gr-mcp-docs/reference/cospas-sarsat/t-series/t022.md

---
title: "T022: Cospas-Sarsat System Beacon Specification And Design Guidelines C"
description: "Official Cospas-Sarsat T-series document T022"
sidebar:
  badge:
    text: "T"
    variant: "note"
# Extended Cospas-Sarsat metadata
documentId: "T022"
series: "T"
seriesName: "Technical"
documentType: "specification"
isLatest: true
documentDate: "October 2023"
originalTitle: "Cospas-Sarsat System Beacon Specification"
---

> **📋 Document Information**
>
> **Series:** T-Series (Technical)
> **Date:** October 2023
> **Source:** [Cospas-Sarsat Official Documents](https://www.cospas-sarsat.int/en/documents-pro/system-documents)

---

# T022 - T022-OCT-27-2023.pdf

**Pages:** 21

---


 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
COSPAS-SARSAT SYSTEM BEACON SPECIFICATION 
AND DESIGN GUIDELINES 
 
C/S T.022 
Issue 2, Revision 1 


COSPAS-SARSAT SYSTEM BEACON 
SPECIFICATION AND DESIGN GUIDELINES 
 
 
HISTORY 
 
Issue 
Revision 
Date 
Comments 


Approved by the Cospas-Sarsat Council (CSC-59) 


Approved by the Cospas-Sarsat Council (CSC-62) 


Approved by the Cospas-Sarsat Council (CSC-64) 


Approved by the Cospas-Sarsat Council (CSC-66) 


Approved by the Cospas-Sarsat Council (CSC-69) 


TABLE OF CONTENTS 
 
1. 
INTRODUCTION .............................................................................................................. 1-1 
1.1 
Overview .................................................................................................................... 1-1 
1.2 
Scope 
1-1 
1.3 
Reference Documents................................................................................................. 1-1 
2. 
PERFORMANCE SPECIFICATION AND DESIGN GUIDELINES FOR 
REFERENCE BEACONS ................................................................................................. 2-1 
2.1 
Purpose 2-1 
2.2 
Requirements Common to all Reference Beacons ..................................................... 2-1 
2.3 
Requirements for Designated QMS Reference Beacons ............................................ 2-2 
2.3.1 
Designated LEOSAR QMS Reference Beacons............................................ 2-2 
2.3.2 
Designated GEOSAR QMS Reference Beacons ........................................... 2-2 
2.3.3 
Designated MEOSAR QMS Reference Beacons .......................................... 2-2 
2.4 
Guidelines for Defining Reference Beacons Requirements ....................................... 2-3 
2.4.1 
Guidelines for Supplying a MEOSAR Reference Beacon ............................ 2-3 
2.4.2 
Other Guidelines for MEOSAR Reference Beacons ..................................... 2-4 
2.5 
List of Reference Beacons in the System ................................................................... 2-6 
3. 
GUIDELINES FOR DEFINING CALIBRATION BEACON REQUIREMENTS ..... 3-1 
3.1 
Guidelines for Supplying a MEOSAR Calibration Beacon ....................................... 3-1 
3.2 
Other Guidelines for MEOSAR Calibration Beacons ................................................ 3-1 
4. 
GUIDELINES FOR BEACON SIMULATOR REQUIREMENTS AND 
SPECIFICATIONS ............................................................................................................ 4-1 
4.1 
Guidelines for Supplying a Beacon Simulator ........................................................... 4-1 
4.2 
Guidelines Unique to a Beacon Simulator ................................................................. 4-1 
 
 
LIST OF ANNEXES 
 
ANNEX A COMMITMENT OF THE MEOSAR REFERENCE BEACON OR 
CALIBRATION BEACON PROVIDER 
 
 


 
1-1 

1. 
INTRODUCTION 
1.1 
Overview 
The purpose of the Cospas-Sarsat System is to provide distress alert and location data for search and 
rescue (SAR), by using spacecraft and ground facilities to detect and locate distress signals and transmit 
the computed position and other related information to appropriate SAR authorities. 
 
This document contains both guidelines for administrations to implement various types of System 
beacons, as well as specifications that explicitly define requirements that must be met (shall), or are 
recommended to be achieved (should). 
1.2 
Scope 
This document describes the performance specification and design guidelines of the different types of 
beacons that are used for System purpose: 
• 
reference beacons including designated QMS reference beacons, 
• 
calibration beacons, 
• 
beacon simulators. 
 
