TRACKING DATA 
MESSAGE 
RECOMMENDED STANDARD 
CCSDS 503.0-B-1 


BLUE BOOK 
November 2007 


CCSDS RECOMMENDED STANDARD FOR TRACKING DATA MESSAGE 


AUTHORITY 


Issue: Recommended Standard, Issue 1 
Date: November 2007 
Location: Washington, DC, USA 

This document has been approved for publication by the Management Council of 
the Consultative Committee for Space Data Systems (CCSDS) and represents the 
consensus technical agreement of the participating CCSDS Member Agencies. The 
procedure for review and authorization of CCSDS Recommendations is detailed 
in the Procedures Manual for the Consultative Committee for Space Data 
Systems, and the record of Agency participation in the authorization of this 
document can be obtained from the CCSDS Secretariat at the address below. 

This document is published and maintained by: 

CCSDS Secretariat 
Space Communications and Navigation Office, 7L70 
Space Operations Mission Directorate 
NASA Headquarters 
Washington, DC 20546-0001, USA 


STATEMENT OF INTENT 


The Consultative Committee for Space Data Systems (CCSDS) is an organization 
officially established by the management of its members. The Committee meets 
periodically to address data systems problems that are common to all 
participants, and to formulate sound technical solutions to these problems. 
Inasmuch as participation in the CCSDS is completely voluntary, the results 
of Committee actions are termed Recommended Standards and are not considered
binding on any Agency. 

This Recommended Standard is issued by, and represents the consensus of, the 
CCSDS members. Endorsement of this Recommendation is entirely voluntary. 
Endorsement, however, indicates the following understandings: 

Whenever a member establishes a CCSDS-related standard, this standard will be 
in accord with the relevant Recommended Standard. Establishing such a 
standard does not preclude other provisions which a member may develop. 
 
Whenever a member establishes a CCSDS-related standard, that member will 
provide other CCSDS members with the following information: 
-- The standard itself. 

-- The anticipated date of initial operational capability. 

-- The anticipated duration of operational service. 

Specific service arrangements shall be made via memoranda of agreement. 
Neither this Recommended Standard nor any ensuing standard is a substitute 
for a memorandum of agreement. 

No later than five years from its date of issuance, this Recommended Standard 
will be reviewed by the CCSDS to determine whether it should: (1) remain in 
effect without change; (2) be changed to reflect the impact of new 
technologies, new requirements, or new directions; or (3) be retired or 
canceled. 
In those instances when a new version of a Recommended Standard is issued, 
existing CCSDS-related member standards and implementations are not negated 
or deemed to be non-CCSDS compatible. It is the responsibility of each 
member to determine when such standards or implementations are to be 
modified. Each member is, however, strongly encouraged to direct planning 
for its new standards and implementations towards the later version of the 
Recommended Standard. 


FOREWORD 


This document is a Recommended Standard for tracking data messages and has 
been prepared by the Consultative Committee for Space Data Systems (CCSDS). 
The tracking data message described in this Recommended Standard is the 
baseline concept for tracking data interchange applications that are 
cross-supported between Agencies of the CCSDS. 

This Recommended Standard establishes a common framework and provides a 
common basis for the format of tracking data exchange between space agencies. 
It allows implementing organizations within each Agency to proceed 
coherently with the development of compatible derived standards for the 
flight and ground systems that are within their cognizance. Derived Agency 
standards may implement only a subset of the optional features allowed by 
the Recommended Standard and may incorporate features not addressed by this 
Recommended Standard. 

Through the process of normal evolution, it is expected that expansion, 
deletion or modification to this document may occur. This Recommended 
Standard is therefore subject to CCSDS document management and change 
control procedures, as defined in the Procedures Manual for the Consultative 
Committee for Space Data Systems. Current versions of CCSDS documents are 
maintained at the CCSDS Web site: 

http://www.ccsds.org/ 

Questions relating to the contents or status of this document should be 
addressed to the CCSDS Secretariat at the address indicated on page i. 


At time of publication, the active Member and Observer Agencies of the 
CCSDS were: 

Member Agencies 

- Agenzia Spaziale Italiana (ASI)/Italy. 
- British National Space Centre (BNSC)/United Kingdom. 
- Canadian Space Agency (CSA)/Canada. 
- Centre National d'Etudes Spatiales (CNES)/France. 
- Deutsches Zentrum fur Luft- und Raumfahrt e.V. (DLR)/Germany. 
- European Space Agency (ESA)/Europe. 
- Federal Space Agency (FSA)/Russian Federation. 
- Instituto Nacional de Pesquisas Espaciais (INPE)/Brazil. 
- Japan Aerospace Exploration Agency (JAXA)/Japan. 
- National Aeronautics and Space Administration (NASA)/USA. 
Observer Agencies 
- Austrian Space Agency (ASA)/Austria. 
- Belgian Federal Science Policy Office (BFSPO)/Belgium. 
- Central Research Institute of Machine Building (TsNIIMash)/Russian 
Federation. 
- Centro Tecnico Aeroespacial (CTA)/Brazil. 
- Chinese Academy of Sciences (CAS)/China. 
- Chinese Academy of Space Technology (CAST)/China. 
- Commonwealth Scientific and Industrial Research Organization (CSIRO)/
Australia. 
- Danish National Space Center (DNSC)/Denmark. 
- European Organization for the Exploitation of Meteorological Satellites 
(EUMETSAT)/Europe. 
- European Telecommunications Satellite Organization (EUTELSAT)/Europe. 
- Hellenic National Space Committee (HNSC)/Greece. 
- Indian Space Research Organization (ISRO)/India. 
- Institute of Space Research (IKI)/Russian Federation. 
- KFKI Research Institute for Particle & Nuclear Physics (KFKI)/Hungary. 
- Korea Aerospace Research Institute (KARI)/Korea. 
- MIKOMTEK: CSIR (CSIR)/Republic of South Africa. 
- Ministry of Communications (MOC)/Israel. 
- National Institute of Information and Communications Technology (NICT)/
Japan. 
- National Oceanic and Atmospheric Administration (NOAA)/USA. 
- National Space Organization (NSPO)/Taiwan. 
- Naval Center for Space Technology (NCST)/USA. 
- Space and Upper Atmosphere Research Commission (SUPARCO)/Pakistan. 
- Swedish Space Corporation (SSC)/Sweden. 
- United States Geological Survey (USGS)/USA. 


DOCUMENT CONTROL 

Document Title Date Status 
CCSDS Tracking Data Message, November Original issue 
503.0-B-1 Recommended Standard, Issue 1 2007 

CCSDS RECOMMENDED STANDARD FOR TRACKING DATA MESSAGE 


CONTENTS 


Section                                                                  Page 
1 INTRODUCTION.......................................................... 1-1 
1.1 PURPOSE ............................................................ 1-1 
1.2 SCOPE AND APPLICABILITY ............................................ 1-1 
1.3 CONVENTIONS AND DEFINITIONS......................................... 1-2 
1.4 STRUCTURE OF THIS DOCUMENT.......................................... 1-3 
1.5 REFERENCES ......................................................... 1-4 

2 OVERVIEW.............................................................. 2-1 
2.1 GENERAL ............................................................ 2-1 
2.2 THE TRACKING DATA MESSAGE (TDM) BASIC CONTENT ...................... 2-1 

3 TRACKING DATA MESSAGE STRUCTURE AND CONTENT........................... 3-1 
3.1 GENERAL ............................................................ 3-1 
3.2 TDM HEADER ......................................................... 3-3 
3.3 TDM METADATA ....................................................... 3-5 
3.4 TDM DATA SECTION (GENERAL SPECIFICATION) ........................... 3-19 
3.5 TDM DATA SECTION KEYWORDS .......................................... 3-23 

4 TRACKING DATA MESSAGE SYNTAX ......................................... 4-1 
4.1 GENERAL ............................................................ 4-1 
4.2 TDM LINES .......................................................... 4-1 
4.3 TDM VALUES ......................................................... 4-2 
4.4 UNITS IN THE TDM ................................................... 4-3 
4.5 COMMENTS IN A TDM .................................................. 4-4 

5 SECURITY.............................................................. 5-1 
5.1 GENERAL ............................................  
5.2 SECURITY CONCERNS RELATED TO THIS RECOMMENDED 
STANDARD ............................................................... 5-1 
5.3 POTENTIAL THREATS AND ATTACK SCENARIOS ............................. 5-2 
5.4 CONSEQUENCES OF NOT APPLYING SECURITY TO THE 
TECHNOLOGY ............................................................. 5-2 
5.5 DATA SECURITY IMPLEMENTATION SPECIFICS ............................. 5-2 

ANNEX A VALUES FOR TIME_SYSTEM AND REFERENCE_FRAME 
(NORMATIVE) ............................................................ A-1 
ANNEX B ITEMS FOR AN INTERFACE CONTROL DOCUMENT 
(INFORMATIVE) .......................................................... B-1 
ANNEX C ABBREVIATIONS AND ACRONYMS (INFORMATIVE)........................ C-1 
ANNEX D EXAMPLE TRACKING DATA MESSAGES (INFORMATIVE) ................... D-1 
ANNEX E INFORMATIVE REFERENCES (INFORMATIVE) ........................... E-1 
ANNEX F RATIONALE FOR TRACKING DATA MESSAGES 
(INFORMATIVE) .......................................................... F-1 
ANNEX G TDM SUMMARY SHEET (INFORMATIVE) ................................ G-1 

Figure 

D-1 TDM Example: One-Way Data .......................................... D-1 
D-2 TDM Example: One-Way Data w/Frequency Offset ....................... D-2 
D-3 TDM Example: Two-Way Frequency Data for Doppler Calculation ........ D-3 
D-4 TDM Example: Two-Way Ranging Data Only ............................. D-4 
D-5 TDM Example: Three-Way Frequency Data .............................. D-5 
D-6 TDM Example: Four-Way Data ......................................... D-6 
D-7 TDM Example: One S/C, X-up, S-down, X-down, Ka-down, Three Segments  D-7 
D-8 TDM Example: Angles, Range, Doppler Combined in Single TDM ......... D-8 
D-9 TDM Example: Range Data with TIMETAG_REF=TRANSMIT .................. D-9 
D-10 TDM Example: Differenced Doppler Observable ....................... D-10 
D-11 TDM Example: Delta-DOR Observable.................................. D-11 
D-12 TDM Example: Angle Data Only ...................................... D-12 
D-13 TDM Example: Media Data Only ...................................... D-13 
D-14 TDM Example: Meteorological Data Only ............................. D-14 
D-15 TDM Example: Clock Bias/Drift Only ................................ D-15 

Table 

3-1 TDM Structure ...................................................... 3-2 
3-2 TDM Header ......................................................... 3-3 
3-3 TDM Metadata Section ............................................... 3-7 
3-4 Tracking Data Record Generic Format ................................ 3-19 
3-5 Summary Table of TDM Data Section Keywords (Alpha Order) ........... 3-24 
3-6 Summary Table of TDM Data Section Keywords (Category Order) ........ 3-25 
F-1 Primary Requirements ............................................... F-2 
F-2 Heritage Requirements .............................................. F-3 
F-3 Desirable Characteristics .......................................... F-3 


1 INTRODUCTION 

1.1 PURPOSE 
1.1.1 This Tracking Data Message (TDM) Recommended Standard specifies a 
standard message format for use in exchanging spacecraft tracking data 
between space agencies. Such exchanges are used for distributing tracking 
data output from routine interagency cross-supports in which spacecraft 
missions managed by one agency are tracked from a ground station managed by 
a second agency. The standardization of tracking data formats facilitates 
space agency allocation of tracking sessions to alternate tracking 
resources. This Recommended Standard has been developed via consensus of the 
Navigation Working Group of the CCSDS Mission Operations and Information 
Management Services (MOIMS) area. 

1.1.2 This document includes requirements and criteria that the message 
format has been designed to meet. For exchanges where these requirements do 
not capture the needs of the participating Agencies another mechanism may be 
selected. 

1.2 SCOPE AND APPLICABILITY 
1.2.1 This Recommended Standard contains the specification for a Tracking 
Data Message designed for applications involving tracking data interchange 
between space data systems. Tracking data includes data types such as 
Doppler, transmit/received frequencies, range, angles, Delta-DOR, DORIS, 
PRARE, media correction, weather, etc. The rationale behind the design of 
the message is described in annex F and may help the application engineer 
construct a suitable message. It is acknowledged that this version of the 
Recommended Standard may not apply to every single tracking session or data 
type; however, it is desired to focus on covering approximately the '95% 
level' of tracking scenarios, and to expand the coverage in future versions 
as experience with the TDM is gained. 

1.2.2 This message is suited to inter-agency exchanges that involve 
automated interaction. The attributes of a TDM make it primarily suitable 
for use in computer-to-computer communication because of the large amount of 
data typically present. The TDM is self-contained, with no additional 
information required beyond that specified in an Interface Control Document 
(ICD) written jointly by the service provider and customer agency. 

1.2.3 Definition of the accuracy pertaining to any particular TDM is outside 
the scope of this Recommended Standard and should be specified via an 
Interface Control Document (ICD) between data exchange participants. 

1.2.4 This Recommended Standard is applicable only to the message format and 
content, but not to its transmission. The method of transmitting the message 
between exchange partners is beyond the scope of this document and should be 
specified in the ICD. Message transmission could be based on a CCSDS data 
transfer protocol, file based transfer protocol such as SFTP, 
stream-oriented media, or other secure transmission mechanism. In general, 
the transmission mechanism must not place constraints on the technical data 
content of a TDM. 

1.2.5 There are some specific exclusions to the TDM, as listed below: 
1.2.5.1 Satellite Laser Ranging (SLR) 'Fullrate' and/or 'Normal Points' 
format (sometimes referred to as 'Quicklook'), which are already transferred 
via a standardized format documented at http://ilrs.gsfc.nasa.gov/;

1.2.5.2 Exchanges of raw Global Navigation Satellite System (GNSS) data, 
which is standardized via the RINEX format (
http://gps.wva.net/html.common/rinex.html); 

1.2.5.3 Global Positioning Satellite (GPS) navigation solutions, which are 
standardized via the SP3 format (http://www.ngs.noaa.gov/GPS/GPS.html);1 

1.2.5.4 Optical data from navigation cameras (pixel based, row-column, etc.); 

1.2.5.5 LIDAR data (which may include a laser range finder); however, such 
data could conceivably be transferred via TDM with a 'RANGE' keyword 
(see 3.5.2.6); and 1.2.5.6 Altimeter data; however, such data could 
conceivably be transferred via TDM with a 'RANGE' keyword (see 3.5.2.6). 

1.2.6 Description of the message format based on the use of eXtensible 
Markup Language (XML) is detailed in an integrated XML schema document for 
all Navigation Data Message Recommendations: Attitude Data Messages (ADM), 
Orbit Data Messages (ODM), and Tracking Data Message (TDM). See reference 
[E8]. 

1.3 CONVENTIONS AND DEFINITIONS 
1.3.1 Conventions and definitions of navigation concepts such as reference 
frames, time systems, etc., are provided in reference [1]. 

1.3.2 The following conventions apply throughout this Recommended Standard: 
- the words 'shall' and 'must' imply a binding and verifiable specification; 
- the word 'should' implies an optional, but desirable, specification; 
- the word 'may' implies an optional specification; 
- the words 'is', 'are', and 'will' imply statements of fact.

---------------------------------------------------------------------------- 
1 It has been suggested that the statement regarding navigation solutions 
being standardized by SP3 is not correct, because SP3 prescribes equidistant 
data (ephemerides), which are in general not provided by each GPS/GNSS 
receiver. It was proposed that the navigation solution data (epoch, x, y, z, 
vx, vy, vz) should be provided in the TDM, with the velocities as optional 
values. However, this would require major changes to the TDM that are 
contrary to its intended purpose. As an alternative, the CCSDS Orbit Data 
Messages OEM (Orbit Ephemeris Message) (reference [4]) could be used to 
convey the navigation solution if all position and velocity components are 
transferred. The OEM is already set up to convey all the required values, 
and can be used to convey orbit reconstructions as well as orbit p
redictions. 
----------------------------------------------------------------------------

- The word 'participant' denotes an entity that has the ability to acquire or 
broadcast navigation messages and/or radio frequencies, for example, a 
spacecraft, a quasar, a tracking station, a tracking instrument, or an 
agency. 
- The term 'n/a' or 'N/A' denotes an attribute that is not applicable or not 
available. 

1.3.3 The following conventions for unit notations apply throughout this 
Recommended Standard. Insofar as possible, an effort has been made to use 
units that are part of the International System of Units (SI Units); units 
are either SI base units, SI derived units, or units outside the SI that are 
accepted for use with the SI (see reference [8]). There are a small number 
of specific cases where units that are more widely used in the navigation 
community are specified, but every effort has been made to minimize these 
departures from the SI. 
%: per cent 
dBHz: decibels referenced to one Hz 
dBW: decibels referenced to one Watt 
deg: degrees of plane angle 
hPa: hectoPascal 
Hz: Hertz 

K: degrees Kelvin 
km: kilometers 
m: meters 
RU: range units 
s: seconds 
TECU: Total Electron Count Units 

1.4 STRUCTURE OF THIS DOCUMENT 
1.4.1 Section 2 provides a brief overview of the CCSDS-recommended Tracking 
Data Message (TDM). 

