Routine DSC Alerts (84) watchkeeping on DSC Distress, Urgency and Safety Frequencies (85) Information Contained in a DSC Alert (86) DSC Alert Formats (87) DSC Distress Alert Procedures (88) Acknowledgement of Receipt of a DSC Distress Alert on 2187.5 kHz or VHF Channel 70 (89) Acknowledgement of Receipt of a DSC Distress Alert on 4207.5, 6312, 8414.5, 12577 or 16804.5 kHz (90) Transmission of a DSC Distress Alert Relay (91) Acknowledgement of a DSC Distress Relay (92) Cancellation of an Inadvertent DSC Distress Alert (93) Transmission of a DSC Urgency Alert (94) Transmission of a DSC Safety Alert (95)

Chapter 7 – EMERGEnCY POSITIOn InDICATInG RADIO BEACOnS SECTIOn 17 - EMERGEnCY POSITIOn InDICATInG BEACOnS (EPIRBs) General (96) Types of ePIRB (97)

SECTIOn 18 - 121.5 MHz component of 406 MHz EPIRBs Detection and Location by Aircraft (101)

SECTION 19 - 406 MHz EPIRBs Methods of Detection and Location (103) Detection and Location by Aircraft (104) Detection and Location by Satellite (105) Identification of 406 MHz EPIRBs (106) Activation of 406 MHz EPIRBs (107)

SECTION 20 - CARE AND MAINTENANCE OF EPIRBs Servicing (109) Inappropriate Activation of EPIRBs (111)

Chapter 8 – SEARCH AND RESCUE TRANSPONDERS (SARTs) SECTION 21 - SEARCH AND RESCUE TRANSPONDERS (SARTs) Search and Rescue Transponders (112)

AUSTRALIAN MARITIME COLLEGE

Chapter 9 – SEARCH AND RESCUE IN AUSTRALIA SECTIOn 22 - SEARCH AnD RESCUE: GEnERAL InFORMATIOn Automatic Identification System (AIS) (117)

Chapter 10 – DISTRESS, URGEnCY AnD SAFETY COMMUnICATIOnS SECTION 23 - PRIORITY CALLS: GENERAL INFORMATION General Information (118)

SECTION 24 - ALARM SIGNALS The Radiotelephony Alarm Signal (119)

SECTIOn 25 – DISTRESS COMMUnICATIOnS Definition and Priority of Distress (121) Authority to Transmit Distress calls and Messages (122) Frequencies for Distress (123.1/2/5) Distress Signal (124) Distress Call (125) Distress Message (126) Distress Position Information (127) Distress Traffic (128) Obligation to Acknowledge Receipt of a Distress Message (129) Acknowledgement of Receipt of a Distress Message (130) Control of Distress Traffic (131) Resumption of Normal working (132) Transmission of a Distress Message by a Station Not Itself in Distress (133)

SECTIOn 26 - URGEnCY AnD SAFETY SIGnALS The Urgency Signal (134) The Safety Signal (135) Safety Communications (136)

Chapter 11 – OPERATInG PROCEDURES FOR ROUTInE COMMUnICATIOnS SECTIOn 27 - ROUTInE CALLInG AnD REPLYInG PROCEDURES FOR RADIOTELEPHONY Calling Procedures (138) Replying to Calls (139) Signal for end of work (140) Difficulties in establishing Communications (141) Repeating Calls (142)

EXAMINATION SYLLABUS FOR THE SHORT RANGE OPERATOR CERTIFICATE OF PROFICIENCY (SROCP) A candidate for the Short Range Operator Certificate of Proficiency will be required to: 1. Demonstrate a practical knowledge of GMDSS sub-systems and equipment which is appropriate to vessels operating in Australian waters on which a radio installation is not compulsory under international agreements. Specifically, VHF radiotelephony equipment with digital selective calling (DSC) facilities, and emergency position indicating radio beacons of the 406 MHz type. 2. Demonstrate an ability to use VHF radiotelephony and digital selective calling (DSC) operating procedures, particularly those relating to distress, urgency and safety. 3. Demonstrate an understanding of simple maintenance practices required to keep the marine radio equipment specified in (1) in good working order, including the repair of minor faults. 4. Demonstrate an understanding of the regulations applicable to ship stations equipped with VHF radiotelephony and digital selective calling facilities. 5. Demonstrate a basic knowledge of the Australian marine search and rescue system.

Chapter 1 - GENERAL SECTION 2 – USE OF SHIP RADIO STATIONS Ship station licence (6) Authority of Master (8) Secrecy of Communications (10) Distress Calls (11) False or Deceptive Distress, Urgency or Safety Signals (12) Unnecessary Transmissions (13) Avoidance of Interference (14) Documents to be Held on Board (15) Log Keeping (16) Ship Station Call Signs and Identities (17) Ship Station Identification (18)

SECTION 3 - MONITORING OF RADIOTELEPHONY FREQUENCIES (WATCHKEEPING) Monitoring of Radiotelephony Distress and Calling Frequencies (19)

MARINE RADIO OPERATORS HANDBOOK

SECTIOn 4 – FREQUEnCIES - GEnERAL InFORMATIOn Use of Frequencies (21) Control of Communications (22) Test Transmissions (23) Radiotelephony Calling and working Frequencies (24) Radiotelephony Calling Frequencies (25) Radiotelephony working Frequencies (26) Phonetic Alphabet and Figure Code (27) Information for Maritime Communication, Coast Radio Stations and Limited Coast Stations (28) Restrictions to the Use of Radio equipment (29)

Chapter 2 – RADIO PROPAGATION SECTION 5 - FREQUENCY CHARACTERISTICS The Ionosphere (30) Radio Propagation (31) Radio Propagation at VHF (34) Modes of Communication (35) Simplex and Duplex Communications Modes of Operation (36)

Chapter 3 – COAST STATIONS SECTIOn 7 - STATE AnD nORTHERn TERRITORY HF (Coast Radio Stations) AnD VHF STATIOnS Services Provided (42) VHF maritime distress and safety service (44)

SECTION 8 - LIMITED COAST STATIONS Services Provided (45) Categories of Limited Coast Stations (46) Hours of Operation (47) Identification of Limited Coast Stations (48)

SECTION 9 - VHF MARINE REPEATERS Principle of Operation (49) VHF Repeater Channels (50) Use of Repeaters (51)

Chapter 4 – POWER SUPPLIES SECTION 10 - CARE AND MAINTENANCE OF BATTERIES Location of Batteries (52) Construction of the Lead Acid Batteries (53) Connection of Lead Acid Batteries (54) Essential Battery Maintenance (55) Battery Cleanliness (56) Electrolyte Level (57) Correct Charging (58) Measuring the Specific Gravity (59) Measuring the On-Load Terminal Voltage (60) Loss of Capacity (61) Battery Hazards (62)

Chapter 5 – MARINE COMMUNICATIONS EQUIPMENT SECTION 11 - TYPES OF MARINE RADIO EQUIPMENT Types of Marine Radio Equipment (65) VHF Marine Radio Equipment (68)