The specifications for orbitography beacons used by the LEOSAR system are provided in document 
C/S T.006. 
1.3 
Reference Documents 
Reference 
Title 
C/S A.002 
Cospas-Sarsat Mission Control Centres Standard Interface Description (SID) 
C/S A.003 
Cospas-Sarsat System Monitoring and Reporting 
C/S G.003 
Introduction to the Cospas-Sarsat System 
C/S T.001 
Specification for Cospas-Sarsat 406 MHz Distress Beacons 
C/S T.003 
Description of the 406-MHz Payloads Used in the Cospas-Sarsat LEOSAR System 
C/S T.006 
Cospas-Sarsat Orbitography Network Specification 
C/S T.016 
Description of the 406 MHz Payloads Used in the Cospas-Sarsat MEOSAR System 
C/S T.018 
Specification for Second-Generation Cospas-Sarsat 406-MHz Distress Beacons 
C/S T.019 
Cospas-Sarsat MEOLUT Performance Specification and Design Guidelines 
 
 
- END OF SECTION 1 - 


 
2-1 

2. 
PERFORMANCE 
SPECIFICATION 
AND 
DESIGN 
GUIDELINES 
FOR 
REFERENCE BEACONS 
2.1 
Purpose 
The Cospas-Sarsat MEOSAR system is designed to provide global coverage. All MEOLUTs have the 
capability to detect and locate 406-MHz distress beacons within, at a minimum, their Declared 
Coverage Area. The location accuracy achieved is dependent on various parameters, including the 
accuracy of TOA and FOA measurements.  
 
MEOSAR reference beacons are deployed with characteristics particularly suited to benefit MEOLUTs 
with a view towards being used for the monitoring of MEOSAR performance and the QMS of the 
MEOSAR system. The monitoring may include the continuous oversight of one or more of the 
following MEOLUT parameters: 
• 
system detection rate, 
• 
system localisation performance (probability and accuracy), 
• 
MEOLUT throughput and single satellite-MEOLUT channel throughput, 
• 
TOA and FOA estimation accuracy of a MEOLUT. 
 
These beacons also provide a resource to complete the Quality Management System (QMS) objectives 
stated in section 7 of document C/S P.015 “Cospas-Sarsat Quality Manual”. 
2.2 
Requirements Common to all Reference Beacons 
The MEOSAR reference beacon network has been developed with the view that each MEOSAR satellite 
has at least one MEOSAR reference beacon in its field of view, thus allowing the monitoring of the 
performance of each MEOLUT channel (satellite/MEOLUT-antenna pair), to contribute to the overall 
MEOSAR QMS. 
 
To limit adverse impact on the System, including the avoidance of unnecessary channel congestion, 
Participants should coordinate at a regional level the location and installation timeline of their 
MEOSAR reference beacon(s), and shall coordinate at a Programme level through the Secretariat its 
transmission characteristics , with a view towards limiting the number of beacon bursts to the minimum 
required to ensure defined MEOSAR performance. 
 
Reference beacon providers shall provide technical characteristics of their beacons to the Secretariat, 
to allow this information to be published and made available on the Cospas-Sarsat website, including 
frequency and time characteristics, hex ID, transmission timing and schedule and, for SGBs, output 
filter types (i.e., transmission waveforms). 


 
2-2 

2.3 
Requirements for Designated QMS Reference Beacons 
This section provides technical requirements for reference beacons to be used for the purpose of the 
QMS defined in document C/S A.003. 
2.3.1 
Designated LEOSAR QMS Reference Beacons 
Text to be developed, noting the definition provided in document C/S A.003. 
2.3.2 
Designated GEOSAR QMS Reference Beacons 
Text to be developed, noting the definition provided in document C/S A.003. 
2.3.3 
Designated MEOSAR QMS Reference Beacons 
Each designated reference beacon used for QMS shall: 
• 
be listed on the Cospas-Sarsat website for QMS, along with its geographic location, 
transmission frequency, transmission schedule and, for SGBs, output filter types (i.e., 
transmission waveforms); and 
• 
be committed for use to ensure that it can reliably be used to produce relevant QMS metrics; 
however, a designated QMS reference beacon may be used for complementary purposes. 
2.3.3.1 C/S T.001 Transmissions 
Designated C/S T.001 QMS reference beacons shall transmit a burst every 50 seconds (± 0.1 seconds) 
for a total of 12 successive bursts (i.e., for 10 minutes of beacon activation), followed by a transmission 
gap of at least 10 minutes, to ensure that the MEOLUT resets the beacon activation status, per 
document C/S T.019 section entitled “Independent Location Processing”. 30 minutes is the preferred 
duration for transmission repetition periods (TRP) (i.e., 10-minute slots of transmission followed by a 
20-minute gap in transmission), as depicted in Figure 2.1. The TRP shall be set to provide an integer 
number of transmissions per day (e.g., a 30-minute repetition period results in 48 transmission periods 
per day, a 20-minute repetition period results in 72 transmission periods per day). 
 