1.4.2 Section 3 provides details about the structure and content of the TDM. 

1.4.3 Section 4 provides details about the syntax used in the TDM. 

1.4.4 Section 5 discusses security considerations for the TDM. 

1.4.5 Annex A provides a normative list of approved values for selected TDM 
Metadata Section keywords. 

1.4.6 Annex B lists a number of items that should be covered in interagency 
ICDs prior to exchanging TDMs on a regular basis. There are several 
statements throughout the document that refer to the desirability or 
necessity of such a document; this annex consolidates all the suggested ICD 
items in a single list. 

1.4.7 Annex C is a list of abbreviations and acronyms applicable to the TDM. 

1.4.8 Annex D shows how various tracking scenarios can be accommodated using 
the TDM, via several examples. 

1.4.9 Annex E contains a list of informative references. 

1.4.10 Annex F lists a set of requirements and desirable characteristics 
that were taken into consideration in the design of the TDM. 

1.4.11 Annex G provides a TDM Summary Sheet, or 'Quick Reference'. 

1.5 
REFERENCES 
The following documents contain provisions which, through reference in this 
text, constitute provisions of this Recommended Standard. At the time of 
publication, the editions indicated were valid. All documents are subject to 
revision, and users of this Recommended Standard are encouraged to 
investigate the possibility of applying the most recent editions of the 
documents indicated below. The CCSDS Secretariat maintains a register of 
currently valid CCSDS Recommended Standards. 

[1] 
Navigation Data-Definitions and Conventions. Report Concerning Space Data 
System Standards, CCSDS 500.0-G-2. Green Book. Issue 2. Washington, D.C.: 
CCSDS, November 2005. 
[2] 
Information Technology-8-Bit Single-Byte Coded Graphic Character Sets-Part 1: 
Latin Alphabet No. 1. International Standard, ISO/IEC 8859-1:1998. 
Geneva:ISO, 1998. 
[3] 
Time Code Formats. Recommendation for Space Data System Standards, CCSDS 
301.0-B-3. Blue Book. Issue 3. Washington, D.C.: CCSDS, January 2002. 
[4] 
Orbit Data Messages. Recommendation for Space Data System Standards, CCSDS 
502.0-B-1. Blue Book. Issue 1. Washington, D.C.: CCSDS, September 2004. 
[5] 
Spacewarn Bulletin. Greenbelt, MD, USA: WDC-SI. 
<http://nssdc.gsfc.nasa.gov/spacewarn> 
[6] 
XML Schema Part 2: Datatypes. 2nd ed. P. Biron and A. Malhotra, eds. W3C 
Recommendation 28. n.p.: W3C, 2004. 
[7] 
IEEE Standard for Binary Floating-Point Arithmetic. IEEE Std 754-1985. New 
York: IEEE, 1985. 
[8] 
"The NIST Reference on Constants, Units, and Uncertainty." NIST Physics 
Laboratory. <http://physics.nist.gov/cuu/index.html> 
NOTE - Informative references are provided in annex E. 


OVERVIEW 

2.1 GENERAL 
This section provides a high-level overview of the CCSDS recommended 
Tracking Data Message, a message format designed to facilitate standardized 
exchange of spacecraft tracking data between space agencies. 


2.2 THE TRACKING DATA MESSAGE (TDM) BASIC CONTENT 
2.2.1 The TDM is realized as a sequence of plain ASCII text lines (reference 
[2]), which may be in either a file format or a real-time stream. The 
content is separated into three basic types of computer data structure as 
described in section 3. The TDM architecture takes into account that some 
aspects of tracking data change on a measurement-by-measurement basis 
(data); some aspects change less frequently, but perhaps several times per 
track (metadata); and other aspects change only rarely, e.g., once per track 
or perhaps less frequently (header). The TDM makes it possible to convey a 
variety of tracking data used in the orbit determination process in a single 
data message (e.g., standard Doppler and range radiometrics in a variety of 
tracking modes, VLBI data, antenna pointing angles, etc.). To aid in 
precision trajectory modeling, additional ancillary information may be 
included within a TDM if it is desired and/or available (e.g., media 
corrections, meteorological data, clock data, and other ancillary data). 
Facilities for documenting comments are provided. 

2.2.2 The Tracking Data Message in this version of the Recommended Standard 
is ASCII-text formatted. While binary-based tracking data message formats 
are computer efficient and minimize overhead during data transfer, there are 
ground-segment applications for which an ASCII character-based message is 
more appropriate. For example, ASCII format character-based tracking data 
representations are useful in transferring data between heterogeneous 
computing systems, because the ASCII character set is nearly universally 
used and is interpretable by all popular systems. In addition, direct 
human-readable dumps of text to displays, emails, documents or printers are 
possible without preprocessing. The penalty for this convenience is some 
measure of inefficiency (based on early tests, such penalty would be greatly 
reduced if the data is compressed for transmission). 

2.2.3 The ASCII text in a TDM can be exchanged in either of two formats: a 
'keywordvalue notation' format (KVN) or an XML format. The KVN formatted TDM 
is described in this document. Description of the message format based on 
XML is detailed in an integrated XML schema document for all Navigation Data 
Messages (reference [E8]). Exchange participants should specify in the ICD 
which TDM ASCII format will be exchanged, the KVN or the XML format. 

2.2.4 Normally a TDM will contain tracking data for a single spacecraft 
participant, unless the tracking session is spacecraft-to-spacecraft in 
nature. If a tracking operation involves information from multiple 
spacecraft participants tracked from the ground, the data may be included in 
a single TDM by using multiple segments (see 3.1); or multiple TDMs may be 
used, one per spacecraft participant. 

2.2.5 For a given spacecraft participant, multiple tracking data messages 
may be provided in a message exchange session to achieve the tracking data 
requirements of the participating agencies (e.g., launch supports with 
periodically delivered TDMs, or other critical events such as maneuvers, 
encounters, etc.). 

2.2.6 Provisions for the frequency of exchange and special types of 
exchanges should be specified in an ICD. 


3 TRACKING DATA MESSAGE STRUCTURE AND CONTENT 

3.1 GENERAL 
3.1.1 The TDM shall consist of digital data represented as ASCII text lines 
(see reference [2]) in KVN format (Keyword = Value Notation-see section 4). 
The lines constituting a TDM shall be represented as a combination of: 
a) a Header (see 3.2); 
b) a Metadata Section (data about data) (see 3.3); and 
c) a Data Section (tracking data represented as 'Tracking Data Records') 
(see 3.4). 

Optional comments may appear in specified locations in the Header, Metadata, 
and Data Sections (see 4.5). 

3.1.2 Taken together, the Metadata Section and its associated Data Section 
shall be called a TDM Segment. 

3.1.3 Each TDM shall have a Header and a Body. The TDM Body shall consist of 
one or more TDM Segments. There shall be no limit to the number of Segments 
in a given TDM Body, beyond practical constraints, as shown in table 3-1. 
Each Segment shall consist of a Metadata Section and a Data Section that 
consists of a minimum of one Tracking Data Record. Therefore, the overall 
structure of the TDM shall be: 
- TDM = Header + Body; 
- Body = Segment [+ Segment + ... + Segment]; 
- Segment = Metadata Section + Data Section; 
- Data Section = Tracking Data Record (TDR) [ + TDR + TDR ... + TDR]. 
CCSDS 503.0-B-1 Page 3-1 November 2007 

Table 3-1: TDM Structure 
See PDF version of document for table.

3.1.4 The TDM shall consist of tracking data for one or more tracking 
participants at multiple epochs contained within a specified time range. 
(Note that the term 'participant' applies equally to spacecraft, quasars, 
tracking stations, and agency centers, as discussed in reference [1]. Thus 
there may exist Tracking Data Messages for which there is no applicable 
spacecraft.) Generally, but not necessarily, the time range of a TDM may 
correspond to a 'tracking pass'. 

3.1.5 The TDM shall be easily readable by both humans and computers. 

3.1.6 It shall be possible to exchange a TDM either as a real-time stream or 
as a file. 

3.1.7 The TDM file naming scheme shall be agreed to on a case-by-case basis 
between the participating agencies, typically specified in an ICD. In 
general, the file name syntax and length must not violate computer 
constraints for those computing environments in use by Member Agencies for 
processing tracking data. 

3.1.8 The method of exchanging TDMs shall be decided on a case-by-case basis 
by the participating agencies and documented in an ICD. The exchange method 
shall not constrain the tracking data content. 


3.2 TDM HEADER 
3.2.1 The TDM shall include a Header that consists of information that 
identifies the basic parameters of the message. The first Header line must 
be the first non-blank line in the message. 
3.2.2 A description of TDM Header items and values is provided in table 3-2, 
which specifies for each item: 
- the keyword to be used; 
- a short description of the item; 
- examples of allowed values; and 
- whether the item is obligatory or not obligatory. 
3.2.3 Only those keywords shown in table 3-2 shall be used in a TDM Header. 
The order of occurrence of the obligatory and optional KVN assignments shall 
be fixed as shown in table 3-2. 


Table 3-2: TDM Header 
See PDF version of document for table.


3.2.4 Each line in the TDM Header, with the exception of COMMENTs, shall 
have the following generic format: 
keyword = value 

3.2.5 The TDM Header shall provide a CCSDS Tracking Data Message version 
number that identifies the format version; this is included to anticipate 
future changes and to provide the ability to extend the standard with no 
disruption to existing users. The version keyword is CCSDS_TDM_VERS and the 
value shall have the form of x.y where y is incremented for corrections and 
minor changes, and x is incremented for major changes. Version 1.0 shall be 
reserved for the initial version accepted by the CCSDS as an official 
Recommended Standard ('Blue Book'). Interagency testing of TDMs shall be 
conducted using version numbers less than 1.0 (e.g., '0.y'). Specific TDM 
versions that will be exchanged between agencies should be documented via 
the ICD. 

3.2.6 The TDM Header shall include the CREATION_DATE keyword with the value 
set to the Coordinated Universal Time (UTC) when the data was created (file 
creation time if in file format, or first data point in stream), as 
specified in reference [3] (ASCII Time Code A or B). 


3.3 TDM METADATA 

3.3.1 GENERAL 
3.3.1.1 The TDM shall include at least one Metadata Section that contains 
configuration details (metadata) applicable to the Data Section in the same 
TDM Segment. The information in the Metadata Section aligns with the 
tracking data to provide descriptive information (typically, the metadata is 
the type of information that does not change frequently during a tracking 
session). 

3.3.1.2 Each line in the TDM Metadata Section, with the exception of 
COMMENTs, shall have the following generic format: 
keyword = value 

3.3.1.3 A single TDM Metadata Section shall precede each Data Section.
 
3.3.1.4 When there are changes in the values assigned to any of the keywords 
in the Metadata Section, a new Segment must be started (e.g., mode change 
from one-way to two-way tracking). 

3.3.1.5 The first and last lines of a TDM Metadata Section shall consist of 
the META_START and META_STOP keywords, respectively. These keywords are used 
to facilitate parsing. 

3.3.1.6 Table 3-3 specifies for each Metadata item: 
- the keyword to be used; 
- a short description of the item; 
- a list of required values or examples of allowed values; and 
- whether the item is obligatory or not obligatory. 
The column marked 'N/E' will contain an 'N' if the column marked 'Normative 
Values / Examples' contains normative values, and will contain an 'E' if the 
column contains example values that are non-normative. For normative values, 
a fully enumerated set of values may be provided, or the contents of table 
3-3 may be a sample of values that are fully enumerated in an annex. In this 
latter case, the necessary annex is identified. 

3.3.1.7 Only those keywords shown in table 3-3 shall be used in a TDM 
Metadata Section. Obligatory items shall appear in every TDM Metadata 
Section. Items that are not obligatory may or may not appear in any given 
TDM Metadata Section, at the discretion of the data producer, based on the 
requirements of the data and its intended application (see annex G for a TDM 
Summary Sheet that illustrates the relationships between data types and 
metadata). For most metadata keywords there is no default value; where there 
is a default value, it is specified at the end of the 'Description' section 
for the given keyword. If a keyword is not present in a TDM, and a default 
value is defined, the default shall be assumed. 

3.3.1.8 The order of occurrence of the obligatory and optional KVN 
assignments shall be fixed as shown in table 3-3. 

3.3.1.9 The Metadata Section shall describe the participants in a tracking 
session using the keyword 'PARTICIPANT_n'. There may be several participants 
associated with a tracking data session (the number of participants is 
always greater than or equal to one, and generally greater than or equal to 
two). The 'n' in the keyword is an indexer. The indexer shall not be the 
same for any two participants in a given Metadata Section. 

3.3.1.10 The value associated with any given PARTICIPANT_n keyword may be a 
ground tracking station, a spacecraft, a quasar catalog name; or may include 
non-traditional objects, such as landers, rovers, balloons, etc. The list of 
eligible names that is used to specify participants should be documented in 
the ICD. Subsections 3.3.2 through 3.3.2.7 provide an explanation of the 
tracking modes and participant numbers. Participants may generally be listed 
in any order. 

3.3.1.11 In this version of the TDM, the maximum number of participants per 
segment shall be five. If more than five participants are defined (i.e., 
PARTICIPANT_6 +), then special arrangements between exchange participants 
are necessary. These arrangements should be documented in an ICD. Note that 
although the restriction to five participants may appear to be a constraint 
it is probably not, because of other aspects of the TDM structure. Five 
participants easily allow the user to describe the great majority of 
tracking passes. In some cases there may be 'critical event' tracking 
sessions in which a single spacecraft is tracked by a large number of 
antennas, such that the total number of participants appears to be six or 
more. However, because of the nature of the 'PATH' keyword, several TDM 
Segments would be required to describe the full set of tracking data. For 
the critical event example scenario just given, one TDM Segment would be 
used to describe the two-way connection, and one additional segment would be 
required for each three-way connection; it would not be possible to provide 
a single 'PATH' statement that would convey the multiple signal paths. 

Table 3-3: TDM Metadata Section 
See PDF version of document for table.


3.3.2 MODE AND PATH SETTINGS FOR TYPICAL TRACKING SESSIONS 
NOTE - 
The following subsections discuss possible relationships between the 'MODE', 
'PATH', and 'PARTICIPANT_n' keywords. This discussion is provided in 
order to facilitate the implementation of TDM generation for typical tracking 
sessions (e.g., one-way, two-way, three-way, etc.). Annex G supplies 
recommendations of the metadata keywords that should be used to properly 
describe the tracking data of various types depending on the settings of the 
MODE and PATH keywords, with allowance for characteristics of the uplink 
frequency (if applicable). 

3.3.2.1 One-Way Data 
3.3.2.1.1 
The setting of the 'MODE' keyword shall be 'SEQUENTIAL'. 

3.3.2.1.2 For one-way data, the signal path generally originates at the 
spacecraft transmitter, so the spacecraft's participant number shall be the 
first number in the value assigned to the PATH keyword. The receiver, which 
may be a tracking station or another spacecraft, shall be represented by the 
second number in the value of the PATH keyword. 
EXAMPLES - 'PATH=1,2' indicates transmission from PARTICIPANT_1 to 
PARTICIPANT_2; 'PATH=2,1' indicates transmission from 
PARTICIPANT_2 to PARTICIPANT_1. 

NOTE - 
See figures D-1 and D-2 for example TDMs containing one-way tracking data. 

3.3.2.2 Two-Way Data 
3.3.2.2.1 
The setting of the 'MODE' keyword shall be 'SEQUENTIAL'. 

3.3.2.2.2 For two-way data, the signal path originates at a ground antenna (
or a 'first spacecraft'), so the uplink (or crosslink) transmit participant 
number shall be the first number in the value assigned to the PATH keyword. 
The participant number of the transponder onboard the spacecraft to which 
the signal is being uplinked shall be the second number in the value 
assigned to the PATH keyword. The third entry in the PATH keyword value shall 
be the same as the first (two way downlink is received at the same 
participant which transmits the uplink/crosslink). Both PARTICIPANT_1 and 
PARTICIPANT_2 may be spacecraft as in the case of a spacecraft-spacecraft 
exchange. 
EXAMPLES - 'PATH=1,2,1' indicates transmission from PARTICIPANT_1 to 
PARTICIPANT_2, with final reception at PARTICIPANT_1; 
'PATH=2,1,2' indicates transmission from PARTICIPANT_2 to 
PARTICIPANT_1, with final reception at PARTICIPANT_2. 

NOTE - 
See figures D-3, D-4, and D-9 for example TDMs containing two-way tracking 
data. 

3.3.2.3 Three-Way Data 
3.3.2.3.1 
The setting of the 'MODE' keyword shall be 'SEQUENTIAL'. 

3.3.2.3.2 For three-way data, the signal path originates with a ground 
station (uplink antenna), so the participant number of the uplink station 
shall be the first entry in the value assigned to the PATH keyword. The 
participant number of the transponder onboard the spacecraft to which the 
signal is being uplinked shall be the second number in the value assigned to 
the PATH keyword. The participant number of the downlink antenna shall be the 
third number in the value assigned to the PATH keyword. 

3.3.2.3.3 For three-way data, the first and last numbers in the value 
assigned to the PATH keyword must be different. 
EXAMPLES - 'PATH=1,2,3' indicates transmission from PARTICIPANT_1 to 
PARTICIPANT_2, with final reception at PARTICIPANT_3. 

NOTE - 
See figure D-5 for an example TDM containing three-way tracking data. 

3.3.2.4 N-Way Data 
3.3.2.4.1 One-way, two-way, and three-way tracking cover the bulk of 
tracking sequences. However, four-way and greater (n-way) scenarios are 
possible (e.g., via use of one or more relay satellites). These may be 
accomplished via the sequence assigned to the PATH keyword. 

3.3.2.4.2 The setting of the 'MODE' keyword shall be 'SEQUENTIAL'. 

3.3.2.4.3 The value assigned to the PATH keyword shall convey the signal 
path among the participants followed by the signal; e.g., 'PATH=1,2,3,2,1' 
and 'PATH=1,2,3,4' represent two different four-way tracking signal paths. 