SECTION 12 - COMPONENT PARTS OF MARINE RADIO EQUIPMENT The Major Parts of Radio Equipment (69) The Power Supply (70) The Transceiver (71) The Antenna (72)

SECTION 13 - TRANSCEIVER CONTROLS Transceiver Controls (73 – Marine VHF)

SECTION 14 - GENERAL CARE AND MAINTENANCE OF MARINE RADIO EQUIPMENT Care of Transceivers (74) Care of Antennas (75)

SECTION 15 - FAULTS IN MARINE RADIO EQUIPMENT Antenna System Faults (77) Transceiver Faults (78) Power Supply Faults (79)

Chapter 6 – DIGITAL SELECTIVE CALLING SECTIOn 16 - DSC - GEnERAL InFORMATIOn Introduction (80) DSC Capable equipment (81) DSC Identification (82) Frequencies for DSC Distress, Urgency and Safety Alerts (83) Frequencies for Routine Alerts (84) watchkeeping on DSC Distress, Urgency and Safety Frequencies (85) Information contained in a DSC Alert (86) DSC Alerts Formats (87) DSC Distress Alert Procedures (88) Acknowledgement of Receipt of Distress Alert on VHF 2187.5 kHz or VHF Channel 70 (89) Transmission of a Distress Alert Relay (91) Acknowledgement of a DSC Distress Alert Relay (92) Cancellation of an Inadvertent DSC Distress Alert (93) Transmission of a DSC Urgency Alert (94) Transmission of a DSC Safety Alert (95)

AUSTRALIAN MARITIME COLLEGE

Chapter 7 –EMERGENCY POSITION INDICATING RADIO BEACONS SECTION 17 – EMERGENCY POSITION INDICATING BEACONS (EPIRBs) General (96) Types of EPIRB (97)

SECTIOn 18 - 121.5 MHz component of 406 MHz EPIRBs Detection & Location by Aircraft (101)

SECTIOn 19 - 406 MHz EPIRBs Methods of Detection & Location (103) Detection & Location by Aircraft (104) Detection & Location by Satellite (105) Identification of 406 MHz ePIRB (106) Activation of 406 MHz ePIRB (107)

SECTION 20 - CARE AND MAINTENANCE OF EPIRBs Servicing (109) Inappropriate Activation (111)

Chapter 8 – SEARCH AND RESCUE TRANSPONDERS SECTIOn 21 - SEARCH AnD RESCUE RADAR TRAnSPOnDERS (SARTs) Search and Rescue Transponders (112)

Chapter 9 – SEARCH AND RESCUE IN AUSTRALIA SECTIOn 22 - SEARCH AnD RESCUE: GEnERAL InFORMATIOn Automatic Identification System (AIS) (117)

Chapter 10 – DISTRESS URGENCY AND SAFETY COMMUNICATIONS SECTION 23 - PRIORITY CALLS General Information (118)

SECTION 24 – ALARM SIGNALS The Radiotelephony Alarm Signal (119) The Navigational Warning Signal (120)

SECTIOn 25 – DISTRESS COMMUnICATIOnS Distress Communication (121) Authority to Transmit Distress Calls and Messages (122) Frequencies for Distress (123) The Distress Signal (124) The Distress Call (125) The Distress Message (126) Distress Position Information (127) Distress Traffic (128) Obligation to Acknowledge Receipt of a Distress Message (129) Acknowledgement of Receipt of a Distress Message (130) Control of Distress Traffic (131) Resumption of Normal working (132) Transmission of a Distress Message by a Station not itself in Distress (133)

SECTION 25 - URGENCY AND SAFETY SIGNALS The Urgency Signal (134) The Safety Signal (135) Safety Communications (136)

Chapter 11- OPERATING PROCEDURES FOR ROUTINE COMMUNICATIONS SECTIOn 27 - ROUTInE CALLInG AnD REPLYInG PROCEDURES FOR RADIOTELEPHONY Calling Procedures (138) Replying to Calls (139) Signal for end of work (140) Difficulties in establishing Communications (141) Repeating Calls (142)

MARINE RADIO OPERATORS HANDBOOK

Appendix 2 SUGGESTED FORMAT FOR A RADIO LOGBOOK PAGE: Call Sign:

Name of Vessel:

Date and Time

MMSI:

Station/MMSI from

Station/MMSI to

Details of Calls, Signals & Distress Working

Frequency/Channel

AUSTRALIAN MARITIME COLLEGE

Appendix 3 FREQUENCIES FOR USE BY SHIP STATIONS All frequencies are carrier frequencies. In the case of single sideband (SSB) transmissions, the assigned frequency is 1.4 kHz higher.

Table 1. Distress, Urgency, Safety and Calling Frequencies (for use by all vessels)

Carrier Frequency (Tx/Rx) & Channel No.

Communicating with

Purpose

2182 kHz

Limited Coast and ship stations

Distress, urgency, safety and routine calling

2187.5 kHz

Limited Coast and ship stations

DSC Distress, urgency and safety alerting

4125 kHz

Maritime Communication*, Limited Coast** and ship stations

Distress, urgency and safety calling

4207.5 kHz

Maritime Communication*, Limited Coast and ship stations

DSC Distress, urgency and safety alerting

6215 kHz

Maritime Communication*, Limited Coast** and ship stations

Distress, urgency and safety calling

6312 kHz

Maritime Communication, Limited Coast and ship stations

DSC Distress, urgency, safety alerting

8291 kHz

Maritime Communication*, Limited Coast** and ship stations

Distress, urgency and safety calling

8414.5 kHz

Maritime Communication, Limited Coast and ship stations

DSC Distress, urgency, safety alerting

12 290 kHz

Maritime Communication*, Limited Coast and ship stations

Distress, urgency and safety

12 359 kHz

Limited Coast and ship stations

Routine calling

12 577 kHz

Maritime Communication, Limited Coast and ship stations

DSC Distress, urgency, safety alerting

16 420 kHz

Maritime Communication*, Limited Coast and ship stations

Distress, urgency and safety

16 537 kHz

Limited Coast and ship stations

Routine calling

16 804.5 kHz

Maritime Communication, Limited Coast and ship stations

DSC Distress, urgency, safety alerting

121.5 MHz

earth stations via satellites, aircraft

EPIRB

156.300 MHz (Ch 6)

Ship and aircraft

Co-ordinated Search and Rescue (SAR)

156.375 MHz (Ch 67)

Limited Coast and ship stations

Distress, urgency and safety calling (supp to Ch 16)

156.525 MHz (Ch 70)

Limited Coast and ship stations

DSC Distress, urgency, safety and routine alerting

156.650 MHz (Ch 13)

Ship stations

Internship Maritime Safety Information

156.800 MHz (Ch 16)

Limited Coast and ship stations

Distress, urgency, safety and routine calling

406.025 MHz

Earth stations via satellites

EPIRBs

406.028 MHz

Earth stations via satellites

EPIRBs with GPS

1530-1545 MHz

Coast earth and ship earth stations via satellites

Inmarsat systems

1626.6-1646.5 MHz

Coast earth and ship earth stations via satellites

Inmarsat systems

* Maritime communication stations do not provide aural monitoring of these frequencies, but may continue to use them for establishing communication with ship stations. ** It is intended that these frequencies are monitored by stations set up by Governments of the States and the Northern Territory. See Section 7 for further information.