 
 
 
 
 
 
 
Figure 2.1: Definition of the Transmission Repetition Periods 
 
Designated QMS reference beacons shall use linear polarization, to be suitable for both L-band and 
S-band satellites. The reference beacon shall transmit nominally, but with a transmit power of 
35.0 ±0.5 dBm (measured at the antenna input). 
 
Time 
30-minute transmission repetition period 
10-minute transmission slot 
(12 bursts) 
… 


 
2-3 

Designated QMS reference beacons shall transmit in self-test mode, to minimize impact on the 
LEOSAR Sarsat SARP. The associated beacon message shall be coded so that no more than 18 bits 
within any sequence of 24 fixed bits match the 24 bit frame pattern for an operational beacon (i.e., 
1111 1111 1111 1110 0010 1111), to minimize impact on the LEOSAR Sarsat SARP-3. Also to reduce 
unintended impact on Sarsat SARP-3 processors, the beacon message should not contain anywhere in 
bits 1 to 61 more than seven bits in the pattern of the word used for message synchronization by the 
Sarsat SARP-3 (i.e., 111000101)1. 
2.3.3.2 C/S T.018 Transmissions 
Designated C/S T.018 QMS reference beacons shall transmit a burst every 5 seconds for the first 
30 seconds (6 bursts) and one burst every 30 seconds up to 5 minutes of transmission (9 bursts, for a 
total of 15 bursts in 5 minutes), followed by a transmission gap of at least 10 minutes, to ensure that 
the MEOLUT resets the beacon activation status, per document C/S T.019 section entitled 
“Independent Location Processing”. 30 minutes is the preferred duration for transmission repetition 
periods (TRP) (i.e., 5 minutes slots of transmission followed by a 25-minute gap in transmission), as 
depicted in Figure 2.2. 
 
Figure 2.2: Definition of the Transmission Repetition Periods SGB QMS 
Designated QMS reference beacons shall use linear polarization, to be suitable for both L-band and 
S-band satellites. The SGB QMS messages shall be transmitted in self-test mode with a transmitted 
power of 35 ±0.5 dBm (measured at the antenna input)2. 
2.4 
Guidelines for Defining Reference Beacons Requirements 
2.4.1 
Guidelines for Supplying a MEOSAR Reference Beacon 
Supplying a MEOSAR Reference Beacon 
A MEOSAR reference beacon is supplied by a country accepting the commitment stated in 
Annex A and noting the operational requirements in document C/S A.003. 
 
1 Nonetheless, if no beacon message can be defined to avoid matching 8 or 9 bits of the Sarsat SARP-3 synchronisation 
word (e.g., no country code is available that does not match the synchronization word pattern), the reference beacon 
might transmit in normal mode on an exceptional basis, with due notice of this exception to the System. 
2 The transmit power of the QMS reference beacon shall be configurable in the range 30 to 37 dBm with 1 dB steps. 
Time 
… 
5-minute transmission slot (6+9 bursts) 
30 minutes transmission repetition period 
6 bursts, 5 seconds 
between each burst 
9 bursts, 30 seconds 
between each burst 


 
2-4 

Availability 
Once a MEOSAR reference beacon has been installed, its availability should be greater 
than 95%. 
 
Antenna Blockage 
The MEOSAR reference beacon antenna should provide the widest possible horizon. 
 
Location Data 
The beacon antenna location (longitude, latitude, altitude) should be provided with a three 
dimensional accuracy better than 1 m.  This location should be given with respect to the 
Bureau International de l'Heure (BIH) Conventional Terrestrial System, having a reference 
ellipsoid defined as follows [or expressed in WGS84]: 
Semi-major axis 
 
= 
6,378,137 m 
Flattening (ellipticity) 
= 
1/298.2572 
The location of all MEOSAR reference beacons is given on the Cospas-Sarsat website 
www.cospas-sarsat.int. 
2.4.2 
Other Guidelines for MEOSAR Reference Beacons 
MEOSAR reference beacons should conform to the signal specifications defined in document 
C/S T.001 (FGB) or C/S T.018 (SGB), except for the following. 
 
Repetition period 
• 
FGB bursts, with a repetition period of 50 seconds, transmitting per 10-minute slots, 
• 
SGB bursts, with a repetition period of 30 seconds, transmitting per 5-minute slots. 
 
Beacon activation should be co-ordinated with other providers of MEOSAR reference 
beacons to prevent repeated transmission collisions. 
It should be possible to interrupt the beacon activation for some periods of time to meet the 
need for coordination of transmissions with other reference beacons or calibration beacons. 
 
Transmitted Frequency 
 
Initial frequency: 
 
 
For FGB: 
 
 
The transmitted frequency can be 406.034 MHz  [10 Hz] or one of the frequency 
channels designated as “Reserved, not to be assigned” in Table H.2 of document 
C/S T.012 up to channel K (406.052 MHz) (note that channels L (406.055 MHz) 
and above should not be used). 
 