3.3.2.4.4 In this version of the TDM, the maximum number of participants per 
segment shall be five. If more than five participants are defined (i.e., 
PARTICIPANT_6 +), then special arrangements shall be made; these should be 
specified in the ICD. 
NOTE - See figure D-6 for an example TDM containing four-way tracking data. 

3.3.2.5 Differenced Modes and VLBI Data 
3.3.2.5.1 Differenced data and VLBI data may also be exchanged in a Tracking 
Data Message. Differenced data can include differenced Doppler and 
differenced range (see references [E3] and [E4]). 

3.3.2.5.2 The setting of the 'MODE' keyword shall be 'SINGLE_DIFF'. 

3.3.2.5.3 When the MODE is 'SINGLE_DIFF', two path keywords, 'PATH_1' and 
'PATH_2', shall be used to convey the signal paths that have been 
differenced. 

3.3.2.5.4 When the mode is 'SINGLE_DIFF', the observable is calculated by 
subtracting the value achieved for the measurement using PATH_1 from the 
value achieved using PATH_2, 
i.e., PATH_2 - PATH_1. Only the final observable shall be communicated via 
the TDM. 

3.3.2.5.5 If the TDM contains differenced Doppler shift data, the 
'RECEIVE_FREQ' keyword shall be used for the observable (the 'RECEIVE_FREQ' 
keyword is a Data Section keyword not yet described in the text-see 3.5.2.7). 

3.3.2.5.6 If the TDM contains two-way or three-way differenced Doppler data, 
then a history of the uplink frequencies shall be provided with the 
TRANSMIT_FREQ_n keyword in order to process the data correctly (the 
'TRANSMIT_FREQ_n' keyword is a Data Section keyword not yet described in the 
text-see 3.5.2.8). 

3.3.2.5.7 If differenced range is provided, the 'RANGE' keyword shall be 
used for the observable (the 'RANGE' keyword is a Data Section keyword not 
yet described in the text- see 3.5.2.6). 

3.3.2.5.8 If the TDM contains differenced data collected during a 
Delta-Differential One Way Range (Delta-DOR) session with a spacecraft, then 
the DOR keyword shall be used for the observable (the 'DOR' keyword is a 
Data Section keyword not yet described in the text-see 3.5.3.2). 

3.3.2.5.9 If the TDM contains differenced data collected during a VLBI 
session with a quasar, then the VLBI_DELAY keyword shall be used for the 
observable (the 'VLBI_DELAY' keyword is a Data Section keyword not yet 
described in the text-see 3.5.3.3). 

NOTE - 
See figures D-10 and D-11 for example TDMs containing single differenced 
tracking data. 

3.3.2.6 Angle Data 
Angle data is applicable for any tracking scenario where MODE=SEQUENTIAL is 
specified, but is based on pointing with respect to the two final 
participants only (e.g., spacecraft downlink to an antenna, direction of a 
participant measured by a navigation camera, etc.). 

NOTE - 
See figures D-8 and D-12 for example TDMs containing angle data. 

3.3.2.7 Media, Weather, Ancillary Data 
3.3.2.7.1 When all the data in a TDM Segment is media related, weather 
related, or ancillary-data related, then the use of the MODE keyword may or 
may not apply as discussed below. 

3.3.2.7.2 Data of this type may be relative to a reference location within 
the tracking complex; in this case the methods used to extrapolate the 
measurements to other antennas should be specified in the ICD. In the case 
where a reference location is used, there shall be only one participant 
(PARTICIPANT_1), which is the reference antenna, and the MODE keyword shall 
not be used. This case corresponds to tropospheric correction data, zenith 
ionospheric correction data, and weather data. 

3.3.2.7.3 When ionospheric charged particle delays are provided for a 
line-of-sight between the antenna and a specific spacecraft, the 
participants include both the antenna and the spacecraft, the MODE should be 
set to 'SEQUENTIAL', and a standard PATH statement should be used. 
NOTE - 
See figures D-13 through D-15 for example TDMs containing tracking data of 
these types. 


3.4 TDM DATA SECTION (GENERAL SPECIFICATION) 
3.4.1 The Data Section of the TDM Segment shall consist of one or more 
Tracking Data Records. Each Tracking Data Record shall have the following 
generic format: 
keyword = timetag measurement 

NOTE - More detail on the generic format of a Tracking Data Record is shown 
in table 3-4. 


Table 3-4: Tracking Data Record Generic Format 
See PDF version of document for table.


3.4.2 Each Tracking Data Record must be provided on a single line. 

3.4.3 Each Tracking Data Record shall contain a value that depends upon the 
data type keyword used. The value shall consist of two elements: a timetag 
and a tracking observable (a measurement or calculation based on 
measurements); either without the other is useless for tracking purposes. 
Hereafter, the term 'measurement' shall be understood to include 
calculations based on measurements as noted above. 

3.4.4 At least one blank character must be used to separate the timetag and 
the observable in the value associated with each Tracking Data Record. 

3.4.5 Applicable keywords and their associated characteristics are detailed 
in 3.5. 

3.4.6 There shall be no obligatory keywords in the Data Section of the TDM 
Segment, with the exception of 'DATA_START' and 'DATA_STOP', because the 
data presented in any given TDM is dependent upon the characteristics of the 
data collection activity. 

3.4.7 The Data Section of the TDM Segment shall be delineated by the 
'DATA_START' and 'DATA_STOP' keywords. These keywords are intended to 
facilitate parsing, and will also serve to advise the recipient that all the 
Tracking Data Records associated with the immediately preceding TDM Metadata 
Section have been received (the rationale for including this is that data 
volumes can be very large, so knowing when the data ends is desirable). The 
TDM recipient may process the 'DATA_STOP' keyword as a 'local' end-of-file 
marker. 

3.4.8 Tracking data shall be tagged according to the value of the 
'TIME_SYSTEM' metadata keyword. 

3.4.9 Interpretation of the timetag for transmitted data is straightforward; 
it is the transmit time. Interpretation of the timetag for received data is 
determined by the values of the 'TIMETAG_REF', 'INTEGRATION_REF', and 
'INTEGRATION_INTERVAL' keywords, as applicable (see table 3-3 and 3.5.2.7). 
For other data types (e.g., meteorological, media, clock bias/drift), the 
timetag represents the time the measurement was taken. 

3.4.10 In general, no required ordering of Tracking Data Records shall be 
imposed, because there are certain scenarios in which data are collected 
from multiple sources that are not processed in strictly chronological 
order. Thus it may only be possible to generate data in chronological order 
if it is sorted post-pass. However, there is one ordering requirement placed 
on Tracking Data Records; specifically, in any given Data Section, the data 
for any given keyword shall be in chronological order. Also, some TDM 
creators may wish to sort tracking data by keyword rather than by timetag. 
Special sorting requirements should be specified in the ICD. 

3.4.11 Each keyword/timetag combination must be unique within a given Data 
Section (i.e., a given keyword/timetag combination shall not be repeated in 
the same set of Tracking Data Records). 

3.4.12 The time duration between timetags may be constant, or may vary, 
within any given TDM. 

3.4.13 Every tracking instrument shall have a defined reference location. 
This reference location shall not depend on the observing geometry. The 
tracking instrument locations should be conveyed via an ICD. The ICD 
information should include a complete description of the station locations 
and characteristics, including the antenna coordinates with their defining 
system, plate motion, and the relative geometry of the tracking point and 
cross axis of the antenna mount, accommodations for antenna tilt to avoid 
keyhole problems, etc. The station location could be provided via an OPM 
(reference [4]). Antenna geometry would be necessary for exceptional cases, 
where the station location is not fixed during track, for example.
 
3.4.14 The measurement shall be converted to an equipment-independent 
quantity; e.g., frequencies shall be reported at the 'sky level' (i.e., 
actual transmitted/received frequencies, unless the FREQ_OFFSET keyword is 
used in the metadata). It should not be necessary for the data recipient to 
have detailed information regarding the internal network of the data 
producer. 

3.4.15 Tracking data is normally subject to a number of corrections, as 
described in the following paragraphs. 
3.4.15.1 The tracking data measurements shall be corrected with the best 
estimate of all known instrument calibrations, such as path delay 
calibrations between the reference point and the tracking equipment, if 
applicable. 
NOTE - 
These measures should reduce the requirement for consumers of tracking data 
to have detailed knowledge of the underlying structure of the 
hardware/software system that performed the measurements. 

3.4.15.2 Tracking data should be corrected for ground delays only. The 
corrections that have been applied may be specified to the message recipient 
via use of the optional 'CORRECTION_*' keywords in the metadata. 
NOTE - 
The 'TRANSMIT_DELAY' and 'RECEIVE_DELAY' keywords do not 
represent 'ground corrections' per se. They are meant to convey gross factors 
that do not change from pass-to-pass. However, if exchange partners agree via 
the ICD, 'TRANSMIT_DELAY' and 'RECEIVE_DELAY' could be removed 
from the measurements. It is generally operationally inconvenient for the 
producer to treat these values as corrections because of the possible 
requirement to alter uplink timetags; thus these delays are best handled in 
orbit determination post-processing. Modifying timetags to account for these 
delays also complicates the use of differenced measurements. It is thus more 
straightforward to allow the recipient to process these delays rather than 
to correct the data prior to exchange. 

3.4.15.3 If correction values are indicated via any of the 'CORRECTION_*' 
keywords, then the TDM producer must indicate whether these correction 
values have or have not been applied to the tracking data. This indication 
is accomplished via the use of the metadata keyword 'CORRECTIONS_APPLIED'; 
this metadata item must have a value of 'YES' or 'NO'. 

3.4.15.4 Media corrections (ionosphere, troposphere) should not be applied by 
the TDM producer; media corrections may be applied by the TDM recipient 
using the data conveyed in the STEC, TROPO_WET, and TROPO_DRY Data Section 
keywords. 

3.4.15.5 The party that will perform any applicable spin corrections should 
be specified in the ICD (most appropriate party may be the party that 
operates the spacecraft). 

3.4.15.6 Special correction algorithms that are more complex than a simple 
scalar value should be specified in the ICD. 

3.4.15.7 Any other corrections applied to the data shall be agreed by the 
service provider and the customer Agencies and specified in an ICD. 

3.4.16 All data type keywords in the TDM Data Section must be from 3.5, 
which specifies for each keyword: 
- the keyword to be used; 
- applicable units for the associated values; 
- a reference to the text section where the keyword is described in detail. 
NOTES 

1 
The standard tracking data types are extended to cover also some of the 
ancillary data that may be required for precise orbit determination work. 
Subsection 3.5 identifies the most frequently used data and ancillary types. 

2 
See annex D for detailed usage examples. 

3 
Annex G supplies recommendations of the metadata keywords that should be 
used to properly describe the tracking data of various types depending on 
the settings of the MODE and PATH keywords, with allowance for 
characteristics of the uplink frequency (if applicable). 


3.5 TDM DATA SECTION KEYWORDS 
3.5.1 OVERVIEW 
This subsection describes each of the keywords that may be used in the Data 
Section of the TDM Segment. In general, there is no required order in the 
Data Section of the TDM Segment. Exceptions are the 'DATA_START' and 
'DATA_STOP' keywords, which must be the first and last keywords in the Data 
Section, respectively. For ease of reference, table 3-5 containing all the 
keywords sorted in alphabetical order is shown immediately below. Table 3-6 
repeats the information from table 3-5 in category order. Descriptive 
information about the keywords is shown starting in 3.5.2. The remainder of 
this subsection is organized according to the class of data to which the 
keyword applies (e.g., all the signal related keywords are together, all 
media related keywords are together, etc.). 

Table 3-5: Summary Table of TDM Data Section Keywords (Alpha Order) 
See PDF version of document for table.


Table 3-6: Summary Table of TDM Data Section Keywords (Category Order) 
See PDF version of document for table.


3.5.2 SIGNAL RELATED KEYWORDS 
3.5.2.1 CARRIER_POWER 
The CARRIER_POWER keyword conveys the strength of the radio signal 
transmitted by the spacecraft as received at the ground station or at 
another spacecraft (e.g., in formation flight). This reports the strength of 
the signal received from the spacecraft, in decibels (referenced to 1 watt). 
The unit for the CARRIER_POWER keyword is dBW. The value shall be a double 
precision value, and may be positive, zero, or negative. The value is based 
on the last leg of the signal path (PATH keyword), e.g., spacecraft downlink 
to an antenna. Additional TDM Segments should be used for each participant 
if it is important to know the carrier power at each participant in a PATH 
that involves more than one receiver. 

3.5.2.2 DOPPLER_INSTANTANEOUS 
The value associated with the DOPPLER_INSTANTANEOUS keyword represents the 
instantaneous range rate of the spacecraft. The observable may be one-way, 
two-way or three-way. The value shall be a double precision value and may be 
negative, zero, or positive. Units are km/s. In order to ensure that 
corrections due to the ionosphere and solar plasma are accurately applied, 
the transmit frequency and receive frequency should be supplied when this 
data type is exchanged. 

NOTE - 
The DOPPLER_INSTANTANEOUS assumes a fixed uplink frequency (or one with 
small RTLT errors), and thus should not be used in cases where there is a 
deep space ramped uplink (the TRANSMIT_FREQ and RECEIVE_FREQ keywords should 
be used instead). 

3.5.2.3 DOPPLER_INTEGRATED 
The value associated with the DOPPLER_INTEGRATED keyword represents the mean 
range rate of the spacecraft over the INTEGRATION_INTERVAL specified in the 
Metadata Section. The timetag and the time bounds of the integration 
interval are determined by the TIMETAG_REF and INTEGRATION_REF keywords. The 
observable may be one-way, two-way or three-way. For one-way data, the 
observable is the mean range rate of the spacecraft over the 
INTEGRATION_INTERVAL. For two-way and three-way data, the ICD should specify 
whether the observable is the calculated mean range rate, or half the 
calculated mean range rate (due to the signal's having traveled to the 
spacecraft and back to the receiver). The value shall be a double precision 
value and may be negative, zero, or positive. Units are km/s. In order to 
ensure that corrections due to the ionosphere and solar plasma are 
accurately applied, the transmit frequency and receive frequency should be 
supplied when this data type is exchanged. 

NOTE - 
The DOPPLER_INTEGRATED assumes a fixed uplink frequency (or one with small 
RTLT errors), and thus should not be used in cases where there is a deep 
space ramped uplink (the TRANSMIT_FREQ and RECEIVE_FREQ keywords should be 
used instead). 

3.5.2.4 PC_N0 
The value associated with the PC_N0 keyword shall be the carrier power to 
noise spectral density ratio (Pc/No). The units for PC_N0 shall be dBHz. The 
value shall be a double precision value. 

3.5.2.5 PR_N0 
The value associated with the PR_N0 keyword shall be the ranging power to 
noise spectral density ratio (Pr/No). The units for PR_N0 shall be dBHz. It 
shall be a double precision value, and may be positive, zero, or negative. 

3.5.2.6 RANGE 
The value associated with the RANGE keyword is the range observable. The 
values represent measurements from ambiguous ranging systems, differenced 
range, skin radar, proximity radar, or similar radar. The units for RANGE 
shall be as determined by the 'RANGE_UNITS' metadata keyword (i.e., either 
'km', 's', or 'RU'). The 'RANGE_UNITS' metadata keyword should always be 
specified, but if it is not, the default (preferred) value shall be 'km'. If 
different range units are used by the tracking agency (e.g., 'DSN range 
units'), the definition of the range unit should be described in the ICD. 
Note that for many applications, proper processing of the RANGE will require 
a time history of the uplink frequencies. If ambiguous range is provided 
(i.e., the RANGE_MODULUS is non-zero), then the RANGE does not represent the 
actual range to the spacecraft; a calculation using the RANGE_MODULUS and 
the RANGE observable must be performed. If differenced range is provided 
(MODE = SINGLE_DIFF), the 'RANGE' keyword shall be used to convey the 
difference in range. The value shall be a double precision value, and is 
generally positive (exceptions to this could occur if the data is a 
differenced type, or if the observable is a one-way pseudorange). 

NOTE - 
The TDM specifically excludes Satellite Laser Ranging (SLR), which is already 
transferred via an internationally standardized format documented at 
http://ilrs.gsfc.nasa.gov/. 

3.5.2.7 RECEIVE_FREQ (and RECEIVE_FREQ_n) 
3.5.2.7.1 The RECEIVE_FREQ keyword shall be used to indicate that the values 
represent measurements of the received frequency. It is suitable for use 
with deep space ramped uplink if the TRANSMIT_FREQ is also exchanged. The 
keyword is indexed to accommodate a scenario in which multiple downlinks are 
used; it may also be used without an index where the frequency cannot be 
associated with a particular participant (e.g., in the case of a differenced 
Doppler shift measurement). The value associated with the RECEIVE_FREQ 
keyword shall be the average frequency observable over the 
INTEGRATION_INTERVAL specified in the metadata, at the measurement timetag. 
The interpretation of the timetag shall be determined by the combined 
settings of the TIMETAG_REF, INTEGRATION_REF, and INTEGRATION_INTERVAL 
keywords (see table 3-3 for a description of how the settings of these 
values affect the interpretation of the timetag). Correlation between the 
RECEIVE_FREQ and the associated TRANSMIT_FREQ may be determined via the use 
of an a priori estimate and should be resolved via the orbit determination 
process. The units for RECEIVE_FREQ shall be Hertz (Hz). The value shall be 
a double precision value (generally positive, but could be negative or zero 
if used with the 'FREQ_OFFSET' metadata keyword). 