MARINE RADIO OPERATORS HANDBOOK

Table 2. Professional Fishing Vessels Frequencies

Carrier Frequency (Tx/Rx) & Channel No.

Communicating with

Purpose

2112 kHz

Limited Coast and ship stations

Calling and working

2164 kHz

Ship Stations

Calling and working

4535 kHz*

Limited Coast and ship stations

Calling and working

4620 kHz*

Limited Coast and ship stations

Calling and working

27.72 MHz (Ch 72)

Limited Coast and ship stations

Calling and working

27.82 MHz (Ch 82)

Limited Coast and ship stations

Calling and working

156.575 MHz (Ch 71)

Limited Coast and ship stations

Calling and working

156.625 MHz (Ch 72)

Ship stations

Calling and working

156.875 MHz (Ch 77)

Ship stations

Calling and working

* Intership use restricted to communications concerning safety of vessels and persons.

Table 3. Commercial Vessel Frequencies

Carrier Frequency (Tx/Rx) & Channel No.

Communicating with

Purpose

1715 kHz*

Limited Coast and ship stations

Calling and working

1725 kHz*

Limited Coast and ship stations

Calling and working

1775 kHz*

Limited Coast and ship stations

Calling and working

2008 kHz*

Limited Coast and ship stations

Calling and working

2032 kHz*

Limited Coast and ship stations

Calling and working

2436 kHz*

Limited Coast and ship stations

Calling and working

2638 kHz

Ship stations

Calling and working

27.68 MHz (Ch 68)

Limited Coast Stations and ship stations

Calling and working

156.300 MHz (Ch 6)

Ship stations

Calling and working

156.400 MHz (Ch 8)

Ship stations

Calling and working

156.625 MHz (Ch 72)

Ship stations

Calling and working

156.725 MHz (Ch 74)

Limited Coast and ship stations

Calling and working

156.925/161.525 MHz (Ch 78)

Limited Coast Stations

Calling and working

* Use restricted to communications with Limited Coast Stations operated by an organisation of which the licensee is a member, and to intership communications with other members.

Table 4. Yachts and Pleasure Vessels Frequencies

Carrier Frequency (Tx/Rx) & Channel No.

Communicating with

Purpose

2284 kHz

Ship stations in pleasure vessels

Calling and working

2524 kHz*

Limited Coast and ship stations in pleasure vessels

Calling and working

156.625 MHz (Ch 72)

Ship stations

Calling and working

156.675 MHz (Ch 73)

Limited Coast and ship stations

Calling and working

156.875 MHz (Ch 77)

Ship stations

Calling and working

* Communications on 2524 kHz with limited coast stations restricted to those concerning the safety of vessels and persons. AUSTRALIAN MARITIME COLLEGE

Table 5. Inshore Boating Service Frequencies

Carrier Frequency (Tx/Rx) & Channel No.

Communicating with

Purpose

1715, 1725, 1775, 2008, 2032, 2436 kHz*

Limited Coast and ship stations

Calling and working

Limited Coast stations

Calling and working

27.91 MHz (Ch 91)*

Limited Coast stations

Calling and working

27.94 MHz (Ch 94)*

Limited Coast and ship stations

Calling and working

27.96 MHz (Ch 96)

Ship stations

Calling and working

27.98

Limited Coast Stations, ship and mobile stations

Calling and working by safety organisations

27.90 MHz (Ch 90)*

MHz (Ch 98)

* Use restricted to communications with limited coast stations operated by an organisation of which the licensee is a member, and to intership communications with other members.

Table 6. Port Operations Frequencies

Carrier Frequency (Tx/Rx) & Channel No.

Communicating with

Purpose

156.300 MHz (Ch 6)

Ship stations

Calling and working

156.400 MHz (Ch 8)

Ship stations

Calling and working

156.425 MHz (Ch 68)

Limited Coast Stations

Calling and working

156.450 MHz (Ch 9)

Limited Coast and ship stations

Calling and working

156.500 MHz (Ch 10)

Limited Coast and ship stations

Calling and working

156.550 MHz (Ch 11)

Limited Coast Stations

Calling and working

156.600 MHz (Ch 12)

Limited Coast Stations

Calling and working

156.625 MHz (Ch 72)

Ship stations

Calling and working

156.650 MHz (Ch 13)

Limited Coast Stations and ship stations

Calling and working

156.700 MHz (Ch 14)

Limited Coast Stations

Calling and working

156.975/161.575 MHz (Ch 79)

Limited Coast Stations

Calling and working

157.000/161.600 MHz (Ch 20)

Limited Coast Stations

Calling and working

Table 7. General Correspondence Frequencies Ship stations may use those MF/HF and VHF frequencies detailed by their provider for general correspondence. Subject to the International Radio Regulations, when operating outside Australian territorial waters, ship stations may use any maritime mobile frequency authorised by those regulations. Details may be found in the Manual for Use by the Maritime Mobile and Maritime Mobile-Satellite Service, published by the International Telecommunication Union.

Table 8. VHF Marine Repeater Channels

Carrier Frequency (Tx/Rx) & Channel No.

Communicating with

157.050/161.650 MHz (Ch 21)

Limited Coast and ship stations via repeaters

Vessel movements, safety of vessels and persons

157.100/161.700 MHz (Ch 22)

Limited Coast and ship stations via repeaters

Vessel movements, safety of vessels and persons

157.025/161.625 MHz (Ch 80)

Limited Coast and ship stations via repeaters

Vessel movements, safety of vessels and persons

157.075/161.675 MHz (Ch 81)

Limited Coast and ship stations via repeaters

Vessel movements, safety of vessels and persons

157.125/161.725 MHz (Ch 82)

Limited Coast and ship stations via repeaters

Vessel movements, safety of vessels and persons

MARINE RADIO OPERATORS HANDBOOK

Purpose

Table 9. On-Board Communications Frequencies

Carrier Frequency (Tx/Rx) & Channel No.

Communicating with

Purpose

457.525 MHz

Stations on board the vessel

Calling and working

457.550 MHz

Stations on board the vessel

Calling and working

457.575 MHz

Stations on board the vessel

Calling and working

467.525 MHz

Stations on board the vessel

Calling and working

467.550 MHz

Stations on board the vessel

Calling and working

467.575 MHz

Stations on board the vessel

Calling and working

* These frequencies may be used with six simplex channels or three duplex channels.

