مطالب آموزشی

Rinex 301

RINEX

The Receiver Independent Exchange Format
Version 3.01
Werner Gurtner
Astronomical Institute
University of Bern
gurtner@aiub.unibe.ch
Lou Estey
UNAVCO
Boulder, Co.
lou@unavco.org
22 June 2009
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Table of Contents
0. REVISION HISTORY………………………………………………………………………………………………….1
1. THE PHILOSOPHY AND HISTORY OF RINEX ………………………………………………………………….2
2. GENERAL FORMAT DESCRIPTION ………………………………………………………………………………3
3. BASIC DEFINITIONS…………………………………………………………………………………………………4
3.1 Time ……………………………………………………………………………………………………………………4
3.2 Pseudo-Range: ……………………………………………………………………………………………………….4
3.3 Phase …………………………………………………………………………………………………………………..4
3.4 Doppler………………………………………………………………………………………………………………..4
3.5 Satellite numbers…………………………………………………………………………………………………….5
4. THE EXCHANGE OF RINEX FILES:……………………………………………………………………………5
5. RINEX VERSION 3 FEATURES…………………………………………………………………………………..7
5.1 Observation codes…………………………………………………………………………………………………..7
5.2 Satellite system-dependent list of observables ……………………………………………………………..9
5.3 Marker type……………………………………………………………………………………………………………9
5.4 Half-wavelength observations, half-cycle ambiguities …………………………………………………..9
5.5 Scale factor ………………………………………………………………………………………………………….10
5.6 Information about receivers on a vehicle …………………………………………………………………..10
5.7 Signal strengths…………………………………………………………………………………………………….10
5.8 Date/time format in the PGM / RUN BY / DATE header record…………………………………………11
5.9 Antenna phase center header record …………………………………………………………………………11
5.10 Antenna orientation……………………………………………………………………………………………..11
5.11 Observation data records ………………………………………………………………………………………11
5.12 Ionosphere delay as pseudo-observables………………………………………………………………….12
5.13 Channel numbers as pseudo-observables …………………………………………………………………12
5.14 Corrections of differential code biases (DCBs) …………………………………………………………13
5.15 Corrections of antenna phase center variations (PCVs)………………………………………………13
5.16 Navigation message files………………………………………………………………………………………13
6. ADDITIONAL HINTS AND TIPS……………………………………………………………………………….13
6.1 Versions……………………………………………………………………………………………………………..13
6.2 Leading blanks in CHARACTER fields …………………………………………………………………………13
6.3 Variable-length records ………………………………………………………………………………………….13
6.4 Blank fields………………………………………………………………………………………………………….14
6.5 Order of the header records, order of data records ………………………………………………………14
6.6 Missing items, duration of the validity of values……………………………………………………………14
6.7 Unknown / Undefined observation types and header records ………………………………………..14
6.8 Event flag records …………………………………………………………………………………………………14
6.9 Receiver clock offset……………………………………………………………………………………………..15
6.10 Two-digit years …………………………………………………………………………………………………..15
6.11 Fit interval (GPS navigation message file)……………………………………………………………….15
6.12 Satellite health (GPS navigation message file)………………………………………………………….15
6.13 Transmission time of message (GPS navigation message file) …………………………………….15
6.14 Antenna references, phase centers ………………………………………………………………………….16
7. RINEX UNDER ANTISPOOFING (AS) ……………………………………………………………………….16
8. DEALING WITH DIFFERENT SATELLITE SYSTEMS……………………………………………………….17
8.1 Time system identifier……………………………………………………………………………………………17
8.2 Pseudorange definition…………………………………………………………………………………………..18
8.3 RINEX navigation message files ……………………………………………………………………………..19
8.3.1 RINEX navigation message files for GLONASS……………………………………………………………19
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8.3.2 RINEX navigation message files for Galileo…………………………………………………………………19
8.3.3 RINEX navigation message files for GEO satellites………………………………………………………….20
8.4 RINEX observation files for GEO satellites …………………………………………………………………..21
9. MODIFICATIONS FOR VERSION 3.01 ………………………………………………………………………….21
9.1 Phase Cycle Shifts……………………………………………………………………………………………………21
9.2 Galileo: BOC-Tracking of an MBOC-Modulated Signal ………………………………………………………22
9.3 Compass Satellite System Code ………………………………………………………………………………….22
9.4 New Observation Codes for GPS L1C and Compass …………………………………………………..22
9.5 Header Records for Glonass Slot and Frequency Numbers …………………………………………..22
9.6 GNSS Navigation Message File: Leap Seconds Record……………………………………………….24
9.7 Clarifications in the Galileo Navigation Message File: ………………………………………………..24
9.8 RINEX Meteorological Data Files…………………………………………………………………………..24