 
 
The transmitted frequency might be configurable to any frequency channel 
identified in Table H.2 of document C/S T.012 (i.e., including operational and 
“Reserved, not to be assigned” channels), in order to accommodate future 
evolution. 
 
 
 
 
 
 


 
2-5 

For SGB: 
 
 
The transmitted frequency should be 406.049 MHz  [10 Hz] or 406.051 MHz 
 [10 Hz]. 
 
 
The exact transmitted frequency should be provided to the Secretariat by the reference 
beacon operator for publication. 
 
Output power (except for designated QMS beacons which shall comply with specifications in 
section 2.3) 
37 dBm  1dB 
 
The transmitted power should be configurable from 25 dBm to 37 dBm with 1 dB steps (note: 
this requirement is needed for possible mitigation of interference in the future, as deemed 
necessary). 
 
Antenna Characteristics (except for QMS beacons which shall comply with specifications in 
section 2.3) 
The beacon antenna should be located to provide visibility to the lowest possible elevation 
angles at all azimuths (i.e., least obstructed horizon). 
 
The antenna polarization should be either right-hand circular polarization (RHCP), left-hand 
circular polarization (LHCP) or linear polarisation (note: RHCP polarization is most 
suitable for L-band MEOSAR satellites, LHCP polarization for DASS S-band satellites, and 
linear polarization for both S-band and L-band satellites, although with attendant 
polarization losses). For LHCP and RHCP antennas, the radiation pattern should be omni-
directional in azimuth and elevation. If selected, linear-polarized antennas should offer the 
widest coverage (radiation pattern) possible, in particular for high elevation angles. 
 
Wideband Interference 
If collocated with a MEOLUT, a MEOSAR reference beacon should not produce a power 
flux spectral density above -211 dB (W/m2Hz) in the 1544.0 MHz – 1545.0 MHz frequency 
band. 
 
Narrowband Interference 
If collocated with a MEOLUT, a MEOSAR reference beacon should not produce a power 
flux density above -168 dBW/m2 within 1 Hz of the 1544.0 MHz – 1545.0 MHz frequency 
band. 
 
Environmental and Operational Requirements 
The MEOSAR reference beacon is designed to be operated within a controlled environment 
consistent with the ranges below and, therefore, is not subject to the stricter thermal or other 
operational requirements specified in document C/S T.001 or C/S T.018 for distress 
beacons. 
 
Temperature requirements 
 
Operating temperature range: 
+15 o C to +40o C 
 
Storage temperature range:  
-20o C to +60o C 


 
2-6 

Built in GNSS Receiver 
A MEOSAR reference beacon may incorporate a GNSS receiver to receive return link 
messages (RLM). 
 
SGB Message Definition 
Using the SGB message definition from document C/S T.018, the following message 
parameters should be used: 
Bits  
Usage  
1 - 16  
specific TAC number indicating a System beacon as follows: 
• 
65,535 for calibration beacons, 
• 
65,534 for QMS beacons, 
• 
65,533 for reference beacons (other than QMS beacons), 
• 
65,532 for beacon simulators. 
If a system beacon has multiple uses, it should be coded with the highest 
applicable TAC number. 
17 - 30  
pre-assign serial number 
31 - 40  
country code 

status of homing device: shall be set to "0" (no homing device or homing device 
disabled) 

RLS function: shall be set to “0” if RLS is not enabled and set to "1" if RLS is 
enabled (e.g., RLS system testing) 

test protocol: shall be set to “1” (test protocol) 
44 - 90  
encoded GNSS location 
91 - 93  
vessel ID protocol identifier: shall be set to "111" (reserved for System testing) 
94 - 137  vessel ID: all bits defaulted to “0” or user defined (fixed) 
138 - 140 beacon type: “111” for System beacons 
141 - 154 spare bits: all bits set to “1” 
And use Rotating Field #0 with all fields with valid values 
 
Lifetime 
MEOSAR reference beacons should be designed for a lifetime of at least 20 years. 
 
2.5 
List of Reference Beacons in the System 
The complete list of beacons, including the identification, location of each, technical characteristics and 
status is provided on the Cospas-Sarsat website.  
 
 
 
- END OF SECTION 2 - 
 
 


 
3-1 

3. 
GUIDELINES FOR DEFINING CALIBRATION BEACON REQUIREMENTS 
3.1 
Guidelines for Supplying a MEOSAR Calibration Beacon 
Supplying a MEOSAR Calibration Beacon 
A MEOSAR calibration beacon is supplied by a country accepting the commitment stated 
in Annex A. 
No more than one MEOSAR calibration beacon should be installed per MEOLUT. 
 
Availability 
Once a MEOSAR calibration beacon has been installed, its availability should be greater 
than 95%. 
 