Table 10. Radar Frequencies Frequency Band

Frequency Band

Purpose

2.9 â&#x20AC;&#x201C; 3.1 GHz

Marine navigation

9.3 â&#x20AC;&#x201C; 9.5 GHz

Marine navigation and radar transponders

Table 11. Broadcast of Weather Information from VMC Australia Weather East at Charleville (Qld)

Frequency Band

Purpose

2201 kHz 4426 kHz 6507 kHz 8176 kHz* 12 365 kHz 16 546 kHz

Frequencies used by Maritime Communication Stations to broadcast weather forecasts and warnings. The broadcasts are generated by the Bureau of Meteorology and automatically transmitted on these frequencies.

* This frequency is also used by stations set up by the States and the Northern Territory to broadcast navigational warnings. See Section 7 for more information.

Table 12. Broadcast of weather Information from VMw Australia weather west at wiluna (wA)

Frequency Band

Purpose

2056 kHz 4149 kHz 6230 kHz 8113 kHz 12 362 kHz 16 528 kHz

Table 13. Broadcast of Weather and Ocean charts via Radio Fax from VMC Australia Weather East at Charleville (Qld)

Frequency Band

Purpose

2628 kHz 5100 kHz 11 030 kHz 13 920 kHz 20 469 kHz

AUSTRALIAN MARITIME COLLEGE

Table 14. Broadcast of Weather and Ocean charts via Radio Fax from VMW Australia Weather West at Wiluna (WA)

Frequency Band

Purpose

5755 kHz

7535 kHz 10 555 kHz 15 615 kHz 18 060 kHz

Table 15. Units of Frequency. Sub division of the radio frequency spectrum

Units of Frequency The kilohertz (kHz)

1,000 hertz

The megahertz (MHz)

1,000,000 hertz

The gigahertz (GHz)

1,000,000,000 hertz

Spectrum – The radio frequency spectrum is sub-divided into eight bands, as follows: Very Low Frequencies

(VLF)

3 to 30 kHz

Low Frequencies

(LF)

30 to 300 kHz

Medium Frequencies

(MF)

300 to 3000 kHz (or 3MHz)

High Frequencies

(HF)

3 MHz to 30 MHz

Very High Frequencies

(VHF)

30 to 300 MHz

Ultra High Frequencies

(UHF)

300 to 3000 MHz (or 3 GHz)

Super High Frequencies

(SHF)

3 GHz to 30 GHz

Extra High Frequencies

(EHF)

30 – 300 GHz

Table 16. Internet websites for general interest

www.acma.gov.au

Australian Communications & Media Authority

www.amsa.gov.au

Australian Maritime Safety Authority

www.bom.gov.au

Bureau of Meteorology

www.cospas-sarsat.org

Cospas Sarsat

www.gmdss.com.au

Global Maritime Distress and Safety System

www.imo.org

International Maritime Organisation

www.inmarsat.com

International Maritime Satellite Service

www.itu.int

International Telecommunications Union

www.painswessex.com.au

Pains Wessex Australia

www.admiraltyleisure.co.uk

British Admiralty/Products/Publications/Maritime Communications

MARINE RADIO OPERATORS HANDBOOK

Appendix 4 Table of Transmitting Frequencies in the VHF Maritime Mobile Band extracted from Appendix 18 (wRC12) to the ITU Radio Regulations NOTE A – For assistance in understanding the Table, see Notes a) to z) below. (WRC12) NOTE B – The Table below defines the channel numbering for maritime VHF communications based on 25 kHz channel spacing and use of several duplex channels. The channel numbering and the conversion of two-frequency channels for single-frequency operation shall be in accordance with Recommendation ITUR M.10844 Annex 4, Tables 1 and 3. The Table below also describes the harmonized channels where the digital technologies defined in the most recent version of Recommendation ITUR M.1842 could be deployed. (WRC12)

Channel designator Notes* 60 01 61 02 62 03 63 04 64 05 65 06

From Ship Stations

From Coast Stations

156.025

160.625

156.050

160.650

156.075

160.675

156.100

160.700

156.125

160.725

156.150

160.750

156.175

160.775

156.200

160.800

156.225

160.825

156.250

160.850

156.275

160.875

156.300

160.900

156.325

160.925

156.350

160.950

156.375

156.400 68

i) 69

h), q) 70

156.425

156.450

156.475

156.500

156.525

156.525 156.550

156.575

156.600

Digital selective calling for distress, safety and calling

156.625

156.650

h), i)

156.675

156.700

74 g) 75

156.550

14 15

12 72

f), j)

Single frequency Two frequency

Public correspondence

66 67

Inter-ship

Port operations and ship movements

2006 07

Transmitting frequencies (MHz)

156.725

156.750

n), s)

156.775

156.800

X X X

X X DISTRESS, SAFETY AND CALLING

AUSTRALIAN MARITIME COLLEGE

Channel designator Notes* 76 17

From Ship Stations

From Coast Stations

n), s)

156.825

156.850

77 18 78

156.875

X 161.500

156.925

161.525

156.925

161.525

156.950

161.550

156.950

161.550

156.975

161.575

156.975

161.575

157.000

161.600

157.000

1019 2019 t), u), v)

1079 2079 t), u), v)

1020 2020

161.600

w), y)

157.025

161.625

w), y)

157.050

161.650

w), y)

157.075

161.675

w), y)

157.100

161.700

w), x), y)

157.125

161.725

w), x), y)

157.150

161.750

w), x), y)

157.175

161.775

w), ww), x), y)

157.200

161.800

w), ww), x), y)

157.225

161.825

w), ww), x), y)

157.250

161.850

w), ww), x), y)

157.275

161.875

w), ww), x), y)

157.300

161.900

w), ww), x), y)

157.325

161.925

157.350

161.950

157.375

157.400

162.000

157.425

AIS 1

f), l), p)

161.975

AIS 2

f), l), p)

162.025

80 21 81 22 23

24 84 25 85 26

27 28

156.900

t), u), v)

Single frequency Two frequency

Public correspondence

2078

Inter-ship

Port operations and ship movements

t), u), v)

1078 19

Transmitting frequencies (MHz)

MARINE RADIO OPERATORS HANDBOOK

X X

Notes referring to the Table a)

Administrations may designate frequencies in the inter-ship, port operations and ship movement services for use by light aircraft and helicopters to communicate with ships or participating coast stations in predominantly maritime support operations under the conditions specified in Nos. 51.69, 51.73, 51.74, 51.75, 51.76, 51.77 and 51.78. However, the use of the channels which are shared with public correspondence shall be subject to prior agreement between interested and affected administrations.

channels of the present Appendix, with the exception of channels 06, 13, 15, 16, 17, 70, 75 and 76, may also be used for high-speed data The and facsimile transmissions, subject to special arrangement between interested and affected administrations.

channels of the present Appendix, with the exception of channels 06, 13, 15, 16, 17, 70, 75 and 76, may be used for direct-printing The telegraphy and data transmission, subject to special arrangement between interested and affected administrations. (WRC12)

frequencies in this table may also be used for radiocommunications on inland waterways in accordance with the conditions specified in The No. 5.226.