10. REFERENCES ……………………………………………………………………………………………………25
APPENDIX: RINEX FORMAT DEFINITIONS AND EXAMPLES……………………………………………1

A 1 GNSS Observation Data File – Header Section Description ………………………………………1
A 2 GNSS Observation Data File – Data Record Description ………………………………………….5
A 3 GNSS Observation Data File – Example ………………………………………………………………..6
A 4 GNSS Navigation Message File – Header Section Description…………………………………..8
A 5 GNSS Navigation Message File – GPS Data Record Description ………………………………9
A 6 GPS Navigation Message File – Example…………………………………………………………….10
A 7 GNSS Navigation Message File – GALILEO Data Record Description…………………………10
A 8 GALILEO Navigation Message File – Example ……………………………………………………12
A 9 GNSS Navigation Message File – GLONASS Data Record Description………………………..12
A 10 GNSS Navigation Message File – Example: Mixed GPS / GLONASS …………………………12
A 11 GNSS Navigation Message File – SBAS Data Record Description………………………………13
A 12 SBAS Navigation Message File – Example…………………………………………………………..14
A 13 Meteorological Data File – Header Section Description ………………………………………….14
A 14 Meteorological Data File – Data Record Description………………………………………………15
A 15 Meteorological Data File – Example ……………………………………………………………………16
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0. REVISION HISTORY
Version 3.00
02 Feb 2006 A few typos and obsolete paragraphs removed.
08 Mar 2006 Epochs of met data of met files version 2.11 are in GPS time only (Table A14).
31 Mar 2006 DCB header record label corrected in Table A3: SYS / DCBS APPLIED.
June 2006 Filenames for mixed GNSS nav mess files.
10 Aug 2006 Table A2: Error in format of EPOCH record: One 6X removed. Trailing 3X removed.
12 Sep 2006 GNSS navigation message files version 3.00 included (including Galileo).
Table A3: Example of the kinematic event was wrong (kinematic event record).
SYS / DCBS APPLIED header record simplified.
Tables A5 and A7: Clarification for adjustment of “Transmission time of message“.
03 Oct 2006 Table A10: Mixed GPS/GLONASS navigation message file
26 Oct 2006 Table A3: Removed obsolete antispoofing flag
Tables A5/7/9: Format error in SV / EPOCH / SV CLK: Space between svn and year was
missing
Half-cycle ambiguity flag (re-)introduced (5.4 and Table A2).
Clarification of reported GLONASS time (8.1).
New header record SYS / PCVS APPLIED
New Table 10: Relations between GPS, GST, and GAL weeks
Recommendation to avoid storing redundant navigation messages (8.3)
14 Nov 2006 Tables A5/9/11: Format error in BROADCAST ORBIT – n: 3X 4X. Examples were OK.
21 Nov 2006 Marker type NON_PHYSICAL added
19-Dec-2006 Table A3: Example of SYS / DCBS APPLIED was wrong.
13-Mar-2007 Paragraph 3.3: Leftover from RINEX version 2 regarding wavelength factor for squaringtype
receiver removed and clarified.
14-Jun-2007 Paragraph 5.11: Clarification regarding the observation record length
28-Nov-2007 Frequency numbers for Glonass –7..+12 (BROADCAST ORBIT – 2)
Version 3.01
22-Jun-2009 Phase cycle shifts
Galileo: BOC-tracking of an MBOC-modulated signal
Compass satellite system: Identifier and observation codes
Code for GPS L1C
Header records for Glonass slot and frequency numbers
Order of data records
Galileo nav mess record BROADCAST ORBIT – 5: Bits 3/4 reserved for Galileo internal use
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1. THE PHILOSOPHY AND HISTORY OF RINEX
The first proposal for the Receiver Independent Exchange Format RINEX was developed by the Astronomical
Institute of the University of Berne for the easy exchange of the GPS data to be collected during the
first large European GPS campaign EUREF 89, which involved more than 60 GPS receivers of 4 different
manufacturers. The governing aspect during the development was the following fact:
Most geodetic processing software for GPS data use a well-defined set of observables:
– the carrier-phase measurement at one or both carriers (actually being a measurement on the beat frequency
between the received carrier of the satellite signal and a receiver-generated reference frequency).
– the pseudorange (code) measurement, equivalent to the difference of the time of reception (expressed
in the time frame of the receiver) and the time of transmission (expressed in the time frame
of the satellite) of a distinct satellite signal.
– the observation time being the reading of the receiver clock at the instant of validity of the carrierphase
and/or the code measurements.