Antenna Blockage 
The MEOSAR calibration beacon antenna should provide the widest possible horizon. 
 
Location Data 
The beacon antenna location (longitude, latitude, altitude) should be provided with a three 
dimensional accuracy better than 1 m.  This location should be given with respect to the 
Bureau International de l'Heure (BIH) Conventional Terrestrial System, having a reference 
ellipsoid defined as follows [or expressed in WGS84]: 
Semi-major axis 
 
= 
6,378,137 m 
Flattening (ellipticity) 
= 
1/298.2572 
The location of all MEOSAR calibration beacons is given on the Cospas-Sarsat website. 
3.2 
Other Guidelines for MEOSAR Calibration Beacons 
MEOSAR calibration beacons should conform to the signal specifications defined in document 
C/S T.001 (FGB) or C/S T.018 (SGB), except for the following. 
 
Repetition period 
• 
FGB bursts, with a period between burst transmissions of 150 seconds continuously 
transmitting, 
• 
SGB bursts, with a period between burst transmissions of 150 seconds continuously 
transmitting, 
 
Beacon activation should be co-ordinated with other providers of MEOSAR reference and 
calibration beacons to prevent repeated transmission collisions. 
It should be possible to interrupt the beacon activation for some periods of time to meet the 
need for coordination of transmissions with other calibration beacons or reference beacons. 
 
 
 


 
3-2 

Transmitted Frequency 
 
Initial frequency: 
 
 
For FGB: 
 
 
The transmitted frequency can be 406.034 MHz  [10 Hz] or one of the frequency 
channels designated as “Reserved, not to be assigned” in Table H.2 of document 
C/S T.012 up to channel K (406.052 MHz) (note that channels L (406.055 MHz) 
and above should not be used). 
 
 
 
The transmitted frequency might be configurable to any frequency channel 
identified in Table H.2 of document C/S T.012 (i.e., including operational and 
“Reserved, not to be assigned” channels), in order to accommodate future 
evolution. 
 
 
 
 
For SGB: 
 
 
The transmitted frequency should be 406.049 MHz  [10 Hz] or 406.051 MHz 
 [10 Hz]. 
 
 
 
The exact transmitted frequency should be provided to the Secretariat by the reference 
beacon operator for publication. 
 
 
Short term frequency stability: 
 
 
The transmitted frequency should not vary more than 1 part in 1010 in 100 ms. 
 
 
Frequency accuracy3: 
 
 
For FGB, the frequency of transmission of each burst should be between [-0.014] Hz 
and [+0.014] Hz from the declared transmission frequency. 
 
 
For SGB, the frequency of transmission of each burst should be between [-0.014] Hz 
and [+0.014] Hz from the declared transmission frequency. 
 
Modulation symmetry 
For FGB, the modulation symmetry, as defined in document C/S T.001, should be less 
than 0.02. 
 
Rise and fall times of the modulated waveform 
For FGB, the modulation rise and fall times should be in the range 50-150 μs and maintained 
within ± 1 μs of the selected value. 
 
The modulation rise and fall times should be provided by the calibration beacon operator. 
 
Digital Message 
For FGB, the final 360 ms ± 1 percent of the transmitted signal should contain a 144-bit 
message at a bit rate of 400 bps ± 0.1%. 
 
3 The frequency accuracy values were derived from section 5.8.1 in document C/S T.019. Considering that a MEOLUT 
may use two calibration beacons to calibrate its FOA measurements, and that the FOA measurement bias is required 
to be below 0.02 Hz, a maximum value of 0.02/√2 = 0.014 Hz is proposed. 


 
3-3 

Timing accuracy of transmitted beacon bursts4 
For FGB, the time of transmission of each burst should be between- [-1.77] μs and 
[+1.77] μs from the declared transmission time. 
 
For SGB, the time of transmission of each burst should be between [-0.14] μs and [+0.14] μs 
from the declared transmission time. 
 
The definition of the time reference point (anchor) of the transmitted bursts is identical to 
the uplink TOA time reference, as defined for MF#67 in document C/S A.002. 
The time reference point should be provided by the calibration beacon operator. 
 
A round second is preferred for the time reference point of calibration beacons. 
 
Output power 
37 dBm  1dB 
 
The transmitted power should be configurable from 25 dBm to 37 dBm with 1 dB steps (note: 
this requirement is needed for possible mitigation of interference in the future, as deemed 
necessary). 
 
Antenna Characteristics 
The beacon antenna should be located to provide visibility to the lowest possible elevation 
angles at all azimuths (i.e., least obstructed horizon). 
 