Administrations may apply 12.5 kHz channel interleaving on a non-interference basis to 25 kHz channels, in accordance with the most recent version of Recommendation ITUR M.1084, provided: – it shall not affect the 25 kHz channels of the present Appendix maritime mobile distress and safety, automatic identification system (AIS), and data exchange frequencies, especially the channels 06, 13, 15, 16, 17, 70, AIS 1 and AIS 2, nor the technical characteristics set forth in Recommendation ITUR M.4892 for those channels; – implementation of 12.5 kHz channel interleaving and consequential national requirements shall be subject to coordination with affected administrations. (WRC12)

Specific notes f)

The frequencies 156.300 MHz (channel 06), 156.525 MHz (channel 70), 156.800 MHz (channel 16), 161.975 MHz (AIS 1) and 162.025 MHz (AIS 2) may also be used by aircraft stations for the purpose of search and rescue operations and other safety-related communication. (WRC07)

Channels 15 and 17 may also be used for onboard communications provided the effective radiated power does not exceed 1 W, and subject to the national regulations of the administration concerned when these channels are used in its territorial waters.

h) Within the European Maritime Area and in Canada, these frequencies (channels 10, 67, 73) may also be used, if so required, by the individual administrations concerned, for communication between ship stations, aircraft stations and participating land stations engaged in coordinated search and rescue and anti-pollution operations in local areas, under the conditions specified in Nos. 51.69, 51.73, 51.74, 51.75, 51.76, 51.77 and 51.78. i)

The preferred first three frequencies for the purpose indicated in Note a) are 156.450 MHz (channel 09), 156.625 MHz (channel 72) and 156.675 MHz (channel 73).

Channel 70 is to be used exclusively for digital selective calling for distress, safety and calling.

Channel 13 is designated for use on a worldwide basis as a navigation safety communication channel, primarily for intership navigation safety communications. It may also be used for the ship movement and port operations service subject to the national regulations of the administrations concerned.

These channels (AIS 1 and AIS 2) are used for an automatic identification system (AIS) capable of providing worldwide operation, unless other frequencies are designated on a regional basis for this purpose. Such use should be in accordance with the most recent version of Recommendation ITUR M.1371. (WRC07)

These channels may be operated as single frequency channels, subject to coordination with affected administrations. (WRC07)

n) With the exception of AIS, the use of these channels (75 and 76) should be restricted to navigation-related communications only and all precautions should be taken to avoid harmful interference to channel 16, by limiting the output power to 1 W. (WRC12) o)

(SUP - WRC-12)

Additionally, AIS 1 and AIS 2 may be used by the mobile-satellite service (Earth-to-space) for the reception of AIS transmissions from ships. (WRC07)

q) When using these channels (10 and 11), all precautions should be taken to avoid harmful interference to channel 70. (WRC07) r)

In the maritime mobile service, this frequency is reserved for experimental use for future applications or systems (e.g. new AIS applications, man over board systems, etc.). If authorized by administrations for experimental use, the operation shall not cause harmful interference to, or claim protection from, stations operating in the fixed and mobile services. (WRC12)

Channels 75 and 76 are also allocated to the mobile-satellite service (Earth-to-space) for the reception of long-range AIS broadcast messages from ships (Message 27; see the most recent version of Recommendation ITUR M.1371). (WRC12)

AUSTRALIAN MARITIME COLLEGE

Until 1 January 2017, in Regions 1 and 3, the existing duplex channels 78, 19, 79 and 20 can continue to be assigned. These channels may be operated as single-frequency channels, subject to coordination with affected administrations. From that date, these channels shall only be assigned as single-frequency channels. However, existing duplex channel assignments may be preserved for coast stations and retained for vessels, subject to coordination with affected administrations. (WRC12)

In Region 2, these channels may be operated as single-frequency channels, subject to coordination with affected administrations. (WRC12)

After 1 January 2017, in the Netherlands, these channels may continue to be operated as duplex frequency channels, subject to coordination with affected administrations. (WRC12)

In Regions 1 and 3: Until 1 January 2017, the frequency bands 157.025-157.325 MHz and 161.625-161.925 MHz (corresponding to channels: 80, 21, 81, 22, 82, 23, 83, 24, 84, 25, 85, 26, 86) may be used for new technologies, subject to coordination with affected administrations. Stations using these channels or frequency bands for new technologies shall not cause harmful interference to, or claim protection from, other stations operating in accordance with Article 5. From 1 January 2017, the frequency bands 157.025157.325 MHz and 161.625-161.925 MHz (corresponding to channels: 80, 21, 81, 22, 82, 23, 83, 24, 84, 25, 85, 26, 86) are identified for the utilization of the digital systems described in the most recent version of Recommendation ITUR M.1842. These frequency bands could also be used for analogue modulation described in the most recent version of Recommendation ITUR M.1084 by an administration that wishes to do so, subject to not claiming protection from other stations in the maritime mobile service using digitally modulated emissions and subject to coordination with affected administrations. (WRC12)

ww) In Region 2, the frequency bands 157.200-157.325 and 161.800-161.925 MHz (corresponding to channels: 24, 84, 25, 85, 26 and 86) are designated for digitally modulated emissions in accordance with the most recent version of Recommendation ITUR M.1842. (WRC12) x)

From 1 January 2017, in Angola, Botswana, Lesotho, Madagascar, Malawi, Mauritius, Mozambique, Namibia, Democratic Republic of the Congo, Seychelles, South Africa, Swaziland, Tanzania, Zambia and Zimbabwe, the frequency bands 157.125-157.325 and 161.725161.925 MHz (corresponding to channels: 82, 23, 83, 24, 84, 25, 85, 26 and 86) are designated for digitally modulated emissions. From 1 January 2017, in China, the frequency bands 157.150-157.325 and 161.750-161.925 MHz (corresponding to channels: 23, 83, 24, 84, 25, 85, 26 and 86) are designated for digitally modulated emissions. (WRC12)

100

These channels may be operated as single or duplex frequency channels, subject to coordination with affected administrations. (WRC12)

These channels may be used for possible testing of future AIS applications without causing harmful interference to, or claiming protection from, existing applications and stations operating in the fixed and mobile services. (WRC12)

MARINE RADIO OPERATORS HANDBOOK

Appendix 5 Phonetic Alphabet As per the International Maritime Organisation (IMO) Standard Marine Communications Phrases (2002). When it is necessary to spell out call signs and words the following letter spelling table should be used:

Letter to be transmitted

Code word to be used

Spoken as *

Alfa

AL FAH

Bravo

BRAH VOH

Charlie

CHAR Lee or SHAR Lee

Delta

DeLL TAH

Echo

eCK OH

Foxtrot

FOKS TROT

Golf

GOLF

Hotel

HOH TeLL

India

IN Dee AH

Juliett

Jew Lee eTT

Kilo

KeY LOH

Lima

Lee MAH

Mike

MIKe

November

NO VeM BeR

Oscar

OSS CAH

Papa

PAH PAH

Quebec

KeH BeCK

Romeo

ROw Me OH

Sierra

See AIR RAH

Tango

Uniform

TAN GO YOU Nee FORM or OO Nee FORM

Victor

VIK TAH

Whiskey

wISS KeY

X-ray

eCKS RAY

Yankee

YANG KeY

Zulu

ZU LU

* The syllables to be emphasised are underlined.