Usually the software assumes that the observation time is valid for both the phase and the code measurements,
and for all satellites observed.
Consequently all these programs do not need most of the information that is usually stored by the receivers:
They need phase, code, and time in the above mentioned definitions, and some station-related information
like station name, antenna height, etc.
Up till now two major format versions have been developed and published:
– The original RINEX Version 1 presented at and accepted by the 5th International Geodetic Symposium
on Satellite Positioning in Las Cruces, 1989. [Gurtner et al. 1989], [Evans 1989]
– RINEX Version 2 presented at and accepted by the Second International Symposium of Precise Positioning
with the Global Positioning system in Ottawa, 1990, mainly adding the possibility to include
tracking data from different satellite systems (GLONASS, SBAS). [Gurtner and Mader 1990a,
1990b], [Gurtner 1994].
Several subversions of RINEX Version 2 have been defined:
– Version 2.10: Among other minor changes allowing for sampling rates other than integer seconds
and including raw signal strengths as new observables. [Gurtner 2002]
– Version 2.11: Includes the definition of a two-character observation code for L2C pseudoranges and
some modifications in the GEO NAV MESS files [Gurtner and Estey 2005]
– Version 2.20: Unofficial version used for the exchange of tracking data from spaceborne receivers
within the IGS LEO pilot project [Gurtner and Estey 2002]
As spin-offs of this idea of a receiver-independent GPS exchange format other RINEX-like exchange file
formats have been defined, mainly used by the International GNSS Service IGS:
– Exchange format for satellite and receiver clock offsets determined by processing data of a GNSS
tracking network [Ray and Gurtner 1999]
– Exchange format for the complete broadcast data of space-based augmentation systems SBAS.
[Suard et al. 2004]
– IONEX: Exchange format for ionosphere models determined by processing data of a GNSS tracking
network [Schaer et al. 1998]
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– ANTEX: Exchange format for phase center variations of geodetic GNSS antennae [Rothacher and
Schmid 2005]
The upcoming European Navigation Satellite System Galileo and the enhanced GPS with new frequencies
and observation types, especially the possibility to track frequencies on different channels, ask for a more
flexible and more detailed definition of the observation codes.
To improve the handling of the data files in case of “mixed” files, i.e. files containing tracking data of more
than one satellite system, each one with different observation types, the record structure of the data record
has been modified significantly and, following several requests, the limitation to 80 characters length has
been removed.
As the changes are quite significant, they lead to a new RINEX Version 3. The new version also includes the
unofficial Version 2.20 definitions for space-borne receivers.
The major change asking for a version 3.01 was the requirement to generate consistent phase observations
across different tracking modes or channels, i.e. to apply ¼-cycle shifts prior to RINEX file generation, if
necessary, to facilitate the processing of such data.
2. GENERAL FORMAT DESCRIPTION
The RINEX version 3.00 format consists of three ASCII file types:
1. Observation data File
2. Navigation message File
3. Meteorological data File
Each file type consists of a header section and a data section. The header section contains global information
for the entire file and is placed at the beginning of the file. The header section contains header labels in
columns 61-80 for each line contained in the header section. These labels are mandatory and must appear
exactly as given in these descriptions and examples.
The format has been optimized for minimum space requirements independent from the number of different
observation types of a specific receiver or satellite system by indicating in the header the types of observations
to be stored for this receiver and the satellite systems having been observed. In computer systems allowing
variable record lengths the observation records may be kept as short as possible. Trailing blanks can
be removed from the records. There is no maximum record length limitation for the observation records.
Each Observation file and each Meteorological Data file basically contain the data from one site and one
session. Starting with Version 2 RINEX also allows to include observation data from more than one site
subsequently occupied by a roving receiver in rapid static or kinematic applications. Although Version 2 and
higher allow to insert header records into the data field it is not recommended to concatenate data of more
than one receiver (or antenna) into the same file, even if the data do not overlap in time.
If data from more than one receiver have to be exchanged, it would not be economical to include the identical
satellite messages collected by the different receivers several times. Therefore the navigation message
file from one receiver may be exchanged or a composite navigation message file created containing nonredundant
information from several receivers in order to make the most complete file.
The format of the data records of the RINEX Version 1 navigation message file was identical to the former
NGS exchange format. RINEX version 3 navigation message files may contain navigation messages of more
than one satellite system (GPS, GLONASS, Galileo, SBAS).
The actual format descriptions as well as examples are given in the Tables at the end of the paper.
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3. BASIC DEFINITIONS
GPS observables include three fundamental quantities that need to be defined: Time, Phase, and Range.