The antenna polarization should be either right-hand circular polarization (RHCP), left-hand 
circular polarization (LHCP) or linear polarisation (note: RHCP polarization is most 
suitable for L-band MEOSAR satellites, LHCP polarization for DASS S-band satellites, and 
linear polarization for both S-band and L-band satellites, although with attendant 
polarization losses). For LHCP and RHCP antennas, the radiation pattern should be omni-
directional in azimuth and elevation. If selected, linear-polarized antennas should offer the 
widest coverage (radiation pattern) possible, in particular for high elevation angles. 
 
Wideband Interference 
If collocated with a MEOLUT, a MEOSAR calibration beacon should not produce a power 
flux spectral density above -211 dB (W/m2Hz) in the 1544.0 MHz – 1545.0 MHz frequency 
band. 
 
 
 
 
4 The time accuracy values were derived from section 5.8.1 in document C/S T.019. Considering that a MEOLUT 
may use two calibration beacons to calibrate its TOA measurements, and that the TOA measurement bias is required 
to be below 2.5 µs for C/S T.001 beacons and [0.2] µs for C/S T.018 beacons, 2.5/√2 = 1.77 µs is proposed for 
C/S T.001 beacons measurements and a maximum value of 0.2/√2 = 0.14 µs is proposed for C/S T.018 beacons 
measurements. 


 
3-4 

Narrowband Interference 
If collocated with a MEOLUT, a MEOSAR calibration beacon should not produce a power 
flux density above -168 dBW/m2 within 1 Hz of the 1544.0 MHz – 1545.0 MHz frequency 
band. 
 
Environmental and Operational Requirements 
The MEOSAR calibration beacon is designed to be operated within a controlled 
environment consistent with the ranges below and, therefore, is not subject to the stricter 
thermal or other operational requirements specified in document C/S T.001 or C/S T.018 
for distress beacons. 
 
Temperature requirements 
 
Operating temperature range: 
+15 o C to +40o C 
 
Storage temperature range:  
-20o C to +60o C 
 
Built in GNSS Receiver 
A MEOSAR calibration beacon may incorporate a GNSS receiver to receive return link 
messages (RLM) and for UTC time and frequency synchronization of calibration bursts. 
 
Calibration Protocol (for FGB calibration bursts) 
The orbitography user protocol should be used.  This protocol, defined in document 
C/S T.001, is as follows: 
Bits 
Usage 
1-15 
bit synchronization 
16-24 
frame synchronization 

format flag ("0" for short message and "1" for long message) 

protocol flag (set bit to "1") 
27-36 
country code (MID) 
37-39 
orbitography protocol ("000") 
40-81 
seven character orbitography beacon clear text identifier using the modified 
Baudot code (see document C/S T.001). The seven characters shall be right 
justified.  Characters not used shall be filled with the "space" character (100100). 
82-85 
four binary zeros ("0000") 

national use (set bit to "0") 
108-112 national use 
113-144 optional long message. National use. 
The 15 hexadecimal character identification used by the MCCs describes bits 26 through 85 
(i.e., 60 bits). 
[A protected PDF2 field might be used.] 
 
If the calibration beacon transmits in self-test mode, to reduce unintended impact on LEOSAR Sarsat 
SARP-3 processors, the beacon message should not contain anywhere in bits 1 to 61 more than seven 
bits in the pattern of the word used for message synchronization by the Sarsat SARP-3 (i.e., 
111000101). 
 
 
 


 
3-5 

SGB Message Definition 
Using the SGB message definition from document C/S T.018, the following message 
parameters should be used: 
Bits  
Usage  
1 - 16  
specific TAC number indicating a System beacon as follows: 
• 
65,535 for calibration beacons, 
• 
65,534 for QMS beacons, 
• 
65,533 for reference beacons (other than QMS beacons), 
• 
65,532 for beacon simulators. 
If a system beacon has multiple uses, it should be coded with the highest 
applicable TAC number. 
17 - 30  
pre-assign serial number 
31 - 40  
country code 

status of homing device: shall be set to "0" (no homing device or homing device 
disabled) 

RLS function: shall be set to “0” if RLS is not enabled and set to "1" if RLS is 
enabled (e.g., RLS system testing) 

test protocol: shall be set to “1” (test protocol) 
44 - 90  
encoded GNSS location 
91 - 93  
vessel ID protocol identifier: shall be set to "111" (reserved for System testing) 
94 - 137  vessel ID: all bits defaulted to “0” or user defined (fixed) 
138 - 140 beacon type: “111” for System beacons 
141 - 154 spare bits: all bits set to “1” 
And use Rotating Field #0 with all fields with valid values 
 
Lifetime 
MEOSAR calibration beacons should be designed for a lifetime of at least 20 years. 
 
 
 
- END OF SECTION 3 - 


 
4-1 

4. 
GUIDELINES 
FOR 
BEACON 
SIMULATOR 
REQUIREMENTS 
AND 
SPECIFICATIONS 
4.1 
Guidelines for Supplying a Beacon Simulator  
Antenna Blockage  
The beacon simulator antenna should provide the widest possible horizon.  
 