AUSTRALIAN MARITIME COLLEGE

101

Figure Code A few digits and numbers have a modified pronunciation compared to general English:

Letter to be transmitted

Code word to be used

Spoken as

zero

ZEEROH

one

WUN

two

TOO

three

TREE

four

FOWER

five

FIFE

six

SIX

seven

SEVEN

eight

AIT

nine

NINER

One zero

WUNZEEROH

1000

thousand

TOUSAND

Decimal point

Decimal

DAY-SEE-MAL

Full stop

Stop

STOP

Oblique Stroke

OBLIQUE

Appendices â&#x20AC;&#x201C; Revision Questions Appendices 3 and 4: Frequencies and Channels - what is the 2 MHz radiotelephony distress frequency? - what is the 2 MHz DSC distress frequency? - what are the 4 MHz, 6 MHz, 8 MHz, 12 MHz and 16 MHz radiotelephony distress frequencies? - what is the VHF Distress Channel? - what is the VHF DSC Channel? - what VHF Channel is reserved for marine ship to ship safety messages? - what Marine VHF Channel may be used for coordinating search and rescue with aircraft? - In Australia, what VHF Channel is supplementary to Channel 16?

Appendix 5: Phonetic Alphabet - What is the correct phonetic alphabet spelling of the word ORGANIZED?

102

MARINE RADIO OPERATORS HANDBOOK

Appendix 6 Standard Marine Communication Phrases English is the language most widely used at sea. To facilitate radiotelephony communications, the International Maritime Organisation has compiled a vocabulary of frequently used words and phrases in a book entitled Standard Marine Communication Phrases (SMCP). The complete SMCP is also available at the IMO website at: http://www.imo.org. In the interests of accuracy, brevity and clarity it is sound practice for operators to use the standard vocabulary when possible. A selection of the standard vocabulary is contained in the following paragraphs.

Message markers If necessary, messages passed by radiotelephony may be preceded by the following message markers: ‘Question’ Indicates the following message is of interrogative character. ‘Answer’

Indicates that the following message is the reply to a previous question.

‘Request’

Indicates that the content of the following message is asking for action with respect to the ship.

‘Information’

Indicates that the following message is restricted to observed facts.

‘Intention’

Indicates that the following message informs others about immediate navigational actions intended to be taken.

‘Warning’

Indicates that the following message informs other traffic participants about dangers.

‘Advice’

Indicates that the following message implies the intention of the sender to influence the recipient(s) by a recommendation.

‘Instruction’

Indicates that the following message implies the intention of the sender to influence the recipient(s) by a regulation.

Responses Where the answer to a question is in the affirmative, say: ‘Yes’ followed by the appropriate phrase in full. Where the answer to a question is in the negative, say: ‘No’ followed by the appropriate phrase in full. Where the information is not immediately available, but soon will be, say: ‘Stand by’. Where the information cannot be obtained, say: ‘No information’. Where a message is not properly heard, say: ‘Say again’. Where a message is not understood, say: ‘Message not understood’. Miscellaneous Phrases ‘What is your vessel’s name (and call sign)?’ ‘How do you read (me)?’ ‘I read you. . .

with signal strength one (i.e.) barely perceptible with signal strength two (i.e.) weak with signal strength three (i.e.) fairly good with signal strength four (i.e.) good

Excellent/five

with signal strength five’

‘Stand by on channel....’ ‘Change to channel.... ‘ ‘I cannot read you (pass your message through..../Advise try channel....)’ ‘I cannot understand you. Please use the Standard Marine Vocabulary/International Code of Signals.’ ‘Correction…..’ plus the corrected part of the message. ‘Mistake…..’ followed by the word, e.g. Speed 14 (one four) kts – mistake – correction speed 12 (one

two) kts.’

AUSTRALIAN MARITIME COLLEGE

103

Relay

I am passing a message for vessel....

Go ahead

I am ready/not ready to receive your message I do not have channel.... Please use channel....

Repetition If any parts of the message are considered sufficiently important to need particular emphasis, use the word ‘repeat’, e.g. ‘Do not repeat do not overtake’. Acknowledgement

'Received' is the official response but 'Romeo' is commonly accepted as the official substitute.

Position When latitude and longitude are used, these should be expressed in degrees and minutes (and decimals of a minute, if necessary), north or south of the Equator and east or west of Greenwich. When the position is related to a mark, the mark shall be a well-defined charted object. The bearing shall be in the 360-degree notation from true north and shall be that of the position from the mark. Courses Courses should always be expressed in the 360-degree notation from true north (unless otherwise stated). Whether this is to, or from, a mark can be stated. Bearings

The bearing of the mark or vessel concerned is the bearing in the 360-degree notation from true north (unless otherwise stated), except in the case of relative bearings. Bearings may be either from the mark or from the vessel.

Distances Distances should be expressed in nautical miles or cables (tenths of a nautical mile), otherwise in kilometres or metres. The unit should always be stated. Speed Speed should be expressed in knots (without further notation meaning speed through the water). ‘Ground speed’ meaning speed over the ground. Numbers

Numbers should be transmitted by speaking each digit separately, for example one five zero for 150.

Geographical names Place names used should be those on the chart or Sailing Directions in use. Should these not be understood, latitude and longitude should be used. Time

104

Time should be expressed in the 24-hour notation indicating whether UTC, zone-time or local shoretime is being used.

MARINE RADIO OPERATORS HANDBOOK

Appendix 7 Contact details

Office of Maritime Communications Australian Maritime College (AMC)

Australian Communications & Media Authority (ACMA)

Internet:

www.amc.edu.au/marineradio

Central Office: Maritime Way Newnham 7248 Locked Bag 1394 Launceston TAS 7250 Free call:

1300 365 262

Telephone:

(03) 6324 9869

Facsimile:

(03) 6324 9885

Email: amcom@amc.edu.au

Australian Search and Rescue (a division of the Australian Maritime Safety Authority)

Email:

www.acma.gov.au

Central Office: Canberra Red Building, Benjamin OfďŹ ces Chan Street Belconnen ACT 2616 PO Box 78 Belconnen ACT 2616 Telephone:

(02) 6219 5555

Facsimile:

(02) 6219 5353

Outside Sydney, Brisbane, Melbourne, Perth and Cairns areas: (A call to this number can be made from outside the listed areas and will be charged at the local rate, except for mobile phones, which are timed.) Telephone:

1300 850 115

GPO Box 2181 Canberra ACT 2601

Bureau of Meteorology

aussarquery@amsa.gov.au

Internet:

Emergency Phone Numbers: 1800 641 792

www.bom.gov.au

Head Office: Melbourne 700 Collins Street Docklands VIC 3000 GPO Box 1289 Melbourne VIC 3001 Telephone:

(03) 9669 4000

Facsimile:

(03) 9669 4699

National Communications Manager Telephone: (03) 9669 4224 National Marine Weather Services Manager Telephone: (03) 9669 4510

AUSTRALIAN MARITIME COLLEGE

105

Appendix 8 Glossary of Terms and Abbreviations AAIC

Accounting Authority Identification Code.