3.1 Time
The time of the measurement is the receiver time of the received signals. It is identical for the phase and
range measurements and is identical for all satellites observed at that epoch. For single-system data files it is
by default expressed in the time system of the respective satellite system. Else the actual time can (for mixed
files must) be indicated in the Start Time header record.
3.2 Pseudo-Range:
The pseudo-range (PR) is the distance from the receiver antenna to the satellite antenna including receiver
and satellite clock offsets (and other biases, such as atmospheric delays):
PR = distance +
c * (receiver clock offset – satellite clock offset +
other biases)
so that the pseudo-range reflects the actual behavior of the receiver and satellite clocks. The pseudo-range is
stored in units of meters.
See also clarifications for pseudoranges in mixed GPS/GLONASS/Galileo files in chapter 8.1.
3.3 Phase
The phase is the carrier-phase measured in whole cycles. The half-cycles measured by squaring-type receivers
must be converted to whole cycles and flagged by the respective observation code (see Table 5 and paragraph
5.4, GPS only).
The phase changes in the same sense as the range (negative doppler). The phase observations between epochs
must be connected by including the integer number of cycles.
The observables are not corrected for external effects like atmospheric refraction, satellite clock offsets, etc.
If necessary phase observations are corrected for phase shifts needed to guarantee consistency between
phases of the same frequency and satellite system based on different signal channels (see section 9.1 below).
If the receiver or the converter software adjusts the measurements using the real-time-derived receiver clock
offsets dT(r), the consistency of the 3 quantities phase / pseudo-range / epoch must be maintained, i.e. the
receiver clock correction should be applied to all 3 observables:
Time(corr) = Time(r) – dT(r)
PR(corr) = PR(r) – dT(r)*c
phase(corr) = phase(r) – dT(r)*freq
3.4 Doppler
The sign of the doppler shift as additional observable is defined as usual: Positive for approaching satellites.
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3.5 Satellite numbers
Starting with RINEX Version 2 the former two-digit satellite numbers nn are preceded by a one-character
system identifier s:
snn
||
|+– nn: PRN (GPS, Galileo, Compass)
| slot number (GLONASS)
| PRN-100 (SBAS Geostationary)
|
+— s: satellite system identifier
G : GPS
R : GLONASS
S : SBAS payload
E : Galileo
C : Compass
SBAS: Satellite-Based Augmentation System
Table 1: Satellite numbers
The same satellite system identifiers are also used in all header records when appropriate.
4. THE EXCHANGE OF RINEX FILES:
We recommend using the following naming convention for RINEX files:
ssssdddf.yyt
| | | | |
| | | | +– t: file type:
| | | | O: Observation file
| | | | N: GPS navigation message file
| | | | M: Meteorological data file
| | | | G: GLONASS navigation message file
| | | | L: Galileo navigation message file
| | | | P: Mixed GNSS navigation message file
| | | | H: SBAS Payload navigation message file
| | | | B: SBAS broadcast data file
| | | | (separate documentation)
| | | | C: Clock file (separate documentation)
| | | | S: Summary file (used e.g., by IGS, not a standard!)
| | | +— yy: two-digit year
| | +—– f: file sequence number/character within day.
| | daily file: f = 0 (zero)
| | hourly files:
| | a = 1st hour: 00h-01h; b = 2nd hour: 01h-02h;
| | . . . x = 24th hour: 23h-24h
| +——- ddd: day of the year of first record
+———– ssss: 4-character station name designator
Table 2: Recommended filenames: General, daily, hourly files
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For 15-minutes high-rate tracking data we recommend the following extended filenames:
ssssdddhmm.yyO
| | || | |
| | || | +- O: observation file
| | || +— yy: two-digit year
| | |+—— mm: starting minute within the hour (00, 15, 30, 45)
| | +——- h: character for the n-th hour in the day
| | a = 1st hour: 00h-01h; b = 2nd hour: 01h-02h;
| | . . . x = 24th hour: 23h-24h.
| +——— ddd: day of the year
+———— ssss: 4-char station ID or ID for the LEO
receiver/antenna
Table 3: Recommended filenames: High-rate data files
When data transmission times or storage volumes are critical we recommend compressing the files prior to
storage or transmission. IGS currently uses the UNIX “compress” und “uncompress” programs. Compatible
routines are available on VAX/VMS and PC/DOS systems, as well.