3.5.2.7.2 Using the RECEIVE_FREQ, the instantaneous Doppler measurement is 
calculated as follows: 


See PDF version of document for equation.


where 'Dm' is the Doppler measurement, 'Ft' is the transmitted frequency, 
'tr' is the transponder ratio (tr=1 for one-way), and 'Fr' is the 
RECEIVE_FREQ. 

For integrated Doppler, the Doppler measurement is calculated as follows, 
where t is the timetag, and .t is the value assigned to the 
INTEGRATION_INTERVAL keyword: 


See PDF version of document for equations.


The limits of integration are determined by the INTEGRATION_REF keyword in 
the metadata; the constant a in the equation has the value -1.5, 0, or 1.5 
for the INTEGRATION_REF values of 'END', 'MIDDLE', or 'START', respectively 
(see reference [E4]). 


See PDF version of document for table.


3.5.2.7.3 If differenced Doppler is provided, the non-indexed 'RECEIVE_FREQ' 
keyword shall be used to convey the difference in Hz. 


3.5.2.7.4 The transponder ratios used for interagency exchanges should be 
specified in the ICD if they are always constant. They may also be specified 
in the metadata by using the TURNAROUND_NUMERATOR and TURNAROUND_DENOMINATOR 
keywords. 

3.5.2.7.5 The equation for four-way Doppler, if it is to be exchanged, 
should be in the ICD since the four-way connections tend to be 
implementation dependent. 

3.5.2.8 TRANSMIT_FREQ_n 
The TRANSMIT_FREQ keyword shall be used to indicate that the values represent 
measurements of a transmitted frequency, e.g., from an uplink operation. The 
TRANSMIT_FREQ keyword is indexed to accommodate scenarios in which multiple 
transmitters are used. The value associated with the TRANSMIT_FREQ_n keyword 
shall be the starting frequency observable at the timetag. The units for 
TRANSMIT_FREQ_n shall be Hertz (Hz). The value shall be a positive double 
precision value. The turnaround ratios necessary to calculate the predicted 
receive frequency may be specified using the TURNAROUND_NUMERATOR and 
TURNAROUND_DENOMINATOR metadata keywords, or may be specified in the ICD. In 
the case of software defined radios, the metadata keywords may be preferable 
as the ratios can change with some regularity and it is necessary to get the 
applicable ratio with the tracking data. Usage notes: when the data mode is 
one-way (i.e., MODE=SEQUENTIAL, PATH=1,2 or PATH=2,1), the signal is at the 
beacon frequency transmitted from the spacecraft. If a given spacecraft has 
more than one transponder, then there should be unique names specified in 
the ICD for each transponder (e.g., Cassini_S, Cassini_X, Cassini_Ka). If a 
TDM is constructed with only transmit frequencies, then the MODE is 
'SEQUENTIAL' and the PATH keyword defines the signal path. Generally the 
timetag for the TRANSMIT_FREQ_n keywords should be the time that the signal 
was transmitted. For quasar DOR, the TRANSMIT_FREQ_n is the interferometer 
reference frequency at the receive time (thus TIMETAG_REF=RECEIVE for this 
case). If the transmit frequency varies in the TDM segment, then the 
TRANSMIT_FREQ_RATE_n keyword should be used to convey the frequency rate 
between transmit frequencies (see next section); otherwise, the frequency 
rate is assumed to be zero and a step function results. 

3.5.2.9 TRANSMIT_FREQ_RATE_n 
The value associated with the TRANSMIT_FREQ_RATE_n keyword is the linear 
rate of change of the frequency starting at the timetag and continuing until 
the next TRANSMIT_FREQ_RATE timetag (or until the end of the data). The 
units for TRANSMIT_FREQ_RATE_n shall be Hertz-per-second (Hz/s). The value 
shall be a double precision value, and may be negative, zero, or positive. 
If the TRANSMIT_FREQ_RATE_n is not specified, it is assumed to be zero 
(i.e., constant frequency). 

3.5.3 VLBI AND DELTA-DOR RELATED KEYWORDS 
3.5.3.1 Overview 
In VLBI, a signal source is measured simultaneously using two receivers in 
different antenna complexes, achieving a long baseline (up to thousands of 
kilometers). The signals recorded at the two complexes are correlated and 
differenced to produce the observable, which may be further processed by 
navigation software. 'Delta-DOR' sessions are a VLBI application in which 
the antenna slews from a spacecraft source to a quasar source and back to the 
spacecraft during the tracking pass. This sequence may occur multiple times. 
There are two data keywords that relate to VLBI and Delta-DOR measurements, 
and several metadata keyword settings are applicable (MODE=SINGLE_DIFF, 
PATH_1 and PATH_2). 

3.5.3.2 DOR 
The observable associated with the DOR keyword represents the range measured 
via PATH_2 minus the range measured via PATH_1. The timetag is the time of 
signal reception via PATH_1. This data type is normally used for the 
spacecraft observable in a Delta-DOR measurement. The range is either 
one-way, two-way, or three-way, depending on the values of the PARTICIPANT_n 
and PATH keywords. TRANSMIT_FREQ_n shall provide the spacecraft beacon 
frequency if one-way, or the transmit frequency at the uplink station if 
two-way or three-way, at the signal transmission time. The DOR measurement 
shall be a double precision value. Units shall be seconds. 

3.5.3.3 VLBI_DELAY 
The observable associated with the VLBI_DELAY keyword represents the time of 
signal arrival via PATH_2 minus the time of signal arrival via PATH_1. The 
timetag is the time of signal reception via PATH_1. This data type is 
normally used for the quasar observable in a Delta-DOR measurement. 
TRANSMIT_FREQ_n shall provide the interferometer reference frequency. The 
VLBI_DELAY measurement shall be a double precision value. Units shall be 
seconds. 

3.5.4 ANGLE DATA KEYWORDS 
3.5.4.1 General 
Angle data is measured at the ground antenna, using downlink data only, 
regardless of the mode of the tracking session. There shall be two angle 
keywords: ANGLE_1 and ANGLE_2. The ANGLE_TYPE metadata keyword indicates how 
these two keywords should be interpreted. Some TDM users may require that 
the ANGLE_1 keyword is followed immediately by the corresponding ANGLE_2 
keyword; however, this sort is not a general TDM requirement. Special 
sorting requirements should be specified in the ICD. 

3.5.4.2 ANGLE_1 
The value assigned to the ANGLE_1 keyword represents the azimuth, right 
ascension, or 'X' angle of the measurement, depending on the value of the 
ANGLE_TYPE keyword. The angle measurement shall be a double precision value 
as follows: -180.0 <= ANGLE_1 < 360.0. Units shall be degrees.
 
3.5.4.3 ANGLE_2 
The value assigned to the ANGLE_2 keyword represents the elevation, 
declination, or 'Y' angle of the measurement, depending on the value of the 
ANGLE_TYPE keyword. The angle measurement shall be a double precision value 
as follows: -180.0 <= ANGLE_2 < 360.0. Units shall be degrees. 

3.5.5 TIME RELATED KEYWORDS 
3.5.5.1 CLOCK_BIAS 
In general, the timetags provided for the tracking data should be corrected, 
but when that is not possible (e.g., for three-way data or differenced data 
types), then this data type may be used. The CLOCK_BIAS keyword can be used 
by the message recipient to adjust timetag measurements by a specified 
amount with respect to a common reference. For example, the CLOCK_BIAS 
keyword may be used to show the difference between a station clock and UTC 
by setting PARTICIPANT_1 to 'UTC' and PARTICIPANT_2 to the name of the 
station clock. The observable should be calculated as clock#2 minus clock#1, 
consistent with the TDM convention for differenced data. This parameter may 
also be used to express the difference between two station clocks, for 
example, for differenced data including Delta-DOR. The clock bias is stated 
in the data, but the timetags in the message have not been corrected by 
applying the bias; application of the bias is up to the user of the data. 
Normally the time related data such as CLOCK_BIAS data and CLOCK_DRIFT data 
should appear in a dedicated TDM Segment, i.e., not mixed with signal data 
or other data types. The units for CLOCK_BIAS shall be seconds. The value 
shall be a double precision value, and may be positive, zero, or negative. 
The default value shall be 0.0. 

3.5.5.2 CLOCK_DRIFT 
In general, ground-based clocks in tracking stations are sufficiently stable 
that a measurement of the clock drift may not be necessary. However, for 
spacecraft-to-spacecraft exchanges, there may be onboard clock drifts that 
are sufficiently significant that they should be accounted for in the 
measurements and calculations. Drift in clocks may also be an important 
factor when differenced data is being exchanged. The CLOCK_DRIFT keyword 
should be used to adjust timetag measurements by an amount that is a 
function of time with respect to a common reference, normally UTC (as 
opposed to the CLOCK_BIAS, which is meant to be a constant adjustment). Thus 
CLOCK_DRIFT could be used to calculate an interpolated CLOCK_BIAS between 
two timetags, by multiplying the CLOCK_DRIFT measurement at the timetag by 
the number of seconds desired and adding it to the 

CLOCK_BIAS. The drift should be calculated as a drift of clock#2 with 
respect to clock#1, consistent with the TDM convention for differenced data. 
Normally the time related data such as CLOCK_DRIFT data and CLOCK_BIAS data 
should appear in a dedicated TDM Segment, i.e., not mixed with signal data 
or other data types. The units for CLOCK_DRIFT shall be seconds-per-second 
(s/s). The value shall be a double precision value, and may be positive, 
zero, or negative. The default value shall be 0.0. 

3.5.6 MEDIA RELATED KEYWORDS 
3.5.6.1 STEC 
The STEC keyword (Slant Total Electron Count) shall be used to convey the 
line of sight, one way charged particle delay or total electron count (TEC) 
at the timetag associated with a tracking measurement, which is calculated 
by integrating the electron density along the propagation path 
(electrons/m2). The charged particles could have several sources, e.g., solar 
plasma, Earth ionosphere, or the Io plasma torus. The units for the STEC 
keyword are Total Electron Count Units (TECU), where 1 TECU = 1016 
electrons/m2 = 1.661 x 10-8 mol/m2 (SI Units). The value shall be a positive 
double precision value (the TEC along the satellite line of sight may vary 
between 1 and 400 TECU; larger values may be observed during periods of high 
solar activity). This keyword should appear in its own TDM Segment with 
PARTICIPANTs being one spacecraft and one antenna, and a MODE setting of 
'SEQUENTIAL'. Exchange partners who wish to distinguish between ionospheric 
and interplanetary STEC should indicate so in the ICD, and the data must be 
provided in separate TDM Segments. 

3.5.6.2 TROPO_DRY 
The value associated with the TROPO_DRY keyword shall be the dry zenith 
delay through the troposphere measured at the timetag. There should be 
agreed upon elevation mappings for the dry component specified in the ICD 
(e.g., the Niell mapping function developed for VLBI applications). 
Tropospheric corrections should be applied by the recipient of the TDM; the 
required correction is the value associated with this keyword at the timetag. 
Recommended polynomial interpolations (if applicable) should be specified in 
the ICD. The units for TROPO_DRY shall be meters (m). The value shall be a 
non-negative double precision value (0.0 <= TROPO_DRY). 

3.5.6.3 TROPO_WET 
The value associated with the TROPO_WET keyword shall be the wet zenith 
delay through the troposphere measured at the timetag. There should be 
agreed upon elevation mappings for the wet component specified in the ICD 
(e.g., the Niell mapping function developed for VLBI applications). 
Tropospheric corrections should be applied by the recipient of the TDM; the 
required correction is the value associated with this keyword at the timetag. 
Recommended polynomial interpolations (if applicable) should be specified in 
the ICD. The units for TROPO_WET shall be meters (m). The value shall be a 
non-negative double precision value (0.0 <= TROPO_WET). 

3.5.7 METEOROLOGICAL RELATED KEYWORDS 
3.5.7.1 PRESSURE 
The value associated with the PRESSURE keyword shall be the atmospheric 
pressure observable as measured at the tracking participant, specified in 
hectopascal (1 hectopascal (hPa) = 1 millibar). The PRESSURE shall be a 
double precision value; practically speaking it is always positive. 

3.5.7.2 RHUMIDITY 
The value associated with the RHUMIDITY keyword shall be the relative 
humidity observable as measured at the tracking participant, specified in 
percent. RHUMIDITY shall be a double precision type value, 0 <= RHUMIDITY 
<= 100. 

3.5.7.3 TEMPERATURE 
The value associated with the TEMPERATURE keyword shall be the temperature 
observable as measured at the tracking participant, specified in Kelvin (K). 
The TEMPERATURE shall be a positive double precision type value. 

3.5.8 MISCELLANEOUS KEYWORDS 
3.5.8.1 COMMENT 
The COMMENT keyword is not required. See 4.5 for full details on usage of the 
COMMENT keyword. 

3.5.8.2 DATA_START 
The 'DATA_START' keyword must be the first keyword in the Data Section of 
the TDM Segment, which serves to delimit the Data Section. The keyword shall 
appear on a line by itself with no timetags or values. Example: 
'DATA_START'. 

3.5.8.3 DATA_STOP 
The 'DATA_STOP' keyword must be the last keyword in the Data Section of the 
TDM Segment, which serves to delimit the Data Section. The keyword shall 
appear on a line by itself with no timetags or values. Example: 'DATA_STOP'. 


4 TRACKING DATA MESSAGE SYNTAX 

4.1 GENERAL 
The TDM shall observe the syntax described in 4.2 through 4.5. 

4.2 TDM LINES 
4.2.1 The TDM shall consist of a set of TDM lines. The TDM line must contain 
only printable ASCII characters and blanks. ASCII control characters (such 
as TAB, etc.) must not be used, except as indicated below for the 
termination of the TDM line. A TDM line must not exceed 254 ASCII characters 
and spaces (excluding line termination character[s]). 
4.2.2 Each TDM line shall be one of the following: 
- Header line; 
- Metadata Section line; 
- Data Section line; 
- blank line. 
4.2.3 All Header, Metadata Section, and Data Section lines, with exceptions 
as noted below, shall use 'keyword = value' syntax, abbreviated as KVN. 

4.2.4 Only a single 'keyword = value' assignment shall be made on a TDM line. 

4.2.5 The following distinctions in KVN syntax shall apply for TDM lines: 
- TDM lines in the Header and Metadata Section shall consist of a keyword, 
followed by an equals sign '=', followed by a single value assignment. 
Before and after the equals sign, blank characters (white space) may be 
added, but shall not be required. 
- TDM lines in the Data Section shall consist of a keyword, followed by an 
equals sign '=', followed by a value that consists of two primary elements 
(essentially an ordered pair): a timetag and the measurement or calculation 
associated with that timetag (either without the other is unusable for 
tracking purposes). Before and after the equals sign, blank characters 
(white space) may be added. The timetag and measurement/calculation in the 
value must be separated by at least one blank character (white space). 
- The keywords COMMENT, META_START, META_STOP, DATA_START, and DATA_STOP are 
exceptions to the KVN syntax. 

4.2.6 Keywords must be uppercase and must not contain blanks. 

4.2.7 Any white space immediately preceding or following the keyword shall 
not be significant. 

4.2.8 Any white space immediately preceding or following the equals sign '=' 
shall not be significant. 

4.2.9 Any white space immediately preceding the end of line shall not be 
significant. 

4.2.10 Blank lines may be used at any position within the TDM. 

4.2.11 TDM lines shall be terminated by a single Carriage Return or a single 
Line Feed or a Carriage Return/Line Feed pair or a Line Feed/Carriage Return 
pair. 


4.3 TDM VALUES 
4.3.1 A non-empty value field must be specified for each keyword provided. 

4.3.2 Integer values shall consist of a sequence of decimal digits with an 
optional leading sign ('+' or '-'). If the sign is omitted, '+' shall be 
assumed. Leading zeros may be used. The range of values that may be 
expressed as an integer is: -2 147 483 648 <= x <= +2 147 483 647 (i.e., 
-231 <= x <= 231-1). 

4.3.3 Non-integer numeric values may be expressed in either fixed-point or 
floating-point notation. Both representations may be used within a TDM. 

4.3.4 Non-integer numeric values expressed in fixed-point notation shall 
consist of a sequence of decimal digits separated by a period as a decimal 
point indicator, with an optional leading sign ('+' or '-'). If the sign is 
omitted, '+' shall be assumed. Leading and trailing zeros may be used. At 
least one digit shall be used before and after a decimal point. The number 
of digits shall be 16 or fewer. 

4.3.5 Non-integer numeric values expressed in floating-point notation shall 
consist of a sign, a mantissa, an alphabetic character indicating the 
division between the mantissa and exponent, and an exponent, constructed 
according to the following rules: 
- The sign may be '+' or '-'. If the sign is omitted, '+' shall be assumed. 
- The mantissa must be a string of no more than 16 decimal digits with a 
decimal point '.' in the second position of the ASCII string, separating the 
integer portion of the mantissa from the fractional part of the mantissa. 
- The character used to denote exponentiation shall be 'E' or 'e'. If the 
character indicating the exponent and the following exponent are omitted, an 
exponent value of zero shall be assumed (essentially yielding a fixed-point 
value). 
- The exponent must be an integer, and may have either a '+' or '-' sign (if 
the sign is omitted, then '+' is assumed). 
- The maximum positive floating-point value is approximately 1.798E+308, 
with 16 significant decimal digits precision. The minimum positive 
floating-point value is approximately 4.94E-324, with 16 significant decimal 
digits precision. 
NOTE - These specifications for integer, fixed-point, and floating-point 
values conform to the XML specifications for the data types four-byte 
integer 'xsd:int', 'decimal', and 'double', respectively (see reference 
[6]). The specifications for floating-point values conform to the IEEE 754 \
double precision type (see reference [7]). 
Floating-point numbers in IEEE extended-single or IEEE extended-double 
precision may be represented, but do require an ICD between participating 
agencies because of their implementation specific attributes. The special 
values 'NaN', '-Inf', '+Inf', and '-0' are not supported in the TDM. 