ACMA

Australian Communications and Media Authority, formerly the Australian Communications Authority.

Amplitude modulation.

AMC

Australian Maritime College.

AMSA

Australian Maritime Safety Authority.

AusSAR

The operating authority for RCC Australia.

Radio channel.

Coast Radio Station

A land station in the maritime mobile service providing terrestrial HF communications to and from ships at sea. These stations are operated on behalf of the State/Territory marine authorities. These stations are licensed as Limited Coast Stations. References in the text to ‘Limited Coast Stations’ should be taken to include these stations as well, unless otherwise specified. A satellite-aided search and rescue system designed to locate emergency position indicating radio beacons transmitting on the frequency of 406.025 MHz. General call to all stations. Frequently used in Morse transmissions. May also be used in radiotelephony.

COSPAS-SARSAT System CQ DE

‘from......’ (used to precede the name or identification of the calling station). Frequently used in Morse transmissions. May also be used in radiotelephony.

DSC

Digital Selective Calling. A digitised alerting technique used between stations in the marine service.

Duplex Frequencies

Different but paired frequencies used for simultaneous transmission and reception.

EGC E

enhanced Group Calling.

EPIRB E

emergency Position Indicating Radio Beacon.

Geostationary Satellite

A satellite whose period of revolution is equal to the period of rotation of the Earth and whose circular and direct orbit lies in the plane of the equator; that is, a satellite which remains approximately ﬁxed relative to a position on Earth

GHz

Gigahertz (1 000 000 000 hertz). A measurement unit of radio frequency.

GPS

Global Positioning System. A satellite-based system for calculating positions anywhere on the earth’s surface.

GMDSS

Global Maritime Distress and Safety System.

GPIRB

Global (Position) Indicating Radio Beacon

High Frequency (3 to 30 MHz).

Hertz. A measurement unit of radio frequency.

H3E

Radiotelephony using amplitude modulation, single sideband, full carrier - the compatible mode. Often referred to as ‘AM’. Permitted only on 2182 kHz

Inmarsat

International Maritime Satellite Organisation.

ITU

International Telecommunication Union.

J3E

Radiotelephony using amplitude modulation, single sideband, suppressed carrier. Often referred to as ‘SSB’.

Kilometre/s (0.54 of a nautical mile)

kHz

Kilohertz (1000 hertz). A measurement unit of radio frequency.

knots

Nautical miles per hour.

Kilowatt (1000 watts). A measurement unit of radio power.

LCS

Limited Coast Station.

LES

Land earth Station.

Limited Coast Station

A land station in the maritime mobile service providing terrestrial communications to and from ships at sea. These differ from the Australian Maritime Communication Stations in the services they provide.

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MARINE RADIO OPERATORS HANDBOOK

A ground receiving station which receives data from COSPAS-SARSAT satellites, calculates the position of the EPIRB and forwards the resultant information to search and rescue authorities.

One of the two major Australian land stations in the maritime mobile service providing terrestrial communications to and from ships at sea. Overseas, stations providing the same services as Maritime Communication Stations may be called ‘coast stations’. MASTREP

Modernised Australian Ship Tracking and Reporting System

MID Maritime Identification Digit. A three figure group included as part of a MMSI to indicate the station’s country of location or, in the case of a ship, its country of registration. MMSI Maritime Mobile Service Identity. A unique nine digit group required as electronic identification by stations using digital selective calling techniques. MHz

Megahertz (1 000 000 hertz). A measurement unit of radio frequency.

Medium Frequency (300 to 3000 kHz).

MRCC

Maritime Rescue Co-ordination Centre.

MSI

Maritime safety information - a term used in the GMDSS to describe distress alerts, navigational warnings, meteorological warnings and forecasts, and other important safety information for vessels.

NCS

Network Co-ordination Station.

Nautical mile/s (1.85 km).

RCC Australia

Rescue Co-ordination Centre located in Canberra. Operated by AusSAR.

Receiver or receive frequency.

SAR

Search and Rescue

SART

Survival craft radar transponder. Also known as a Search And Rescue Transponder.

SES

Ship Earth Station.

SIMPLEX

The same frequency used for transmission and reception.

SOLAS Convention

Safety Of Life At Sea Convention as adopted by the International Maritime Organisation and accepted by contracting governments.

SSB

Single sideband.

USB

Upper sideband.

TAFE

Technical And Further education, College of.

Telstra

Telstra Global Satellite and Radio Services.

Transmitter or transmit frequency.

UTC

Co-ordinated Universal Time (replaced Greenwich Mean Time as the world standard in 1986).

VHF

Very High Frequency (30 to 300 MHz).

AUSTRALIAN MARITIME COLLEGE

107

Index Subject-Paragraph

AAIC 144 Acknowledgement of receipt of distress message/alert 90, 130

Deceptive or false distress, urgency or safety signals 12

AIS-SART 112

Digital selective calling, cancellation of inadvertent distress alert 93

AIS-MOB (Man Overboard) 112

Digital selective calling, contents of alert 86

Alarm signal, radiotelephony 119

Digital selective calling, description of technique 80

Alarm signal, navigational warning 120 Alphabet, phonetic App. 5

Digital selective calling, distress alert 88 Digital selective calling, distress alert acknowledgement 89, 90

Amplitude modulation (AM) 35, 73, 118, App. 3

Digital selective calling, distress alert relay 91, 92

Antenna, function, faults and care 72, 75, 77

Digital selective calling, equipment 81

AMVeR system 147

Digital selective calling, frequencies 83, 84

Australian Register of Ships 143

Digital selective calling, identiﬁcation 82

Australian ship reporting system 28, 118

Digital selective calling, man overboard 81

Authority of the master 8, 88, 94, 122, 134

Digital selective calling, safety alert 95

Avoidance of interference 14

Digital selective calling, urgency alert 94

b Battery, maintenance 55 - 63 Battery, connection in parallel and series 54 Battery, hazards 62 Battery, specific gravity 59 Broadcasts by Maritime Communication and coast stations 123, 138

Digital selective calling, call format 87

Digital selective calling, watchkeeping 85 Distress call radiotelephony 125 Distress call and message, authority to transmit 122 Distress call and message, radiotelephony frequencies 123 Distress message radiotelephony 126 Distress message radiotelephony, acknowledgement of receipt 130 Distress message radiotelephony, transmission by vessel not in distress 133 Distress, imposition of silence 131 Distress, procedure when distress traffic ended 132 Distress signal, misuse of 124