Proposed file name extensions for the compressed files:
+———————————————————————-+
| File Types All platforms UNIX VMS DOS |
| uncompressed compressed |
+———————————————————————-+
| Obs Files .yyO .yyO.Z .yyO_Z .yyY |
| Obs Files (Hatanaka compressed) .yyD .yyD.Z .yyD_Z .yyE |
| GPS Nav Message Files .yyN .yyN.Z .yyN_Z .yyX |
| GLONASS Nav Message File .yyG .yyG.Z .yyG_Z .yyV |
| Galileo Nav Message File .yyL .yyL.Z .yyL_Z .yyT |
| Mixed GNSS Nav Message File .yyP .yyP.Z .yyP_Z .yyQ |
| GEO SBAS Nav Message Files .yyH .yyH.Z .yyH_Z .yyU |
| GEO SBAS Broadcast Files (sep. doc.) .yyB .yyB.Z .yyB_Z .yyA |
| Met Data Files .yyM .yyM.Z .yyM_Z .yyW |
| Clock Files (see sep.doc.) .yyC .yyC.Z .yyC_Z .yyK |
+———————————————————————-+
Table 4: Recommended filename extensions for compressed files
In order to additionally reduce the size of observation files Yuki Hatanaka developed a special compression
scheme that takes advantage of the structure of the RINEX observation data by forming higher-order differences
in time between observations of the same type and satellite. This compressed file is also an ASCII file
that is subsequently compressed again using the above mentioned standard compression programs.
References for the Hatanaka compression scheme: See e.g.
– ftp://terras.gsi.go.jp/software
– IGSMails 1525,1686,1726,1763,1785,4967,4969,4975
The file naming and compression recommendations are strictly speaking not part of the RINEX format definition.
However, they significantly facilitate the exchange of RINEX data in large user communities like
IGS.
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5. RINEX VERSION 3 FEATURES
The following section contains features that have been introduced for RINEX Version 3:
5.1 Observation codes
The new signal structures for GPS and Galileo make it possible to generate code and phase observations
based on one or a combination of several channels: Two-channel signals are composed of I and Q components,
three-channel signals of A, B, and C components. Moreover a wideband tracking of a combined
E5a + E5b frequency tracking is possible. In order to keep the observation codes short but still allow for a
detailed characterization of the actual signal generation the length of the codes is increased from two (Version
1 and 2) to three by adding a signal generation attribute:
The observation code tna consists of three parts:
– t : observation type: C = pseudorange, L = carrier phase, D = doppler, S = signal strength)
– n : band / frequency: 1, 2,…,8
– a : attribute: tracking mode or channel, e.g., I, Q, etc
Examples:
– L1C: C/A code-derived L1 carrier phase (GPS, GLONASS)
Carrier phase on E2-L1-E1 derived from C channel (Galileo)
– C2L: L2C pseudorange derived from the L channel (GPS)
Observation Codes
System
Freq.
Band
Frequency Channel or Code Pseudo
Range
Carrier
Phase
Doppler
Signal
Strength
C/A C1C L1C D1C S1C
L1C (M) C1S L1S D1S S1S
L1C (L) C1L L1L D1L S1L
L1C (M+L) C1X L1X D1X S1X
P C1P L1P D1P S1P
Z-tracking and similar
(AS on)
C1W L1W D1W S1W
Y C1Y L1Y D1Y S1Y
M C1M L1M D1M S1M
L1 1575.42
codeless — L1N D1N S1N
C/A C2C L2C D2C S2C
L1(C/A)+(P2-P1)
(semi-codeless) C2D L2D D2D S2D
L2C (M) C2S L2S D2S S2S
L2C (L) C2L L2L D2L S2L
L2C (M+L)1 C2X L2X D2X S2X
P C2P L2P D2P S2P
Z-tracking and similar
(AS on)
C2W L2W D2W S2W
Y C2Y L2Y D2Y S2Y
M C2M L2M D2M S2M
GPS
L2 1227.60
codeless — L2N D2N S2N
1 Example: Trimble NetRS and Septentrio PolaRx2C track L2C on the combined code M+L, therefore
attribute X has to be used for these observables.