Location Data  
The beacon antenna location (longitude, latitude, altitude) should be provided with a three-
dimensional accuracy better than 1 m. This location should be given with respect to the 
Bureau International de l'Heure (BIH) Conventional Terrestrial System, having a reference 
ellipsoid defined as follows [or expressed in WGS84]:  
Semi-major axis = 6,378,137 m  
Flattening (ellipticity) = 1/298.2572 
4.2 
Guidelines Unique to a Beacon Simulator  
Guidelines for Functional Specifications 
A beacon simulator should:  
a) 
Be able to simulate the burst transmissions of both C/S T.001 and C/S T.018 beacons 
in accordance with those specifications; 
b) 
Be able to execute all test scripts for both C/S T.001 and C/S T.018 beacons as defined 
in documents C/S T.005, C/S T.010 and C/S T.020;  
c) 
Be able to transmit C/S T.001 and C/S T.018 beacon bursts over the average burst 
power range 25 dBm to 39 dBm in 1 dB steps by pre-configuration; 
d) 
Be able to transmit bursts at fixed invariant power and variable power levels per burst 
following a pre-configured profile over time; 
e) 
Have transmission antenna patterns with associated EIRP values consistent with 
C/S T.001 and C/S T.018 beacons for the particular beacon types being simulated; 
f) 
Be able to implement burst schedules including time randomization as defined in 
document C/S T.001 and C/S T.018, and also transmit bursts at time-invariant rates 
as defined by the pre-configuration; 
g) 
Be able to simultaneously transmit at least [10] beacon bursts of any combination of 
C/S T.001 and C/S T.018 beacon types, with both partial and complete bursts 
overlapping in time; 
h) 
Be able to synchronize burst transmission schedules with UTC time (see timing 
accuracy specification below); 


 
4-2 

i) 
Be able to simulate up to 200 C/S T.001 and up to 200 C/S T.018 simultaneous active 
beacons; 
j) 
Be able to vary message content (e.g., GNSS encoded position) from burst to burst for 
any given simulated beacon event; 
k) 
Be configurable in all beacon transmission parameters (e.g., by script or operator 
interface) within allowed ranges in documents C/S T.001 and C/S T.018 (e.g., 
modulation index, rise time, bit rate, chip rate, chip rate variation, etc.); 
l) 
Be able to record, store and export to a file in a standard format (e.g., csv, xml) all 
beacon transmission parameters for each burst transmission, including transmission 
time stamps; and  
m) Be able to generate various pulse shapes (i.e., waveform) for C/S T.018 beacons (e.g., 
half-sine, cosine, rectangular). 
These functional requirements are useful for both MEOLUT commissioning tests and 
system-level tests (e.g., Demonstration and Evaluation (D&E)). Items (a), (b) and (c) are 
particularly useful for commissioning tests. Item (g) through (i) are particularly useful for 
system capacity testing. Item (j) could be useful for evaluating message processing of 
moving beacons.  
 
Transmitted Frequency 
Initial frequency:  
For FGB: 
The transmitted frequency can be from 406.0 MHz to 406.1 MHz. 
Note that when conducting MEOLUT commissioning, FGB signals should 
only transmitted in non-operational frequency channels in the upper part 
of the 406 MHz band (from channel L (406.055 MHz) and above. 
For SGB:  
The transmitted frequency should be from 406.048 MHz to 406.052 MHz. 
 
Short term frequency stability: 
For simulated bursts, the transmitted frequency should not vary more than 1 part in 
1010 in 100 ms. 
 
Frequency accuracy5 
For FGB simulator, the frequency of transmission of each burst should be between 
[-0.014] Hz and [+0.014] Hz from the declared transmission frequency. 
 
For SGB simulator, the frequency of transmission of each burst should be between 
[-0.014] Hz and [+0.014] Hz from the declared transmission frequency. 
 
5 The frequency accuracy values were derived from section 5.8.1 in document C/S T.019. Considering that a MEOLUT 
may use two calibration beacons to calibrate its FOA measurements, and that the FOA measurement bias is required 
to be below 0.02 Hz, a maximum value of 0.02/√2 = 0.014 Hz is proposed 


 
4-3 

Timing Accuracy of Transmitted Beacon Bursts6 
For FGB simulator, the time of transmission of each burst should be [-1.77] μs and 
[+1.77] μs from the declared transmission time. 
 
For SGB simulator, the time of transmission of each burst should be [-0.14] μs and 
[+0.14] μs from the declared transmission time. 
 
The definition of the time reference point (anchor) of the transmitted bursts is identical to 
the uplink TOA time reference, as defined for MF#67 in document C/S A.002. 
 