4.3.6 Blanks shall not be permitted within numeric values and time values. 

4.3.7 Text value fields may be constructed using mixed case; case shall not 
be significant. 

4.3.8 In value fields that are text, an underscore shall be equivalent to a 
single blank. 

Individual blanks between non-blank characters shall be retained (shall be 
significant) but multiple blanks shall be equivalent to a single blank. 

4.3.9 In value fields that represent a timetag or epoch, one of the 
following two formats shall be used: 
YYYY-MM-DDThh:mm:ss[.d.d][Z] 

or 

YYYY-DDDThh:mm:ss[.d.d][Z] 

where 'YYYY' is the year, 'MM' is the two-digit month, 'DD' is the two-digit 
day, 'DDD' is the three-digit day of year, 'T' is constant, 'hh:mm:ss[.d.d]' 
is the time in hours, minutes seconds, and optional fractional seconds; 'Z' 
is an optional time code terminator (the only permitted value is 'Z' for 
Zulu, i.e., UTC). All fields shall have leading zeros. See reference [3], 
ASCII Time Code A and B. 

4.3.10 There are four types of TDM values that represent a timetag or epoch, 
as shown in the applicable tables. The time system for the CREATION_DATE, 
START_TIME, and STOP_TIME shall be UTC. The time system for the timetags in 
the TDM Data Section shall be determined by the TIME_SYSTEM metadata keyword. 
4.4 UNITS IN THE TDM 
Units are not explicitly displayed in the TDM. The units associated with 
values in the TDM are as specified in table 3-5. 


4.5 COMMENTS IN A TDM 
4.5.1 Comments may be used to provide any pertinent information associated 
with the data that is not covered via one of the keywords. This additional 
information is intended to aid in consistency checks and elaboration where 
needed. Comments shall not be required for successful processing of a TDM; 
i.e., comment lines shall be optional. 
NOTE - 
Given that TDMs may consist of large amounts of data, and are generally 
produced via automation, using the COMMENT feature of the TDM may have 
limited usefulness. On the other hand, a simple utility could be developed 
to search for and extract all the comments in a TDM to make them easily 
reviewable. Existing built-in utilities (e.g., UNIX 'grep') or 'freeware' 
utilities could also be used for this purpose. 

4.5.2 Comment lines, if used, shall only occur: 
- at the beginning of the TDM Header (i.e., between the CCSDS_TDM_VERS 
keyword and the CREATION_DATE keyword, as shown in table 3-2); 
- at the beginning of the TDM Metadata Section (i.e., between the META_START 
keyword and the TIME_SYSTEM keyword, as shown in table 3-3); 
- at the beginning of the TDM Data Section (i.e., between the 'DATA_START' 
keyword and the first Tracking Data Record). 

4.5.3 All comment lines shall begin with the 'COMMENT' keyword followed by 
at least one space (note: may also be preceded by spaces). The 'COMMENT' 
keyword must appear on every comment line, not just the first comment line. 
After the keyword, the remainder of the line shall be the comment value. 
White space shall be retained (is significant) in comment values. 

4.5.4 Conventions for particular comments in the TDM that may be required 
between any two participating agencies should be specified in the ICD. 

4.5.5 Descriptions of any ancillary data that cannot be accommodated via 
keywords in the TDM may have to be specified via comments, and should be 
outlined in the ICD. 


5 SECURITY 

5.1 OVERVIEW 
This section presents the results of an analysis of security considerations 
applied to the technologies specified in this Recommended Standard. 

5.2 SECURITY CONCERNS RELATED TO THIS RECOMMENDED STANDARD 
5.2.1 DATA PRIVACY 
Privacy of data formatted in compliance with the specifications of this 
Recommended Standard should be assured by the systems and networks on which 
this Recommended Standard is implemented. 

5.2.2 DATA INTEGRITY 
Integrity of data formatted in compliance with the specifications of this 
Recommended Standard should be assured by the systems and networks on which 
this Recommended Standard is implemented. 

5.2.3 AUTHENTICATION OF COMMUNICATING ENTITIES 
Authentication of communicating entities involved in the transport of data 
which complies with the specifications of this Recommended Standard should 
be provided by the systems and networks on which this Recommended Standard 
is implemented. 

5.2.4 DATA TRANSFER BETWEEN COMMUNICATING ENTITIES 
The transfer of data formatted in compliance with this Recommended Standard 
between communicating entities should be accomplished via secure mechanisms 
approved by the IT Security functionaries of exchange participants. 

5.2.5 CONTROL OF ACCESS TO RESOURCES 
This Recommended Standard assumes that control of access to resources will be 
managed by the systems upon which provider formatting and recipient 
processing are performed. 

5.2.6 AUDITING OF RESOURCE USAGE 
This Recommended Standard assumes that auditing of resource usage will be 
handled by the management of systems and networks on which this Recommended 
Standard is implemented. 


5.3 POTENTIAL THREATS AND ATTACK SCENARIOS 
There are no certain threats or attack scenarios that apply specifically to 
the technologies specified in this Recommended Standard. Potential threats 
or attack scenarios applicable to the systems and networks on which this 
Recommended Standard is implemented should be addressed by the management of 
those systems and networks. Protection from unauthorized access is 
especially important if the mission utilizes open ground networks such as 
the Internet to provide ground station connectivity for the exchange of data 
formatted in compliance with this Recommended Standard. 

5.4 CONSEQUENCES OF NOT APPLYING SECURITY TO THE TECHNOLOGY 
There are no known consequences of not applying security to the technologies 
specified in this Recommended Standard. The consequences of not applying 
security to the systems and networks on which this Recommended Standard is 
implemented could include potential loss, corruption, and theft of data. 

5.5 DATA SECURITY IMPLEMENTATION SPECIFICS 
Specific information-security interoperability provisions that may apply 
between agencies involved in an exchange of data formatted in compliance 
with this Recommended Standard should be specified in an ICD. 


ANNEX A 
VALUES FOR TIME_SYSTEM AND REFERENCE_FRAME 
(NORMATIVE) 

The values in this annex represent the set of acceptable values for the 
TIME_SYSTEM and REFERENCE_FRAME keywords. For details and description of 
these time systems, see reference [1]. If exchange partners wish to use 
different settings, they should be documented in the ICD. 

A1 TIME_SYSTEM METADATA KEYWORD 

Time System Value Meaning 
GMST Greenwich Mean Sidereal Time 
GPS Global Positioning System 
SCLK Spacecraft Clock (receiver) 
TAI International Atomic Time 
TCB Barycentric Coordinated Time 
TDB Barycentric Dynamical Time 
TT Terrestrial Time 
UT1 Universal Time 
UTC Coordinated Universal Time 
 
 
Reference Frame 
Value 
Meaning 
EME2000 Earth Mean Equator and Equinox of J2000 
ICRF International Celestial Reference Frame 
ITRF2000 International Terrestrial Reference Frame 2000 
ITRF-93 International Terrestrial Reference Frame 1993 
ITRF-97 International Terrestrial Reference Frame 1997 
TOD True of Date 


ANNEX B 

ITEMS FOR AN INTERFACE CONTROL DOCUMENT 
(INFORMATIVE) 

In several places in this document there are references to items which 
should be specified in an Interface Control Document (ICD) between agencies 
participating in an exchange of tracking data, if they are applicable to the 
particular exchange. The ICD should be jointly produced by both Agencies 
participating in a cross-support activity involving the collection, 
analysis, and transfer of tracking data. This section compiles those items 
into a single location. 

The greater the amount of material specified via ICD, the lesser the 
utility/benefit of the TDM (custom programming may be required to tailor 
software for each ICD). It is suggested to avoid a large number of items 
specified via ICD, to ensure full utility/benefit of the TDM. 

From an implementation standpoint, it is probable that many of the items 
that need to be negotiated via ICD will be introduced into the system that 
processes tracking data via one or more configuration files that specify the 
settings of specific, related parameters that will be used during the 
tracking session, for example, the name of the time system to be used for 
the tracking data. This may vary between exchange participants. Different 
versions of programs could be used to prepare the tracking data where these 
parameters differ; however, a more efficient design would be to have a 
single program that is configured based on tracking pass-specific 
information. It seems likely that there may be at least two configuration 
files necessary, one which contains Agency-specific parameters that do not 
change between tracking passes, and one which contains 
spacecraft/mission-specific parameters that could change with every tracking 
pass. 

Another thought on ICDs is that it might be feasible for participating 
agencies to have a generic baseline ICD ('standard service provider ICD') 
that specifies mission/spacecraftindependent entities on the interface, 
e.g., those associated with the agency's ground antennas (axis offsets, 
station locations, side motions, reference frame, epoch, supported frequency 
bands, etc.). Then smaller ICDs could be used for the 
mission/spacecraft-specific arrangements. 

The following table lists the items that should be covered in an ICD, along 
with where they are discussed in the text: 


See PDF version of document for table.


ANNEX C 
ABBREVIATIONS AND ACRONYMS 
(INFORMATIVE) 

ADM Attitude Data Message 
ASCII American Standard Code for Information Interchange 
AZEL Azimuth-Elevation 
CCIR International Coordinating Committee for Radio Frequencies 
CCSDS Consultative Committee for Space Data Systems 
Delta-DOR Delta Differential One-Way Ranging 
DOR Differential One-Way Ranging 
DORIS Doppler Orbitography and Radiopositioning Integrated by Satellite 
GNSS Global Navigation Satellite System 
GPS Global Positioning System 
ICD Interface Control Document 
ICRF International Celestial Reference Frame 
IEEE Institute of Electrical and Electronics Engineers 
IEC International Electrotechnical Commission 
ISO International Organization for Standardization 
K Kelvin 
KVN Keyword = Value Notation 
LIDAR Light Detection and Ranging 
MOIMS Mission Operations and Information Management Services 
N/A or n/a Not Applicable / Not Available 
ODM Orbit Data Message 
OEM Orbit Ephemeris Message 
OPM Orbit Parameter Message 
Pc/No Carrier Power to Noise Spectral Density ratio 
Pr/No Ranging Power to Noise Spectral Density ratio 
PRARE Precise Range and Range Rate Equipment 
RADEC Right Ascension-Declination 
RINEX Receiver Independent Exchange 
RTLT Round-Trip Light Time 
SANA Space Assigned Numbers Authority 
SCLK Spacecraft Clock 
SFTP Secure File Transfer Protocol 
SLR Satellite Laser Ranging 
TDM Tracking Data Message 
TEC Total Electron Count 
TECU Total Electron Count Units 
UTC Coordinated Universal Time 
VLBI Very Long Baseline Interferometry 
XEYN X:East, Y:North 
XSYE X:South, Y:East 
XML eXtensible Markup Language 


ANNEX D 
EXAMPLE TRACKING DATA MESSAGES 
(INFORMATIVE) 

CCSDS_TDM_VERS = 1.0 

COMMENT TDM example created by yyyyy-nnnA Nav Team (NASA/JPL)
COMMENT StarTrek 1-way data, Ka band down 

CREATION_DATE = 2005-160T20:15:00Z 
ORIGINATOR = NASA/JPL 

META_START 
COMMENT Data quality degraded by antenna pointing problem...
COMMENT Slightly noisy dataTIME_SYSTEM = UTC 
PARTICIPANT_1 = DSS-25 
PARTICIPANT_2 = yyyy-nnnAMODE = SEQUENTIALPATH = 2,1INTEGRATION_INTERVAL = 1 
INTEGRATION_REF = MIDDLE 
FREQ_OFFSET = 0TRANSMIT_DELAY_1 = 0.000077 
RECEIVE_DELAY_1 = 0.000077 
DATA_QUALITY = DEGRADEDMETA_STOP 

DATA_START 
COMMENT TRANSMIT_FREQ_2 is spacecraft reference 
downlinkTRANSMIT_FREQ_2 = 2005-159T17:41:00 32023442781.733 
RECEIVE_FREQ_1 = 2005-159T17:41:00 32021034790.7265 
RECEIVE_FREQ_1 = 2005-159T17:41:01 32021034828.8432 
RECEIVE_FREQ_1 = 2005-159T17:41:02 32021034866.9449 
RECEIVE_FREQ_1 = 2005-159T17:41:03 32021034905.0327 
RECEIVE_FREQ_1 = 2005-159T17:41:04 32021034943.0946 
RECEIVE_FREQ_1 = 2005-159T17:41:05 32021034981.2049 
RECEIVE_FREQ_1 = 2005-159T17:41:06 32021035019.2778 
RECEIVE_FREQ_1 = 2005-159T17:41:07 32021035057.3773 
RECEIVE_FREQ_1 = 2005-159T17:41:08 32021035095.4377 
RECEIVE_FREQ_1 = 2005-159T17:41:09 32021035133.5604 
RECEIVE_FREQ_1 = 2005-159T17:41:10 32021035171.5861 
RECEIVE_FREQ_1 = 2005-159T17:41:11 32021035209.6653 
RECEIVE_FREQ_1 = 2005-159T17:41:12 32021035247.7804 
RECEIVE_FREQ_1 = 2005-159T17:41:13 32021035285.8715 
RECEIVE_FREQ_1 = 2005-159T17:41:14 32021035323.8187 
RECEIVE_FREQ_1 = 2005-159T17:41:15 32021035361.9571 
RECEIVE_FREQ_1 = 2005-159T17:41:16 32021035400.0304 
RECEIVE_FREQ_1 = 2005-159T17:41:17 32021035438.0126 
RECEIVE_FREQ_1 = 2005-159T17:41:18 32021035476.1241 
RECEIVE_FREQ_1 = 2005-159T17:41:19 32021035514.1714 
RECEIVE_FREQ_1 = 2005-159T17:41:20 32021035552.2263 
RECEIVE_FREQ_1 = 2005-159T17:41:21 32021035590.2671 
RECEIVE_FREQ_1 = 2005-159T17:41:22 32021035628.304 
RECEIVE_FREQ_1 = 2005-159T17:41:23 32021035666.3579 
RECEIVE_FREQ_1 = 2005-159T17:41:24 32021035704.3745 
RECEIVE_FREQ_1 = 2005-159T17:41:25 32021035742.4425 
RECEIVE_FREQ_1 = 2005-159T17:41:26 32021035780.4974 
RECEIVE_FREQ_1 = 2005-159T17:41:27 32021035818.5158 
RECEIVE_FREQ_1 = 2005-159T17:41:28 32021035856.5721 
RECEIVE_FREQ_1 = 2005-159T17:41:29 32021035894.5601 
DATA_STOP 

Figure D-1: TDM Example: One-Way Data 


CCSDS_TDM_VERS = 1.0 

COMMENT TDM example created by yyyyy-nnnA Nav Team (NASA/JPL)
COMMENT StarTrek 1-way data, Ka band down 

CREATION_DATE = 2005-160T20:15:00 
ORIGINATOR = NASA/JPL 

META_START 
TIME_SYSTEM = UTC 
START_TIME = 2005-159T17:41:00 
STOP_TIME = 2005-159T17:41:40 
PARTICIPANT_1 = DSS-25 
PARTICIPANT_2 = yyyy-nnnAMODE = SEQUENTIALPATH = 2,1INTEGRATION_INTERVAL = 
1.0 
INTEGRATION_REF = MIDDLE 
FREQ_OFFSET = 32021035200.0TRANSMIT_DELAY_1 = 0.000077 
RECEIVE_DELAY_1 = 0.000077 
DATA_QUALITY = RAWMETA_STOP 

DATA_START 
TRANSMIT_FREQ_2 = 2005-159T17:41:00 32023442781.733 
RECEIVE_FREQ_1 = 2005-159T17:41:00 -409.2735 
RECEIVE_FREQ_1 = 2005-159T17:41:01 -371.1568 
RECEIVE_FREQ_1 = 2005-159T17:41:02 -333.0551 
RECEIVE_FREQ_1 = 2005-159T17:41:03 -294.9673 
RECEIVE_FREQ_1 = 2005-159T17:41:04 -256.9054 
RECEIVE_FREQ_1 = 2005-159T17:41:05 -218.7951 
RECEIVE_FREQ_1 = 2005-159T17:41:06 -180.7222 
RECEIVE_FREQ_1 = 2005-159T17:41:07 -142.6227 
RECEIVE_FREQ_1 = 2005-159T17:41:08 -104.5623 
RECEIVE_FREQ_1 = 2005-159T17:41:09 -66.4396 
RECEIVE_FREQ_1 = 2005-159T17:41:10 -28.4139 
RECEIVE_FREQ_1 = 2005-159T17:41:11 9.6653 
RECEIVE_FREQ_1 = 2005-159T17:41:12 47.7804 
RECEIVE_FREQ_1 = 2005-159T17:41:13 85.8715 
RECEIVE_FREQ_1 = 2005-159T17:41:14 123.8187 
RECEIVE_FREQ_1 = 2005-159T17:41:15 161.9571 
RECEIVE_FREQ_1 = 2005-159T17:41:16 200.0304 
RECEIVE_FREQ_1 = 2005-159T17:41:17 238.0126 
RECEIVE_FREQ_1 = 2005-159T17:41:18 276.1241 
RECEIVE_FREQ_1 = 2005-159T17:41:19 314.1714 
RECEIVE_FREQ_1 = 2005-159T17:41:20 352.2263 
RECEIVE_FREQ_1 = 2005-159T17:41:21 390.2671 
RECEIVE_FREQ_1 = 2005-159T17:41:22 428.3040 
RECEIVE_FREQ_1 = 2005-159T17:41:23 466.3579 
RECEIVE_FREQ_1 = 2005-159T17:41:24 504.3745 
RECEIVE_FREQ_1 = 2005-159T17:41:25 542.4425 
RECEIVE_FREQ_1 = 2005-159T17:41:26 580.4974 
RECEIVE_FREQ_1 = 2005-159T17:41:27 618.5158 
RECEIVE_FREQ_1 = 2005-159T17:41:28 656.5721 
RECEIVE_FREQ_1 = 2005-159T17:41:29 694.5601 
RECEIVE_FREQ_1 = 2005-159T17:41:30 732.5939 
RECEIVE_FREQ_1 = 2005-159T17:41:31 770.6275 
RECEIVE_FREQ_1 = 2005-159T17:41:32 808.6377 
RECEIVE_FREQ_1 = 2005-159T17:41:33 846.6657 
RECEIVE_FREQ_1 = 2005-159T17:41:34 884.6911 
RECEIVE_FREQ_1 = 2005-159T17:41:35 922.6890 
RECEIVE_FREQ_1 = 2005-159T17:41:36 960.7083 
RECEIVE_FREQ_1 = 2005-159T17:41:37 998.7493 
RECEIVE_FREQ_1 = 2005-159T17:41:38 1036.7388 
RECEIVE_FREQ_1 = 2005-159T17:41:39 1074.7529 
RECEIVE_FREQ_1 = 2005-159T17:41:40 1112.7732 
DATA_STOP 