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I C5I L5I D5I S5I
Q C5Q L5Q D5Q S5Q
L5 1176.45
I+Q C5X L5X D5X S5X
C/A C1C L1C D1C S1C G1 1602+k*9/16
k= -7…+12 P C1P L1P D1P S1P
C/A (GLONASS M) C2C L2C D2C S2C
GLONASS
G2 1246+k*7/16
P C2P L2P D2P S2P
A PRS C1A L1A D1A S1A
B I/NAV OS/CS/SoL C1B L1B D1B S1B
C no data C1C L1C D1C S1C
B+C C1X L1X D1X S1X
E1 1575.42
A+B+C C1Z L1Z D1Z S1Z
I F/NAV OS C5I L5I D5I S5I
Q no data E5a 1176.45 C5Q L5Q D5Q S5Q
I+Q C5X L5X D5X S5X
I I/NAV OS/CS/SoL C7I L7I D7I S7I
E5b 1207.140 Q no data C7Q L7Q D7Q S7Q
I+Q C7X L7X D7X S7X
I C8I L8I D8I S8I
Q C8Q L8Q D8Q S8Q
E5
(E5a+E5b)
1191.795
I+Q C8X L8X D8X S8X
A PRS C6A L6A D6A S6A
B C/NAV CS C6B L6B D6B S6B
C no data C6C L6C D6C S6C
B+C C6X L6X D6X S6X
Galileo
E6 1278.75
A+B+C C6Z L6Z D6Z S6Z
L1 1575.42 C/A C1C L1C D1C S1C
I C5I L5I D5I S5I
Q C5Q L5Q D5Q S5Q
SBAS
L5 1176.45
I+Q C5X L5X D5X S5X
E1 1589.74 ? ? ? ? ?
I C2I L2I D2I S2I
E2 1561.098 Q C2Q L2Q D2Q S2Q
I+Q C2X L2X D2X S2X
I C7I L7I D7I S7I
E5b 1207.14 Q C7Q L7Q D7Q S7Q
I+Q C7X L7X D7X S7X
I C6I L6I D6I S6I
Q C6Q L6Q D6Q S6Q
Compass
E6 1268.52
I+Q C6X L6X D6X S6X
Table 5: RINEX Version 3.01 observation codes
For Galileo the band/frequency number n does not necessarily agree with the official frequency numbers: n
= 7 for E5b, n = 8 for E5a+b.
GPS-SBAS and -pseudorandom noise (PRN) code assignments:
See e.g., http://www.losangeles.af.mil/library/factsheets/factsheet.asp?id=8618
Antispoofing (AS) of GPS: True codeless GPS receivers (squaring-type receivers) use the attribute N.
Semi-codeless receivers tracking the first frequency using C/A code and the second frequency using some
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codeless options use attribute D. Z-tracking under AS or similar techniques to recover pseudorange and
phase on the “P-code” band use attribute W. Y-code tracking receivers use attribute Y.
As all observations affected by “AS on” get now their own attribute (codeless, semi-codeless, Z-tracking and
similar) the Antispoofing flag introduced into the observation data records of RINEX Version 2 has become
obsolete.
Unknown tracking mode: In case of unknown tracking mode or channel the attribute a can be left blank.
However, a mixture of blank and non-blank attributes within the same observation type of the same frequency
band and of the same satellite system has to be avoided: L2S and L2 is not allowed, L2S and C2 is
OK.
5.2 Satellite system-dependent list of observables
The order of the observations stored per epoch and satellite in the observation records is given by a list of
observation codes in a header record. As the types of the observations actually generated by a receiver may
heavily depend on the satellite system RINEX Version 3 requests system-dependent observation code list
(header record type SYS / # / OBS TYPES).
5.3 Marker type
In order to indicate the nature of the marker a MARKER TYPE header record has been defined:
GEODETIC
NON_GEODETIC
SPACEBORNE
AIRBORNE
WATER_CRAFT
GROUND_CRAFT
FIXED_BUOY
FLOATING_BUOY
FLOATING_ICE
GLACIER
BALLISTIC
ANIMAL
HUMAN
Earth-fixed, high-precision monumentation
Earth-fixed, low-precision monumentation
Orbiting space vehicle
Aircraft, balloon, etc.
Mobile water craft
Mobile terrestrial vehicle
“Fixed” on water surface
Floating on water surface
Floating ice sheet, etc.
“Fixed” on a glacier
Rockets, shells, etc
Animal carrying a receiver
Human being
Table 6: Proposed marker type keywords
The record is required except for GEODETIC and NON_GEODETIC marker types.
Attributes other than GEODETIC and NON_GEODETIC will tell the user program that the data were collected
by a moving receiver. The inclusion of a “start moving antenna” record (event flag 2) into the data
body of the RINEX file is therefore not necessary. Event flags 2 and 3 are still necessary to flag alternating
kinematic and static phases of a receiver visiting multiple earth-fixed monuments, however.
Users may define other project-dependent keywords
5.4 Half-wavelength observations, half-cycle ambiguities
Half-wavelength observations (collected by codeless squaring techniques) get their own observation codes.
A special wavelength factor header line and bit 1 of the LLI flag in the observation records are not necessary
anymore. If a receiver changed between squaring and full cycle tracking within the time period of a RINEX
file, observation codes for both types of observations have to be inserted into the respective SYS / # /
OBS TYPES header record.