Wideband Interference  
If collocated with a MEOLUT, a beacon simulator should not produce a power flux spectral 
density above -211 dB (W/m2/Hz) in the 1544.0 MHz – 1545.0 MHz frequency band. 
 
Narrowband Interference  
If collocated with a MEOLUT, a beacon simulator should not produce a power flux density 
above -168 dBW/m2 within 1 Hz of the 1544.0 MHz – 1545.0 MHz frequency band. 
 
Environmental and Operational Requirements 
The beacon simulator should be designed to be operated within a controlled environment 
and, therefore, is not subject to the stricter thermal or other operational requirements 
specified in documents C/S T.001 and C/S T.018 for distress beacons.  
 
Built in GNSS Receiver  
A beacon simulator should incorporate a GNSS receiver to receive return link messages 
(RLM) and for UTC time and frequency synchronization of bursts. This GNSS receiver 
should be compatible with RLS providers. 
 
SGB Message Definition 
Using the SGB message definition from document C/S T.018, the following message 
parameters should be used: 
Bits  
Usage  
1 - 16  
specific TAC number indicating a System beacon as follows: 
• 
65,535 for calibration beacons, 
• 
65,534 for QMS beacons, 
• 
65,533 for reference beacons (other than QMS beacons), 
• 
65,532 for beacon simulators. 
If a system beacon has multiple uses, it should be coded with the highest 
applicable TAC number. 
17 - 30  
pre-assign serial number 
 
6 The time accuracy values were derived from section 5.8.1 in document C/S T.019. Considering that a MEOLUT 
may use two calibration beacons to calibrate its TOA measurements, and that the TOA measurement bias is required 
to be below 2.5 µs for C/S T.001 beacons and [0.2] µs for C/S T.018 beacons, 2.5/√2 = 1.77 µs is proposed for 
C/S T.001 beacons measurements and a maximum value of 0.2/√2 = 0.14 µs is proposed for C/S T.018 beacons 
measurements. 


 
4-4 

31 - 40  
country code 

status of homing device: shall be set to "0" (no homing device or homing device 
disabled) 

RLS function: shall be set to “0” if RLS is not enabled and set to "1" if RLS is 
enabled (e.g., RLS system testing) 

test protocol: shall be set to “1” (test protocol) 
44 - 90  
encoded GNSS location 
91 - 93  
vessel ID protocol identifier: shall be set to "111" (reserved for System testing) 
94 - 137  vessel ID: all bits defaulted to “0” or user defined (fixed) 
138 - 140 beacon type: “111” for System beacons 
141 - 154 spare bits: all bits set to “1” 
And use Rotating Field #0 with all fields with valid values 
 
 
 
- END OF SECTION 4 - 
 
 


 
A-1 

ANNEX A  
COMMITMENT OF THE MEOSAR REFERENCE BEACON OR CALIBRATION 
BEACON PROVIDER 
The installation and operation of a MEOSAR reference beacon or calibration beacon is based upon a 
mutual agreement between Cospas-Sarsat and the country providing such a beacon, whereby the 
Cospas-Sarsat Council accepts the proposed provision of the MEOSAR reference beacon and the 
providing country agrees to abide with the following principles: 
• 
the host country will assume all costs of providing, operating and maintaining the beacon in 
service, 
• 
in taking the decision where to place an orbitography, MEOSAR reference beacon or 
calibration beacon, both Cospas Sarsat system requirements and the supplying country's 
requirements should be taken into account, 
• 
the supplying country will inform Cospas-Sarsat of the precise location of the MEOSAR 
reference or calibration beacon, 
• 
information on the MEOSAR reference beacon or calibration beacon must be provided by the 
beacon operator as described in document C/S T.022, 
• 
the MEOSAR reference beacon should meet the Cospas-Sarsat specifications defined in 
document C/S T.022, 
• 
Cospas-Sarsat may request and/or the country supplying the beacon may decide to terminate 
the operation of the MEOSAR reference beacon or calibration beacon, 
• 
a decision to terminate operation will be subject to coordination among Cospas-Sarsat 
Participants and will not take effect until 12 months after the request/decision has been made 
by one of the parties involved, 
• 
in case of a failure of a beacon that would be cost-prohibitive to remedy, the supplying country 
will not be obliged to supply a new beacon, 
• 
the host country will only code reference beacons using an associated country code, as assigned 
by the ITU, unless coordinated with another country to transmit a country code assigned to that 
other country. 
 
 
 
- END OF ANNEX A - 
 
 
 
- END OF DOCUMENT - 


 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
  
 
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Telephone: +1 514 500 7999  /  Fax: +1 514 500 7996 
Email: mail@cospas-sarsat.int  
Website: www.cospas-sarsat.int