Figure D-2: TDM Example: One-Way Data w/Frequency Offset 


CCSDS_TDM_VERS=1.0 
COMMENT TDM example created by yyyyy-nnnA Nav Team (NASA/JPL)
CREATION_DATE=2005-184T20:15:00 
ORIGINATOR=NASA/JPLMETA_START 
TIME_SYSTEM=UTC 
START_TIME=2005-184T11:12:23 
STOP_TIME=2005-184T13:59:43.27 
PARTICIPANT_1=DSS-55 
PARTICIPANT_2=yyyy-nnnAMODE=SEQUENTIALPATH=1,2,1INTEGRATION_INTERVAL=1.0 
INTEGRATION_REF=MIDDLE 
FREQ_OFFSET=0.0META_STOP 
DATA_START 
TRANSMIT_FREQ_1=2005-184T11:12:23 7175173383.615373 
TRANSMIT_FREQ_RATE_1=2005-184T11:12:23 0.40220 
TRANSMIT_FREQ_1=2005-184T11:12:24 7175173384.017573 
TRANSMIT_FREQ_RATE_1=2005-184T11:12:24 0.40220 
TRANSMIT_FREQ_1=2005-184T11:12:25 7175173384.419773 
TRANSMIT_FREQ_RATE_1=2005-184T11:12:25 0.40220 
TRANSMIT_FREQ_1=2005-184T11:12:26 7175173384.821973 
TRANSMIT_FREQ_RATE_1=2005-184T11:12:26 0.40220 
TRANSMIT_FREQ_1=2005-184T11:12:27 7175173385.224173 
TRANSMIT_FREQ_RATE_1=2005-184T11:12:27 0.40220 
TRANSMIT_FREQ_1=2005-184T11:12:28 7175173385.626373 
TRANSMIT_FREQ_RATE_1=2005-184T11:12:28 0.40220 
TRANSMIT_FREQ_1=2005-184T11:12:29 7175173386.028573 
TRANSMIT_FREQ_RATE_1=2005-184T11:12:29 0.40220 
TRANSMIT_FREQ_1=2005-184T11:12:30 7175173386.430773 
TRANSMIT_FREQ_RATE_1=2005-184T11:12:30 0.40220 
TRANSMIT_FREQ_1=2005-184T11:12:31 7175173386.832973 
TRANSMIT_FREQ_RATE_1=2005-184T11:12:31 0.40220 
TRANSMIT_FREQ_1=2005-184T11:12:32 7175173387.235173 
TRANSMIT_FREQ_RATE_1=2005-184T11:12:32 0.40220 
TRANSMIT_FREQ_1=2005-184T11:12:33 7175173387.637373 
TRANSMIT_FREQ_RATE_1=2005-184T11:12:33 0.40220 
TRANSMIT_FREQ_1=2005-184T11:12:34 7175173388.039573 
TRANSMIT_FREQ_RATE_1=2005-184T11:12:34 0.40220 
TRANSMIT_FREQ_1=2005-184T11:12:35 7175173388.441773 
TRANSMIT_FREQ_RATE_1=2005-184T11:12:35 0.40220 
TRANSMIT_FREQ_1=2005-184T11:12:36 7175173388.843973 
TRANSMIT_FREQ_RATE_1=2005-184T11:12:36 0.40220 
TRANSMIT_FREQ_1=2005-184T11:12:37 7175173389.246173 
TRANSMIT_FREQ_RATE_1=2005-184T11:12:37 0.40220 
TRANSMIT_FREQ_1=2005-184T11:12:38 7175173389.648373 
TRANSMIT_FREQ_RATE_1=2005-184T11:12:38 0.40220 
TRANSMIT_FREQ_1=2005-184T11:12:39 7175173390.050573 
RECEIVE_FREQ_1=2005-184T13:59:27.27 8429753135.986102 
RECEIVE_FREQ_1=2005-184T13:59:28.27 8429749428.196568 
RECEIVE_FREQ_1=2005-184T13:59:29.27 8429749427.584727 
RECEIVE_FREQ_1=2005-184T13:59:30.27 8429749427.023103 
RECEIVE_FREQ_1=2005-184T13:59:31.27 8429749426.346252 
RECEIVE_FREQ_1=2005-184T13:59:32.27 8429749425.738658 
RECEIVE_FREQ_1=2005-184T13:59:33.27 8429749425.113143 
RECEIVE_FREQ_1=2005-184T13:59:34.27 8429749424.489933 
RECEIVE_FREQ_1=2005-184T13:59:35.27 8429749423.876996 
RECEIVE_FREQ_1=2005-184T13:59:36.27 8429749423.325228 
RECEIVE_FREQ_1=2005-184T13:59:37.27 8429749422.664049 
RECEIVE_FREQ_1=2005-184T13:59:38.27 8429749422.054996 
RECEIVE_FREQ_1=2005-184T13:59:39.27 8429749421.425801 
RECEIVE_FREQ_1=2005-184T13:59:40.27 8429749420.824186 
RECEIVE_FREQ_1=2005-184T13:59:41.27 8429749420.204178 
RECEIVE_FREQ_1=2005-184T13:59:42.27 8429749419.596043 
RECEIVE_FREQ_1=2005-184T13:59:43.27 8429749418.986191 
DATA_STOP 

Figure D-3: TDM Example: Two-Way Frequency Data for Doppler Calculation 


CCSDS_TDM_VERS = 1.0 
COMMENT TDM example created by yyyyy-nnnA Nav Team (NASA/JPL)
CREATION_DATE = 2005-191T23:00:00 
ORIGINATOR = NASA/JPL

META_START 
COMMENT Range correction applied is range calibration to DSS-24.
COMMENT Estimated RTLT at begin of pass = 950 secondsCOMMENT Antenna 
Z-height correction 0.0545 km applied to uplink signalCOMMENT Antenna 
Z-height correction 0.0189 km applied to downlink signalTIME_SYSTEM = UTC 
PARTICIPANT_1 = DSS-24 
PARTICIPANT_2 = yyyy-nnnAMODE = SEQUENTIALPATH = 1,2,1

INTEGRATION_REF = START 
RANGE_MODE = COHERENT 
RANGE_MODULUS = 2.0e+26 
RANGE_UNITS = RU 
TRANSMIT_DELAY_1 = 7.7e-5 
TRANSMIT_DELAY_2 = 0.0 
RECEIVE_DELAY_1 = 7.7e-5 
RECEIVE_DELAY_2 = 0.0 
CORRECTION_RANGE = 46.7741 
CORRECTIONS_APPLIED = YES 


META_STOP 

DATA_START 
TRANSMIT_FREQ_1 = 2005-191T00:31:51 7180064367.3536 
TRANSMIT_FREQ_RATE_1 = 2005-191T00:31:51 0.59299 
RANGE = 2005-191T00:31:51 39242998.5151986 
PR_N0 = 2005-191T00:31:51 28.52538 
TRANSMIT_FREQ_1 = 2005-191T00:34:48 7180064472.3146 
TRANSMIT_FREQ_RATE_1 = 2005-191T00:34:48 0.59305 
RANGE = 2005-191T00:34:48 61172265.3115234 
PR_N0 = 2005-191T00:34:48 28.39347 
TRANSMIT_FREQ_1 = 2005-191T00:37:45 7180064577.2756 
TRANSMIT_FREQ_RATE_1 = 2005-191T00:37:45 0.59299 
RANGE = 2005-191T00:37:45 15998108.8168328 
PR_N0 = 2005-191T00:37:45 28.16193 
TRANSMIT_FREQ_1 = 2005-191T00:40:42 7180064682.2366 
TRANSMIT_FREQ_RATE_1 = 2005-191T00:40:42 0.59299 
RANGE = 2005-191T00:40:42 37938284.4138008 
PR_N0 = 2005-191T00:40:42 29.44597 
TRANSMIT_FREQ_1 = 2005-191T00:43:39 7180064787.1976 
TRANSMIT_FREQ_RATE_1 = 2005-191T00:43:39 0.60774 
RANGE = 2005-191T00:43:39 59883968.0697146 
PR_N0 = 2005-191T00:43:39 27.44037 
TRANSMIT_FREQ_1 = 2005-191T00:46:36 7180064894.77345 
TRANSMIT_FREQ_RATE_1 = 2005-191T00:46:36 0.60989 
RANGE = 2005-191T00:46:36 14726355.3958799 
PR_N0 = 2005-191T00:46:36 27.30462 
TRANSMIT_FREQ_1 = 2005-191T00:49:33 7180065002.72044 
TRANSMIT_FREQ_RATE_1 = 2005-191T00:49:33 0.60989 
RANGE = 2005-191T00:49:33 36683224.3750253 
PR_N0 = 2005-191T00:49:33 28.32537 
TRANSMIT_FREQ_1 = 2005-191T00:52:30 7180065110.66743 
TRANSMIT_FREQ_RATE_1 = 2005-191T00:52:30 0.60983 
RANGE = 2005-191T00:52:30 58645699.4734682 
PR_N0 = 2005-191T00:52:30 29.06158 
TRANSMIT_FREQ_1 = 2005-191T00:55:27 7180065218.61442 
TRANSMIT_FREQ_RATE_1 = 2005-191T00:49:33 0.60989 
RANGE = 2005-191T00:55:27 13504948.3585422 
PR_N0 = 2005-191T00:55:27 27.29589 
TRANSMIT_FREQ_1 = 2005-191T00:58:24 7180065326.56141 
TRANSMIT_FREQ_RATE_1 = 2005-191T00:49:33 0.62085 
RANGE = 2005-191T00:58:24 35478729.4012973 
PR_N0 = 2005-191T00:58:24 30.48199 
TRANSMIT_FREQ_1 = 2005-191T01:01:21 7180065436.45167 
RANGE = 2005-191T01:01:21 57458219.0681689 
PR_N0 = 2005-191T01:01:21 27.15509 

DATA_STOP 

Figure D-4: TDM Example: Two-Way Ranging Data Only 


CCSDS_TDM_VERS = 1.0 

COMMENT TDM example created by yyyyy-nnnA Nav Team (NASA/JPL) 

CREATION_DATE = 2005-184T20:15:00 
ORIGINATOR = NASA/JPL 

META_START 
TIME_SYSTEM = UTC 
START_TIME = 2005-184T11:12:23 
STOP_TIME = 2005-184T13:59:40.27 
PARTICIPANT_1 = DSS-55 
PARTICIPANT_2 = yyyy-nnnAPARTICIPANT_3 = DSS-15 
MODE = SEQUENTIALPATH = 1,2,3INTEGRATION_INTERVAL = 1.0 
INTEGRATION_REF = MIDDLE 
META_STOP 

DATA_START 
TRANSMIT_FREQ_1 = 2005-184T11:12:23 7175173383.615373 
TRANSMIT_FREQ_RATE_1 = 2005-184T11:12:23 0.40220 
RECEIVE_FREQ_3 = 2005-184T13:59:27.27 8429753135.986102 
TRANSMIT_FREQ_1 = 2005-184T11:12:24 7175173384.017573 
TRANSMIT_FREQ_RATE_1 = 2005-184T11:12:23 0.40220 
RECEIVE_FREQ_3 = 2005-184T13:59:28.27 8429749428.196568 
TRANSMIT_FREQ_1 = 2005-184T11:12:25 7175173384.419773 
TRANSMIT_FREQ_RATE_1 = 2005-184T11:12:23 0.40220 
RECEIVE_FREQ_3 = 2005-184T13:59:29.27 8429749427.584727 
TRANSMIT_FREQ_1 = 2005-184T11:12:26 7175173384.821973 
TRANSMIT_FREQ_RATE_1 = 2005-184T11:12:23 0.40220 
RECEIVE_FREQ_3 = 2005-184T13:59:30.27 8429749427.023103 
TRANSMIT_FREQ_1 = 2005-184T11:12:27 7175173385.224173 
TRANSMIT_FREQ_RATE_1 = 2005-184T11:12:23 0.40220 
RECEIVE_FREQ_3 = 2005-184T13:59:31.27 8429749426.346252 
TRANSMIT_FREQ_1 = 2005-184T11:12:28 7175173385.626373 
TRANSMIT_FREQ_RATE_1 = 2005-184T11:12:23 0.40220 
RECEIVE_FREQ_3 = 2005-184T13:59:32.27 8429749425.738658 
TRANSMIT_FREQ_1 = 2005-184T11:12:29 7175173386.028573 
TRANSMIT_FREQ_RATE_1 = 2005-184T11:12:23 0.40220 
RECEIVE_FREQ_3 = 2005-184T13:59:33.27 8429749425.113143 
TRANSMIT_FREQ_1 = 2005-184T11:12:30 7175173386.430773 
TRANSMIT_FREQ_RATE_1 = 2005-184T11:12:23 0.40220 
RECEIVE_FREQ_3 = 2005-184T13:59:34.27 8429749424.489933 
TRANSMIT_FREQ_1 = 2005-184T11:12:31 7175173386.832973 
TRANSMIT_FREQ_RATE_1 = 2005-184T11:12:23 0.40220 
RECEIVE_FREQ_3 = 2005-184T13:59:35.27 8429749423.876996 
TRANSMIT_FREQ_1 = 2005-184T11:12:32 7175173387.235173 
TRANSMIT_FREQ_RATE_1 = 2005-184T11:12:23 0.40220 
RECEIVE_FREQ_3 = 2005-184T13:59:36.27 8429749423.325228 
TRANSMIT_FREQ_1 = 2005-184T11:12:33 7175173387.637373 
TRANSMIT_FREQ_RATE_1 = 2005-184T11:12:23 0.40220 
RECEIVE_FREQ_3 = 2005-184T13:59:37.27 8429749422.664049 
TRANSMIT_FREQ_1 = 2005-184T11:12:34 7175173388.039573 
TRANSMIT_FREQ_RATE_1 = 2005-184T11:12:23 0.40220 
RECEIVE_FREQ_3 = 2005-184T13:59:38.27 8429749422.054996 
TRANSMIT_FREQ_1 = 2005-184T11:12:35 7175173388.441773 
TRANSMIT_FREQ_RATE_1 = 2005-184T11:12:23 0.40220 
RECEIVE_FREQ_3 = 2005-184T13:59:39.27 8429749421.425801 
TRANSMIT_FREQ_1 = 2005-184T11:12:36 7175173388.843973 
TRANSMIT_FREQ_RATE_1 = 2005-184T11:12:23 0.40220 
RECEIVE_FREQ_3 = 2005-184T13:59:40.27 8429749420.824186 
DATA_STOP 

Figure D-5: TDM Example: Three-Way Frequency Data 


CCSDS_TDM_VERS = 1.0 
COMMENT TDM example created by yyyyy-nnnA Nav Team (JAXA)
CREATION_DATE = 1998-06-10T01:00:00 
ORIGINATOR = JAXA 

META_START 
TIME_SYSTEM = UTC 
START_TIME = 1998-06-10T00:57:37 
STOP_TIME = 1998-06-10T00:57:44 
PARTICIPANT_1 = NORTH 
PARTICIPANT_2 = F07R07 
PARTICIPANT_3 = E7 
MODE = SEQUENTIALPATH = 1,2,3,2,1INTEGRATION_INTERVAL = 1.0 
INTEGRATION_REF = MIDDLE 
RANGE_MODE = CONSTANT 
RANGE_MODULUS = 0 
RANGE_UNITS = km 
ANGLE_TYPE = AZEL 
META_STOP 

DATA_START 
RANGE = 1998-06-10T00:57:37 80452.7542 
ANGLE_1 = 1998-06-10T00:57:37 256.64002393 
ANGLE_2 = 1998-06-10T00:57:37 13.38100016 
TRANSMIT_FREQ_1 = 1998-06-10T00:57:37 2106395199.07917 
RECEIVE_FREQ = 1998-06-10T00:57:37 2287487999.0 