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Half-wavelength phase observations are stored in full cycles. Ambiguity resolution however has to account
for half wavelengths!.
Full-cycle observations collected by receivers with possible half cycle ambiguity (e.g., during acquisition or
after loss of lock) are to be flagged with Loss of Lock Indicator bit 1 set (see Table A2).
5.5 Scale factor
The optional SYS / SCALE FACTOR record allows e.g., to store phase data with 0.0001 cycles resolution
if the data was multiplied by a scale factor of 10 before being stored into RINEX file. Used to increase resolution
by 10, 100, etc only. It is a modification of the Version 2.20 OBS SCALE FACTOR record.
5.6 Information about receivers on a vehicle
For the processing of data collected by receivers on a vehicle the following additional information can be
provided by special header records:
– Antenna position (position of the antenna reference point) in a body-fixed coordinate system: ANTENNA:
DELTA X/Y/Z
– Bore-sight of antenna: The unit vector of the direction of the antenna axis towards the GNSS satellites.
It corresponds to the vertical axis on earth-bound antenna: ANTENNA: B.SIGHT XYZ
– Antenna orientation: Zero-direction of the antenna. Used for the application of “azimuth”-dependent
phase center variation models (see 6.14 below). ANTENNA: ZERODIR XYZ
– Current center of mass of the vehicle (for spaceborne receivers): CENTER OF MASS: XYZ
– Average phase center position: ANTENNA: PHASECENTER (see below)
All three quantities have to be given in the same body-fixed coordinate system. The attitude of the vehicle
has to be provided by separate attitude files in the same body-fixed coordinate system.
5.7 Signal strengths
The generation of the RINEX signal strength indicators sn_rnx in the data records (1 = very weak,…,9 =
very strong) are standardized in case the raw signal strength2 sn_raw is given in dbHz:
sn_rnx = MIN(MAX(INT(sn_raw/6),1),9)
S/N (dbHz) S/N (RINEX)
<12 1 12-17 2 18-23 3 24-29 4 30-35 5 36-41 6 42-47 7 48-53 8 ≥54 9 Table 7: Standardized S/N indicators 2 S/N is the raw S/N at the output of the correlators, without attempting to recover any correlation losses RINEX Version 3.01 Description 11 rinex301_2009_06_22.doc 23.06.2009 11:03 The raw signal strengths optionally stored as Sna observations in the data records should be stored in dbHz if possible. The new SIGNAL STRENGTH UNIT header record can be used to indicate the units of these observations. 5.8 Date/time format in the PGM / RUN BY / DATE header record The format of the generation time of the RINEX files stored in the second header record PGM / RUN BY / DATE is now defined to be yyyymmdd hhmmss zone zone: 3 – 4 character code for the time zone It is recommended to use UTC as time zone. Set zone to LCL if local time was used with unknown local time system code. 5.9 Antenna phase center header record An optional header record for antenna phase center positions ANTENNA: PHASECENTER is defined to allow for higher precision positioning without need of additional external antenna information. It can be useful in well-defined networks or applications. It contains the position of an average phase center relative to the antenna reference point for a specific frequency and satellite system. On vehicles the phase center position can be reported in the body-fixed coordinate system. See 6.14 below. Regarding the use of phase center variation corrections see 5.15. 5.10 Antenna orientation Header records have been defined to report the orientation of the antenna zero-direction as well as the direction of its vertical axis (bore-sight) if mounted tilted on a fixed station. The header records can also be used for antennas on vehicles. See 6.14 below. 5.11 Observation data records Apart from the new observation code definitions the most conspicuous modification of the RINEX format concerns the observation records. As the types of the observations and their order within a data record depend on the satellite system, the new format should make it easier for programs as well as human beings to read the data records. Each observation record begins with the satellite number snn, the epoch record starts with special character >. It is now also much easier to synchronize the reading program with the next epoch
record in case of a corrupted data file or when streaming observation data in a RINEX-like format. The record
length limitation to 80 characters of RINEX Versions 1 and 2 has been removed.
For the following list of observation types for the four satellite systems G,S,E,R
G 5 C1P L1P L2C C2C S2C SYS / # / OBS TYPES
R 2 C1C L1C SYS / # / OBS TYPES
E 2 L1B L5I SYS / # / OBS TYPES
S 2 C1C L1C SYS / # / OBS TYPES
Table 8: Example for a list of observation types
the epoch and observation records look as follows:
> 2006 03 24 13 10 54.0000000 0 7 -0.123456789210
G06 23619095.450 -53875.632 8 -41981.375 5 23619112.008 24.158
G09 20886075.667 -28688.027 9 -22354.535 6 20886082.101 38.543
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G12 20611072.689 18247.789 9 14219.770 8 20611078.410 32.326
R21 21345678.576 12345.567 5
R22 22123456.789 23456.789 5
E11 65432.123 5 48861.586 7
S20 38137559.506 335849.135 9
Table 9: Example for observation data records
The receiver clock correction in the epoch record has been placed such that it could be preceded by an identifier
to make it system-dependent in a later format revision, if necessary.