Calling frequencies, radiotelephony 24, 25 Calling procedures, radiotelephony 138

Distress traffic, control of 131

Call signs, ship’s 17, 138

Documents to be held on board 15

Call signs, maritime communication and limited coast 39, 48

Duplex transmission 36

Cancellation of inadvertent distress alert 93

Certificates of proficiency 1 – 5, App. 1 Certificates of proficiency, production of 9, 143 Certificates of proficiency, replacement 3 Coast Radio Stations 42 - 44 Coast stations, foreign 145

Distress traffic, delegation of control 131

eligibility for operators’ certificates 3 emergency position indicating radio beacons (ePIRBs) 96 - 111 ePIRBs, detection and location by aircraft 101, 104 ePIRBs, detection and location by satellite 102, 105

Communications, secrecy of 10 Control of radiotelephony distress working 131

ePIRBs, identification of 406 MHz 106

Control of routine working 22 COSPAS-SARSAT satellite system 98

ePIRBs, servicing 109

ePIRBs, inappropriate activation 111 ePIRBs, stowage 110 examination for operators’ certificates 1, 2, 3, 4 examination syllabi App. 1

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MARINE RADIO OPERATORS HANDBOOK

False, distress, urgency or safety signals 12 Faults, antenna 77

Licence, ship station, obligation to obtain 6, 7

Faults, power supply 79

Licence, inspection 6, 9, 143 Limited coast stations, categories 46

Faults, transceiver 78

Limited coast stations, hours of operation 47

Figures, transmission of 27, App. 5 Foreign coast stations, details of 145

Limited coast stations, services provided 45

Limited coast stations, identification 48

Frequencies, radiotelephony calling 24, 25 Frequencies, distress, urgency and safety 83, 123, 134 - 136

Log book, sample page App. 2

Frequencies, guide to use of App. 3

Loss of person overboard 119

Frequencies, licence restrictions to use 6

Loss of operators’ certificates 3

Frequencies, VHF Transmitting Table App. 4 Frequencies, working 26, 83

g Global Maritime Distress and Safety System, Foreword

h Hours of service, maritime communication stations 40 Hours of service, limited coast stations 47

Log keeping, requirements 16

m Maritime Communication Stations, control of working 22 Maritime Communication Stations, identification 39 Maritime Communications Stations, location 38 Maritime Communication Stations, service provided 37 Maritime Communication Stations, watchkeeping 40 Maritime Mobile Service Identities 82 Maritime Identification Digits 82 Master, authority of 8

MASTReP 116

Identification of maritime communication stations 39

MAYDAY ReLAY 133

Identification of maritime communication and coast stations 48

Medical advice 41, 146 Meteorological information and warnings 37, 137

Identification of ship stations 17, 18

MAYDAY 125

Information for coast and limited coast stations 28

MF/HF radio equipment 65, 66 MF/HF radio equipment, expected range 32, 33, 66

Inspection of radio stations 9, 143

Misuse of distress signal 12

Inspection of ship stations 9, 143

Modulation, amplitude 35, 73, 118

Identification, transmission without, forbidden 18

Interference, avoidance of 14 International Telecommunication Union (ITU) Foreword, 1 International Telecommunication Union, publications 145

n Navigational warnings 37, 136, 137 Navigational warning signal 120 Normal and restricted working during distress 131

o Obligation to accept distress calls 121 Operators’ certificates 1 – 5

AUSTRALIAN MARITIME COLLEGE

109

PAN PAN 134

Testing equipment on air 14, 23, 109

Phonetic alphabet 27, App. 5 Port, use of radio transmitting equipment in 29

Time signals 148

Power, minimum to be used 14 Priority of distress calls 121

Transceiver controls 73

Propagation of radio energy 31 - 34

Transmissions, unnecessary or deceptive 12, 13 27 MHz radio equipment 65, 67

q Qualifications, operators 1 â&#x20AC;&#x201C; 5

r Radar transponders 112 Radiation hazard, satellite communications equipment 162, 171 Radio communications, secrecy of 10 Radio energy propagation 31 - 34 Repetition of distress messages 126

Transmissions without identification 18

27 MHz radio equipment, expected range 33, 66, 67

u Unnecessary transmissions 13 Urgency alert, digital selective calling 94 Urgency signal and message 134

v VHF marine repeaters 49, 50, 51

Reply, radiotelephony 139

VHF, expected range of transmissions 34, 68

ReSCUe Co-ordination Centre (RCC) 96, 100, 111, 113

VHF, radio equipment, advantages and disadvantages 68

Safety alert, digital selective calling 95

Watchkeeping hours, maritime communication and coast stations 40, 47

Safety signal and message 135

Watchkeeping, ships, distress and calling frequencies 19, 85

Search and Rescue in Australia 113 - 117

Working frequencies radiotelephony 24, 26, App. 3

Search and Rescue radar transponders 112 Secrecy of communications 10 SECURITE 135 SEELONCE FEENEE 132 SEELONCE MAYDAY 131 Ship stations, identiďŹ cation of 17, 18 Ship stations, inspections of 9, 143 Silence periods, radiotelephony 20 Single sideband mode of transmission 36, 73 Standard marine vocabulary App. 6 State and NT HF and VHF Stations 42 - 44 Survival craft radar transponders 112

110

Traffic lists 137

MARINE RADIO OPERATORS HANDBOOK

NOTES

AUSTRALIAN MARITIME COLLEGE

111

NOTES

112

MARINE RADIO OPERATORS HANDBOOK

AMC SEARCH

Commercial arm of the Australian Maritime College

Course information, including scheduled dates, fees and content is available at: www.amcsearch.com.au

Marine Radio Operators Handbook

Radio Distress Calling

Used Only if in grave or imminent danger • MAYDAY MAYDAY MAYDAY • tHIS IS (Name of vessel and call sign - spoken 3 times) • MAYDAY > Name of vessel & call sign

MARINE RADIO FREQUENCIES for small craft

DISTRESS SAFETY AND CALLING 4125 kHz

6215 kHz 8291 kHz

VHF Channel 16

Monitored by State / Territory services 24 hours 7 days a week

Monitored by State / Territory services in certain areas 24 hours 7 days a week

WEATHER FORECASTS AND WARNINGS VMW Wiluna

2056kHz

4149 kHz

6230 kHz

8113 kHz

12362 kHz

16528 kHz

VMC Charleville

2201 kHz

4426 kHz

6507 kHz

8176 kHz

12365 kHz

16546 kHz

VHF Channel 67

Available in certain areas. Refer to State / Territory marine authorities for details

Broadcast schedule

Available at: www.bom.gov.au/marine

VHF Channel 67 HF 8176 kHz

Marine Radio

Available in certain areas. Refer to State / Territory marine authorities for details Refer to State / Territory marine authorities for schedule details

Operators Handbook

2017

NAVIGATION WARNINGS

Marine Radio

Operators Handbook MRO Handbook 2017