RANGE = 1998-06-10T00:57:38 80452.7368 
ANGLE_1 = 1998-06-10T00:57:38 256.64002393 
ANGLE_2 = 1998-06-10T00:57:38 13.38100016 
TRANSMIT_FREQ_1 = 1998-06-10T00:57:38 2106395199.07917 
RECEIVE_FREQ = 1998-06-10T00:57:38 2287487999.0 

RANGE = 1998-06-10T00:57:39 80452.7197 
ANGLE_1 = 1998-06-10T00:57:39 256.64002393 
ANGLE_2 = 1998-06-10T00:57:39 13.38100016 
TRANSMIT_FREQ_1 = 1998-06-10T00:57:39 2106395199.07917 
RECEIVE_FREQ = 1998-06-10T00:57:39 2287487999.0 

RANGE = 1998-06-10T00:57:40 80452.7025 
ANGLE_1 = 1998-06-10T00:57:40 256.64002393 
ANGLE_2 = 1998-06-10T00:57:40 13.38100016 
TRANSMIT_FREQ_1 = 1998-06-10T00:57:40 2106395199.07917 
RECEIVE_FREQ = 1998-06-10T00:57:40 2287487999.0 

RANGE = 1998-06-10T00:57:41 80452.6854 
ANGLE_1 = 1998-06-10T00:57:41 256.64002393 
ANGLE_2 = 1998-06-10T00:57:41 13.38100016 
TRANSMIT_FREQ_1 = 1998-06-10T00:57:41 2106395199.07917 
RECEIVE_FREQ = 1998-06-10T00:57:41 2287487999.0 

RANGE = 1998-06-10T00:57:42 80452.6680 
ANGLE_1 = 1998-06-10T00:57:42 256.64002393 
ANGLE_2 = 1998-06-10T00:57:42 13.38100016 
TRANSMIT_FREQ_1 = 1998-06-10T00:57:42 2106395199.07917 
RECEIVE_FREQ = 1998-06-10T00:57:42 2287487999.0 

RANGE = 1998-06-10T00:57:43 80452.6503 
ANGLE_1 = 1998-06-10T00:57:43 256.64002393 
ANGLE_2 = 1998-06-10T00:57:43 13.38100016 
TRANSMIT_FREQ_1 = 1998-06-10T00:57:43 2106395199.07917 
RECEIVE_FREQ = 1998-06-10T00:57:43 2287487999.0 

RANGE = 1998-06-10T00:57:44 80452.6331 
ANGLE_1 = 1998-06-10T00:57:44 256.64002393 
ANGLE_2 = 1998-06-10T00:57:44 13.38100016 
TRANSMIT_FREQ_1 = 1998-06-10T00:57:44 2106395199.07917 
RECEIVE_FREQ = 1998-06-10T00:57:44 2287487999.0 
DATA_STOP 

Figure D-6: TDM Example: Four-Way Data 


CCSDS_TDM_VERS = 1.0 
COMMENT TDM example created by yyyyy-nnnA Nav Team (NASA/JPL) 


COMMENT This example TDM describes a scenario such as might occur with a
COMMENT spacecraft like Cassini, which has 3 transponders: X/S, X/X, X/Ka.
COMMENT In this tracking session all 3 transponders were used.
COMMENT This requires a TDM with 3 segments, because a single segment would
COMMENT not be able to specify a 'PATH' statement that would describe the
COMMENT S-down, X-down, and Ka-down signal paths. 


CREATION_DATE = 2006-347T22:51 
ORIGINATOR = NASA/JPL 


META_START 
TIME_SYSTEM = UTC 
PARTICIPANT_1 = DSS-25 
PARTICIPANT_2 = 1997-061A-X 
MODE = SEQUENTIAL
PATH = 1,2,1
INTEGRATION_INTERVAL = 300.0 
INTEGRATION_REF = MIDDLE 
TRANSMIT_DELAY_1 = 0.000077 
RECEIVE_DELAY_1 = 0.000077 
META_STOP 


DATA_START 
TRANSMIT_FREQ_1 = 2006-347T03:50:34 7175802770.23 
RECEIVE_FREQ_1 = 2006-347T06:17:49 8430849716.68 
DATA_STOP 


META_START 
TIME_SYSTEM = UTC 
PARTICIPANT_1 = DSS-25 
PARTICIPANT_2 = 1997-061A-KA 
MODE = SEQUENTIAL
PATH = 1,2,1
INTEGRATION_INTERVAL = 300.0 
INTEGRATION_REF = MIDDLE 
TRANSMIT_DELAY_1 = 0.000077 
RECEIVE_DELAY_1 = 0.000077 
META_STOP 


DATA_START 
TRANSMIT_FREQ_1 = 2006-347T03:50:34 7175802770.23 
RECEIVE_FREQ_1 = 2006-347T06:17:49 32037228923.40 
DATA_STOP 


META_START 
TIME_SYSTEM = UTC 
PARTICIPANT_1 = DSS-25 
PARTICIPANT_2 = 1997-061A-S 
PARTICIPANT_3 = DSS-24 
MODE = SEQUENTIAL
PATH = 1,2,3
INTEGRATION_INTERVAL = 300.0 
INTEGRATION_REF = MIDDLE 
TRANSMIT_DELAY_1 = 7.7e-5 
RECEIVE_DELAY_3 = 7.7e-5 
META_STOP 


DATA_START 
TRANSMIT_FREQ_1 = 2006-347T03:50:34 7175802770.23 
RECEIVE_FREQ_1 = 2006-347T06:17:49 2299322650.01 
DATA_STOP 


Figure D-7: TDM Example: One S/C, X-up, S-down, X-down, Ka-down, Three 
Segments 

CCSDS_TDM_VERS = 1.0 CCSDS_TDM_VERS = 1.0 
CREATION_DATE = 2007-08-30T12:01:44.749 
ORIGINATOR = GSOC 
META_START 
TIME_SYSTEM = UTC 
START_TIME = 2007-08-29T07:00:02.000 
STOP_TIME = 2007-08-29T14:00:02.000 
PARTICIPANT_1 = HBSTK 
PARTICIPANT_2 = SAT 
MODE = SEQUENTIALPATH = 1,2,1INTEGRATION_INTERVAL = 1.0 
INTEGRATION_REF = END 
ANGLE_TYPE = XSYE 
DATA_QUALITY = RAWMETA_STOP 
DATA_START 
DOPPLER_INTEGRATED = 2007-08-29T07:00:02.000 -1.498776048 
ANGLE_1 = 2007-08-29T07:00:02.000 67.01312389 
ANGLE_2 = 2007-08-29T07:00:02.000 18.28395556 
DOPPLER_INTEGRATED = 2007-08-29T08:00:02.000 -2.201305217 
ANGLE_1 = 2007-08-29T08:00:02.000 67.01982278 
ANGLE_2 = 2007-08-29T08:00:02.000 21.19609167 
DOPPLER_INTEGRATED = 2007-08-29T12:00:02.000 2.248620597 
ANGLE_1 = 2007-08-29T12:00:02.000 -84.79697583 
ANGLE_2 = 2007-08-29T12:00:02.000 4.11574444 
DOPPLER_INTEGRATED = 2007-08-29T13:00:02.000 1.547592295 
ANGLE_1 = 2007-08-29T13:00:02.000 -85.14762500 
ANGLE_2 = 2007-08-29T13:00:02.000 4.35471389 
DOPPLER_INTEGRATED = 2007-08-29T14:00:02.000 0.929545817 
ANGLE_1 = 2007-08-29T14:00:02.000 -89.35626083 
ANGLE_2 = 2007-08-29T14:00:02.000 2.78791667 
DATA_STOP 
META_START 
TIME_SYSTEM = UTC 
START_TIME = 2007-08-29T06:00:02.000 
STOP_TIME = 2007-08-29T13:00:02.000 
PARTICIPANT_1 = WHM1 
PARTICIPANT_2 = SAT 
MODE = SEQUENTIALPATH = 1,2,1INTEGRATION_INTERVAL = 1.0 
INTEGRATION_REF = END 
RANGE_MODE = CONSTANT 
RANGE_MODULUS = 1.000000E+07 
ANGLE_TYPE = AZEL 
DATA_QUALITY = RAWMETA_STOP 
DATA_START 
RANGE = 2007-08-29T06:00:02.000 4.00165248953670E+04 
DOPPLER_INTEGRATED = 2007-08-29T06:00:02.000 -0.885640091 
ANGLE_1 = 2007-08-29T06:00:02.000 99.53204250 
ANGLE_2 = 2007-08-29T06:00:02.000 1.26724167 
RANGE = 2007-08-29T07:00:02.000 3.57238793591890E+04 
DOPPLER_INTEGRATED = 2007-08-29T07:00:02.000 -1.510223139 
ANGLE_1 = 2007-08-29T07:00:02.000 103.33061750 
ANGLE_2 = 2007-08-29T07:00:02.000 4.77875278 
RANGE = 2007-08-29T08:00:02.000 2.90270197047210E+04 
DOPPLER_INTEGRATED = 2007-08-29T08:00:02.000 -2.229907387 
ANGLE_1 = 2007-08-29T08:00:02.000 104.60635806 
ANGLE_2 = 2007-08-29T08:00:02.000 5.47492500 
RANGE = 2007-08-29T12:00:02.000 2.81439006334980E+04 
DOPPLER_INTEGRATED = 2007-08-29T12:00:02.000 2.222121620 
ANGLE_1 = 2007-08-29T12:00:02.000 240.89006194 
ANGLE_2 = 2007-08-29T12:00:02.000 6.71215556 
RANGE = 2007-08-29T13:00:02.000 3.48156855860090E+04 
DOPPLER_INTEGRATED = 2007-08-29T13:00:02.000 1.504082291 
ANGLE_1 = 2007-08-29T13:00:02.000 243.73365222 
ANGLE_2 = 2007-08-29T13:00:02.000 8.78254167 
DATA_STOP 


Figure D-8: TDM Example: Angles, Range, Doppler Combined in Single TDM 


CCSDS_TDM_VERS = 1.0 

COMMENT This TDM example contains range data timetagged at transmit time 

CREATION_DATE = 2005-09-17T23:59:59 
ORIGINATOR = JAXA 

META_START 
TIME_SYSTEM = UTC 
START_TIME = 2005-09-17T00:41:38.0000 
STOP_TIME = 2005-09-17T00:42:58.0000 
PARTICIPANT_1 = yyyy-nnnAPARTICIPANT_2 = USC1 
MODE = SEQUENTIALPATH = 2,1,2TRANSMIT_BAND = S 
RECEIVE_BAND = S 
TIMETAG_REF = TRANSMIT 
INTEGRATION_REF = START 
RANGE_MODE = CONSTANT 
RANGE_MODULUS = 1.0E7 
RANGE_UNITS = km 
DATA_QUALITY = VALIDATEDCORRECTION_RANGE = 0.0 
CORRECTIONS_APPLIED = YES 
META_STOP 

DATA_START 
RANGE = 2005-09-17T00:41:38.000000 3198.03679519614 
RANGE = 2005-09-17T00:41:40.000000 3199.82505720811 
RANGE = 2005-09-17T00:41:42.000000 3201.61631714467 
RANGE = 2005-09-17T00:41:44.000000 3203.40832656236 
RANGE = 2005-09-17T00:41:46.000000 3205.20108546120 
RANGE = 2005-09-17T00:41:48.000000 3206.99384436004 
RANGE = 2005-09-17T00:41:50.000000 3208.79110014575 
RANGE = 2005-09-17T00:41:52.000000 3210.58535800688 
RANGE = 2005-09-17T00:41:54.000000 3212.38336327374 
RANGE = 2005-09-17T00:41:56.000000 3214.18136854059 
RANGE = 2005-09-17T00:41:58.000000 3215.98012328859 
RANGE = 2005-09-17T00:42:00.000000 3217.78037699888 
RANGE = 2005-09-17T00:42:02.000000 3219.58287915260 
RANGE = 2005-09-17T00:42:04.000000 3221.38613078747 
RANGE = 2005-09-17T00:42:06.000000 3223.19013190349 
RANGE = 2005-09-17T00:42:08.000000 3224.99488250065 
RANGE = 2005-09-17T00:42:10.000000 3226.80113206010 
RANGE = 2005-09-17T00:42:12.000000 3228.60963006298 
RANGE = 2005-09-17T00:42:14.000000 3230.41587962244 
RANGE = 2005-09-17T00:42:16.000000 3232.22587658761 
RANGE = 2005-09-17T00:42:18.000000 3234.03662303393 
RANGE = 2005-09-17T00:42:20.000000 3235.84886844254 
RANGE = 2005-09-17T00:42:22.000000 3237.65961488886 
RANGE = 2005-09-17T00:42:24.000000 3239.47560770319 
RANGE = 2005-09-17T00:42:26.000000 3241.28860259295 
RANGE = 2005-09-17T00:42:28.000000 3243.10384592614 
RANGE = 2005-09-17T00:42:30.000000 3244.92133770276 
RANGE = 2005-09-17T00:42:32.000000 3246.73882947939 
RANGE = 2005-09-17T00:42:34.000000 3248.55856969945 
RANGE = 2005-09-17T00:42:36.000000 3250.37681095722 
RANGE = 2005-09-17T00:42:38.000000 3252.19879962071 
RANGE = 2005-09-17T00:42:40.000000 3254.02003880307 
RANGE = 2005-09-17T00:42:42.000000 3255.84352642885 
RANGE = 2005-09-17T00:42:44.000000 3257.66851301693 
RANGE = 2005-09-17T00:42:46.000000 3259.49125116157 
RANGE = 2005-09-17T00:42:48.000000 3261.31848619307 
RANGE = 2005-09-17T00:42:50.000000 3263.14572122459 
RANGE = 2005-09-17T00:42:52.000000 3264.97295625609 
RANGE = 2005-09-17T00:42:54.000000 3266.80169024990 
RANGE = 2005-09-17T00:42:56.000000 3268.63267268713 
RANGE = 2005-09-17T00:42:58.000000 3270.46440460551 
DATA_STOP 

Figure D-9: TDM Example: Range Data with TIMETAG_REF=TRANSMIT 


CCSDS_TDM_VERS = 1.0 
COMMENT This TDM example contains single differenced Doppler data.
CREATION_DATE = 2006-354T01:38:00Z 
ORIGINATOR = NASA/JPL 

META_START 
TIME_SYSTEM = UTC 
START_TIME = 2003-07-08T04:45:25.0000 
STOP_TIME = 2003-07-08T04:48:25.0000 
PARTICIPANT_1 = yyyy-nnnAPARTICIPANT_2 = DSS-24 
PARTICIPANT 3 = DSS-25 
MODE = SINGLE_DIFF 
PATH_1 = 1,2PATH_2 = 1,3TRANSMIT_BAND = X 
RECEIVE_BAND = X 
INTEGRATION_INTERVAL = 10.0 
INTEGRATION_REF = MIDDLE 
RECEIVE_DELAY_2 = 0.00007732 
RECEIVE_DELAY_3 = 0.00007732 
DATA_QUALITY = VALIDATEDMETA_STOP 

DATA_START 

COMMENT Transmit frequency is S/C beacon one OWLT prior to receive time 

TRANSMIT_FREQ_1 = 2003-07-08T04:10:0000 8.435360E+09 

RECEIVE_FREQ = 2003-07-08T04:45:25.0000 8.738750457763670E+00 
RECEIVE_FREQ = 2003-07-08T04:45:35.0000 8.320683479309080E+00 
RECEIVE_FREQ = 2003-07-08T04:45:45.0000 7.909399032592770E+00 
RECEIVE_FREQ = 2003-07-08T04:45:55.0000 7.490205764770500E+00 
RECEIVE_FREQ = 2003-07-08T04:46:05.0000 7.149572372436510E+00 
RECEIVE_FREQ = 2003-07-08T04:46:15.0000 6.808938980102530E+00 
RECEIVE_FREQ = 2003-07-08T04:46:25.0000 6.481011390686030E+00 
RECEIVE_FREQ = 2003-07-08T04:46:35.0000 6.167441368103020E+00 
RECEIVE_FREQ = 2003-07-08T04:46:45.0000 5.865190505981440E+00 
RECEIVE_FREQ = 2003-07-08T04:46:55.0000 5.590643882751460E+00 
RECEIVE_FREQ = 2003-07-08T04:47:05.0000 5.330531120300290E+00 
RECEIVE_FREQ = 2003-07-08T04:47:15.0000 5.083267211914060E+00 
RECEIVE_FREQ = 2003-07-08T04:47:25.0000 4.850607872009270E+00 
RECEIVE_FREQ = 2003-07-08T04:47:35.0000 4.643701979796000E+00 
RECEIVE_FREQ = 2003-07-08T04:47:45.0000 4.453802272725000E+00 
RECEIVE_FREQ = 2003-07-08T04:47:55.0000 4.281702585856000E+00 
RECEIVE_FREQ = 2003-07-08T04:48:05.0000 4.127402919189000E+00 
RECEIVE_FREQ = 2003-07-08T04:48:15.0000 3.990903272724000E+00 
RECEIVE_FREQ = 2003-07-08T04:48:25.0000 3.872203646461000E+00 

DATA_STOP 

Figure D-10: TDM Example: Differenced Doppler Observable 


CCSDS_TDM_VERS = 1.0 
COMMENT This TDM example contains Delta-DOR data.
COMMENT Quasar CTD 20 also known as J023752.4+284808 (ICRF), 0234+285 (IERS)
CREATION_DATE = 2005-178T21:45:00 
ORIGINATOR = NASA/JPLMETA_START 
TIME_SYSTEM = UTC 
START_TIME = 2004-136T15:42:00.0000 
STOP_TIME = 2004-136T16:02:00.0000 
PARTICIPANT_1 = VOYAGER1 
PARTICIPANT_2 = DSS-55 
PARTICIPANT_3 = DSS-25 
MODE = SINGLE_DIFF 
PATH_1 = 1,2PATH_2 = 1,3TRANSMIT_BAND = X 
RECEIVE_BAND = X 
TIMETAG_REF = RECEIVE 
RANGE_MODE = ONE_WAY 
RANGE_MODULUS = 1.674852710000000E+02 
RECEIVE_DELAY_3 = 0.000077 
DATA_QUALITY = VALIDATEDMETA_STOP 

DATA_START 
COMMENT Timetag is time of signal arrival at PARTICIPANT_2.
COMMENT Transmit frequency is spacecraft beacon a OWLT before receive time.
DOR = 2004-136T15:42:00.0000 -4.911896106591159E-03 
DOR = 2004-136T16:02:00.0000 1.467382930436399E-02 
TRANSMIT_FREQ_1 = 2004-136T14:42:00.0000 8.415123456E+09DATA_STOP 

META_START 
TIME_SYSTEM = UTC 
START_TIME = 2004-136T15:52:00.0000 
STOP_TIME = 2004-136T15:52:00.0000 
PARTICIPANT_1 = CTD 20 
PARTICIPANT_2 = DSS-55 
PARTICIPANT_3 = DSS-25 
MODE = SINGLE_DIFF 
PATH_1 = 1,2PATH_2 = 1,3TRANSMIT_BAND = X 
RECEIVE_BAND = X 
TIMETAG_REF = RECEIVE 
RANGE_MODE = ONE_WAY 
RANGE_MODULUS = 1.674852710000000E+02 
RECEIVE_DELAY_3 = 0.000077 
DATA_QUALITY = VALIDATEDMETA_STOP 

DATA_START 
COMMENT Timetag is time of signal arrival at PARTICIPANT_2.
COMMENT Transmit frequency is reference for 2-station interferometer.
VLBI_DELAY = 2004-136T15:52:00.0000 -1.911896106591159E-03 
TRANSMIT_FREQ_1 = 2004-136T15:42:00.0000 8.415123000E+09DATA_STOP 

META_START 
TIME_SYSTEM = UTC 
PARTICIPANT_1 = DSS-55 
PARTICIPANT_2 = DSS-25 
DATA_QUALITY = VALIDATEDMETA_STOP 

DATA_START 
CLOCK_BIAS = 2004-136T15:42:00.0000 -4.59e-7 
CLOCK_BIAS = 2004-136T16:02:00.0000 -4.59e-7 
DATA_STOP 

Figure D-11: TDM Example: Delta-DOR Observable 


CCSDS_TDM_VERS = 1.0 

COMMENT TDM example created by yyyyy-nnnA Nav Team (NASA/JPL)
COMMENT StarTrek: one minute of launch angles from DSS-16 

CREATION_DATE = 2005-157T18:25:00 
ORIGINATOR = NASA/JPLMETA_START 
TIME_SYSTEM = UTC 
START_TIME = 2004-216T07:44:00 
STOP_TIME = 2004-216T07:45:00 
PARTICIPANT_1 = DSS-16 
PARTICIPANT_2 = yyyy-nnnAMODE = SEQUENTIALPATH = 2,1ANGLE_TYPE = XSYE 
CORRECTION_ANGLE_1 = -0.09 
CORRECTION_ANGLE_2 = 0.18 
CORRECTIONS_APPLIED = NO 
META_STOP 

DATA_START 

ANGLE_1 = 2004-216T07:44:00 -23.62012 
ANGLE_2 = 2004-216T07:44:00 -73.11035 

ANGLE_1 = 2004-216T07:44:10 -23.04004 
ANGLE_2 = 2004-216T07:44:10 -72.74316 

ANGLE_1 = 2004-216T07:44:20 -22.78125 
ANGLE_2 = 2004-216T07:44:20 -72.53027 

ANGLE_1 = 2004-216T07:44:30 -22.59180 
ANGLE_2 = 2004-216T07:44:30 -72.37598 

ANGLE_1 = 2004-216T07:44:40 -22.40527 
ANGLE_2 = 2004-216T07:44:40 -72.23730 

ANGLE_1 = 2004-216T07:44:50 -22.23047 
ANGLE_2 = 2004-216T07:44:50 -72.08887 

ANGLE_1 = 2004-216T07:45:00 -22.08984 
ANGLE_2 = 2004-216T07:45:00 -71.93750 

DATA_STOP 

Figure D-12: TDM Example: Angle Data Only 


CCSDS_TDM_VERS = 1.0 

COMMENT TDM example created by NASA/JPL Navigation System Engineering 

CREATION_DATE = 2005-282T23:00:00 
ORIGINATOR = NASA/JPL 

META_START 
TIME_SYSTEM = UTC 
START_TIME = 2005-274T12:00:00 
STOP_TIME = 2005-280T12:00:00 
PARTICIPANT_1 = DSS-14 
DATA_QUALITY = VALIDATEDMETA_STOP 

DATA_START 
COMMENT Elevation mapping function is Niell 
modelTROPO_DRY = 2005-274T12:00:00 2.0526 
TROPO_DRY = 2005-275T12:00:00 2.0530 
TROPO_DRY = 2005-276T12:00:00 2.0533 
TROPO_DRY = 2005-277T12:00:00 2.0537 
TROPO_DRY = 2005-278T12:00:00 2.0540 
TROPO_DRY = 2005-279T12:00:00 2.0544 
TROPO_DRY = 2005-280T12:00:00 2.0547 

TROPO_WET = 2005-274T12:00:00 0.1139 
TROPO_WET = 2005-275T12:00:00 0.1126 
TROPO_WET = 2005-276T12:00:00 0.1113 
TROPO_WET = 2005-277T12:00:00 0.1099 
TROPO_WET = 2005-278T12:00:00 0.1086 
TROPO_WET = 2005-279T12:00:00 0.1074 
TROPO_WET = 2005-280T12:00:00 0.1061 
DATA_STOP 

META_START 
COMMENT Line of vertical ionospheric calibration for yyyy-nnnACOMMENT Time 
tags are end time of 15 minute measurement intervalTIME_SYSTEM = UTC 
START_TIME = 2005-280T21:45:00 
STOP_TIME = 2005-281T00:00:00 
PARTICIPANT_1 = DSS-14 
PARTICIPANT_2 = yyyy-nnnAMODE = SEQUENTIALPATH = 2,
1DATA_QUALITY = VALIDATEDMETA_STOP 

DATA_START 

STEC = 2005-280T21:45:00 23.1 
STEC = 2005-280T22:00:00 22.8 
STEC = 2005-280T22:15:00 23.2 
STEC = 2005-280T22:30:00 24.4 
STEC = 2005-280T22:45:00 23.6 
STEC = 2005-280T23:00:00 22.4 
STEC = 2005-280T23:15:00 22.6 
STEC = 2005-280T23:30:00 24.6 
STEC = 2005-280T23:45:00 24.0 
STEC = 2005-281T00:00:00 22.2 
DATA_STOP 

Figure D-13: TDM Example: Media Data Only 


CCSDS_TDM_VERS = 1.0 

COMMENT TDM example created by yyyyy-nnnA Nav Team (NASA/JPL)
COMMENT JPL/DSN/Goldstone (DSS-10) weather for DOY 156, 2005 

CREATION_DATE = 2005-156T06:15:00 
ORIGINATOR = NASA/JPLMETA_START 
TIME_SYSTEM = UTC 
START_TIME = 2005-156T00:03:00 
STOP_TIME = 2005-156T06:03:00 
PARTICIPANT_1 = DSS-10 
DATA_QUALITY = VALIDATEDMETA_STOP 

DATA_START 

TEMPERATURE = 2005-156T00:03:00 302.95 
PRESSURE = 2005-156T00:03:00 896.2 
RHUMIDITY = 2005-156T00:03:00 12.0 

TEMPERATURE = 2005-156T00:33:00 304.05 
PRESSURE = 2005-156T00:33:00 895.9 
RHUMIDITY = 2005-156T00:33:00 11.0 

TEMPERATURE = 2005-156T01:03:00 302.55 
PRESSURE = 2005-156T01:03:00 895.7 
RHUMIDITY = 2005-156T01:03:00 12.0 

TEMPERATURE = 2005-156T01:33:00 302.65 
PRESSURE = 2005-156T01:33:00 895.7 
RHUMIDITY = 2005-156T01:33:00 11.0 

TEMPERATURE = 2005-156T02:03:00 301.55 
PRESSURE = 2005-156T02:03:00 895.9 
RHUMIDITY = 2005-156T02:03:00 11.0 

TEMPERATURE = 2005-156T02:33:00 300.45 
PRESSURE = 2005-156T02:33:00 895.9 
RHUMIDITY = 2005-156T02:33:00 12.0 

TEMPERATURE = 2005-156T03:03:00 299.55 
PRESSURE = 2005-156T03:03:00 896.1 
RHUMIDITY = 2005-156T03:03:00 14.0 

TEMPERATURE = 2005-156T03:33:00 298.65 
PRESSURE = 2005-156T03:33:00 896.2 
RHUMIDITY = 2005-156T03:33:00 15.0 

TEMPERATURE = 2005-156T04:03:00 298.05 
PRESSURE = 2005-156T04:03:00 896.4 
RHUMIDITY = 2005-156T04:03:00 17.0 

TEMPERATURE = 2005-156T04:33:00 297.15 
PRESSURE = 2005-156T04:33:00 896.8 
RHUMIDITY = 2005-156T04:33:00 19.0 

TEMPERATURE = 2005-156T05:03:00 294.85 
PRESSURE = 2005-156T05:03:00 897.3 
RHUMIDITY = 2005-156T05:03:00 21.0 

TEMPERATURE = 2005-156T05:33:00 293.95 
PRESSURE = 2005-156T05:33:00 897.3 
RHUMIDITY = 2005-156T05:33:00 23.0 

TEMPERATURE = 2005-156T06:03:00 293.05 

PRESSURE = 2005-156T06:03:00 897.3 
RHUMIDITY = 2005-156T06:03:00 25.0 
DATA_STOP 

Figure D-14: TDM Example: Meteorological Data Only 


CCSDS_TDM_VERS = 1.0 
COMMENT TDM example created by yyyyy-nnnA Nav Team (NASA/JPL)
COMMENT The following are clock offsets, in seconds between theCOMMENT 
clocks at each DSN complex relative to UTC(NIST). The offset 
COMMENT is a mean of readings using several GPS space vehicles inCOMMENT 
common view. Value is "station clock minus UTC". 

CREATION_DATE = 2005-161T15:45:00 
ORIGINATOR = NASA/JPL 

META_START 
COMMENT Note: SPC10 switched back to Maser1 from Maser2 on 2005-142 
TIME_SYSTEM = UTC 
START_TIME = 2005-142T12:00:00 
STOP_TIME = 2005-145T12:00:00 
PARTICIPANT_1 = UTC-NIST 
PARTICIPANT_2 = DSS-10 

META_STOP 

DATA_START 
CLOCK_BIAS = 2005-142T12:00:00 9.56e-7 
CLOCK_DRIFT = 2005-142T12:00:00 6.944e-14 
CLOCK_BIAS = 2005-143T12:00:00 9.62e-7 
CLOCK_DRIFT = 2005-143T12:00:00 -2.083e-13 
CLOCK_BIAS = 2005-144T12:00:00 9.44e-7 
CLOCK_DRIFT = 2005-144T12:00:00 -2.778e-13 
CLOCK_BIAS = 2005-145T12:00:00 9.20e-7 
DATA_STOP 

META_START 
TIME_SYSTEM = UTC 
START_TIME = 2005-142T12:00:00 
STOP_TIME = 2005-145T12:00:00 
PARTICIPANT_1 = UTC-NIST 
PARTICIPANT_2 = DSS-40 

META_STOP 

DATA_START 
CLOCK_BIAS = 2005-142T12:00:00 -7.40e-7 
CLOCK_DRIFT = 2005-142T12:00:00 -3.125e-13 
CLOCK_BIAS = 2005-143T12:00:00 -7.67e-7 
CLOCK_DRIFT = 2005-143T12:00:00 -1.620e-13 
CLOCK_BIAS = 2005-144T12:00:00 -7.81e-7 
CLOCK_DRIFT = 2005-144T12:00:00 -4.745e-13 
CLOCK_BIAS = 2005-145T12:00:00 -8.22e-7 
DATA_STOP 

META_START 
TIME_SYSTEM = UTC 
START_TIME = 2005-142T12:00:00 
STOP_TIME = 2005-145T12:00:00 
PARTICIPANT_1 = UTC-NIST 
PARTICIPANT_2 = DSS-60 

META_STOP 

DATA_START 
CLOCK_BIAS = 2005-142T12:00:00 -1.782e-6 
CLOCK_DRIFT = 2005-142T12:00:00 1.736e-13 
CLOCK_BIAS = 2005-143T12:00:00 -1.767e-6 
CLOCK_DRIFT = 2005-143T12:00:00 1.157e-14 
CLOCK_BIAS = 2005-144T12:00:00 -1.766e-6 
CLOCK_DRIFT = 2005-144T12:00:00 8.102e-14 
CLOCK_BIAS = 2005-145T12:00:00 -1.759e-6 
DATA_STOP 

Figure D-15: TDM Example: Clock Bias/Drift Only 


The following are some additional scenarios that are not currently 
considered in the example set, but could be included in later versions of 
the TDM: 

a) S/C-S/C crosslinks; 

b) Ground based transponder; 

c) 'DORIS'; 

d) Arrayed downlink; 

e) Orbital debris example; 

f) Combination of radiometric types with media or meteorological data. 


ANNEX E 
INFORMATIVE REFERENCES 
(INFORMATIVE) 


NOTE - Normative references are provided in 1.5. 

[E1] 
Standard Frequencies and Time Signals. Volume 7 of Recommendations and 
Reports of the CCIR: XVIIth Plenary Assembly. Geneva: CCIR, 1990. 

[E2] 
Radio Metric and Orbit Data. Recommendation for Space Data System Standards, 
CCSDS 501.0-B-1-S. Historical Recommendation. Issue 1-S. Washington, D.C.: 
CCSDS, January 1987. 

[E3] Catherine L. Thornton and James S. Border. Radiometric Tracking 
Techniques for Deep-Space Navigation. JPL Deep Space Communications and 
Navigation Series. Hoboken, New Jersey: Wiley, February 2003. 

[E4] Theodore D. Moyer. Formulation for Observed and Computed Values of Deep 
Space Network Data Types for Navigation. JPL Deep Space Communications and 
Navigation Series. Hoboken, New Jersey: Wiley, January 2003. 

[E5] 
Procedures Manual for the Consultative Committee for Space Data Systems. 
CCSDS A00.0-Y-9. Yellow Book. Issue 9. Washington, D.C.: CCSDS, November 
2003. 

[E6] 
The Application of CCSDS Protocols to Secure Systems. Report Concerning 
Space Data System Standards, CCSDS 350.0-G-2. Green Book. Issue 2. 
Washington, D.C.: CCSDS, January 2006. 

[E7] 
Attitude Data Messages. Draft Recommendation for Space Data System Standards, 
CCSDS 504.0-R-1. Red Book. Issue 1. Washington, D.C.: CCSDS, November 2005. 

[E8] 
XML Specification for Navigation Data Messages. Draft Recommendation for 
Space Data System Standards, CCSDS 505.0-R-1. Red Book. Issue 1. Washington, 
D.C.: CCSDS, November 2005. 


ANNEX F 

RATIONALE FOR TRACKING DATA MESSAGES 

(INFORMATIVE) 

F1 GENERAL 

This annex presents the rationale behind the design of the Tracking Data 
Message. It may help the application engineer construct a suitable message. 
Corrections and/or additions to these requirements may occur during future 
updates. 

A specification of requirements agreed to by all parties is essential to 
focus design and to ensure the product meets the needs of the Member 
Agencies. There are many ways of organizing requirements, but the 
categorization of requirements is not as important as the agreement to a 
sufficiently comprehensive set. In this section, the requirements are 
organized into three categories: 

Primary Requirements - These are the most elementary and necessary 
requirements. They would exist no matter the context in which the CCSDS is 
operating, i.e., regardless of preexisting conditions within the CCSDS or 
its Member Agencies. 

Heritage Requirements - These are additional requirements that derive from 
pre-existing Member Agency requirements, conditions, or needs. Ultimately 
these carry the same weight as the Primary Requirements. This Recommended 
Standard reflects heritage requirements pertaining to some of the technical 
participants' home institutions collected during the preparation of the 
Recommended Standard; it does not speculate on heritage requirements that 
could arise from other Member Agencies. 

Desirable Characteristics - These are not requirements, but they are felt to 
be important or useful features of the Recommended Standard. 


F2 
PRIMARY REQUIREMENTS ACCEPTED FOR TRACKING DATA 
MESSAGES 

Table F-1: Primary Requirements 
See PDF version of document for table. 


Table F-2: Heritage Requirements
See PDF version of document for table. 

Table F-3: Desirable Characteristics 
See PDF version of document for table.


TDM SUMMARY SHEET 

(INFORMATIVE) 

The tables in the following pages of this annex show the association between 
data types and metadata keywords. There are only a few required metadata 
keywords, but many more that are applicable to one or more of the various 
data types. Additionally, there are some keywords that are only applicable 
in certain restricted situations. Finally, there are some metadata keywords 
that are completely optional. This summary may assist the user in 
constructing a TDM that captures the data from a specific measurement 
session. 

See PDF version of document for tables.