5.12 Ionosphere delay as pseudo-observables
RINEX files could also be used to make available additional information linked to the actual observations.
One such element is the ionosphere delay having been determined or derived from a ionosphere model.
We add the ionosphere phase delay expressed in full cycles of the respective satellite system-dependent
wavelength as pseudo-observable to the list of the RINEX observables.
– t : observation type: I = Ionosphere phase delay
– n : band / frequency: 1, 2,…,8
– a : attribute: blank
The ionosphere pseudo-observable has to be included into the list of observables of the respective satellite
system. Only one ionosphere observable per satellite has to be included.
The user adds the ionosphere delay to the raw phase observation of the same wavelength and converts it to
other wavelengths and to pseudorange corrections in meters:
corr_phase(fi) = raw_phase(fi) + d_ion(fi)
corr_prange(fi) = raw_prange(fi) – d_ion(fi) × c/fi
d_ion(fk) = d_ion(fi) × (fi/fk)2 (accounting for 1st order effects only)
d_ion(fi): Given ionospheric phase correction for frequency fi
5.13 Channel numbers as pseudo-observables
For special applications it might be necessary to know the receiver channel numbers having been assigned
by the receiver to the individual satellites. We may include this information as another pseudo-observable:
– t : observation type: X = Receiver channel number
– n : band / frequency : 0
– a : attribute: blank
Lowest channel number allowed is 1 (re-number channels beforehand, if necessary). In case of a receiver
using multiple channels for one satellite the channels could be packed with two digits each right-justified
into the same data field, order corresponding to the order of the observables concerned. Format F14.3 according
to (<5-nc>(2X),I2.2,’.000′), nc being the number of channels.
Restriction: Not more than 5 channels and channel numbers <100. Examples: 0910.000 for channels 9 and 10 010203.000 for channels 1, 2, and 3 —–F14.3—- RINEX Version 3.01 Description 13 rinex301_2009_06_22.doc 23.06.2009 11:03 5.14 Corrections of differential code biases (DCBs) For special high-precision applications it might be useful to generate RINEX files with corrections of the differential code biases (DCBs) already applied. There are programs available to correct the observations in RINEX files for differential code biases (e.g., cc2noncc, J. Ray 2005). This can be reported by special header records SYS / DCBS APPLIED pointing to the file containing the applied corrections. 5.15 Corrections of antenna phase center variations (PCVs) For more precise applications an elevation- or elevation and azimuth-dependent phase center variation (pcv) model for the antenna (referring to the agreed-upon ARP) should be used. For special applications it might be useful to generate RINEX files with these variations already applied. This can be reported by special header records SYS / PCVS APPLIED pointing to the file containing the PCV correction models. 5.16 Navigation message files The header portion has been unified (with respect to the format definitions) for all satellite systems. The data portion contains now in the first record of each message block in addition to the satellite number also the code for the satellite system. G06 1999 09 02 17 51 44 -.839701388031D-03 -.165982783074D-10 .000000000000D+00 Header records with system-dependent contents also contain the system identifier. They are repeated for each system, if applicable. GPSA .1676D-07 .2235D-07 .1192D-06 .1192D-06 IONOSPHERIC CORR GPSB .1208D+06 .1310D+06 -.1310D+06 -.1966D+06 IONOSPHERIC CORR GAL .1234D+05 .2345D+04 -.3456D+03 IONOSPHERIC CORR 6. ADDITIONAL HINTS AND TIPS 6.1 Versions Programs developed to read RINEX files have to verify the version number. Files of newer versions may look different even if they do not use any of the newer features 6.2 Leading blanks in CHARACTER fields We propose that routines to read files automatically delete leading blanks in any CHARACTER input field. Routines creating RINEX files should also left-justify all variables in the CHARACTER fields. 6.3 Variable-length records ASCII files usually have variable record lengths, so we recommend to first read each observation record into a blank string long enough to accommodate the largest possible observation record3 and decode the data afterwards. In variable length records, empty data fields at the end of a record may be missing, especially in the case of the optional receiver clock offset. 3 Defined by the satellite system with the largest number of possible observables plus any “pseudo-observables” like S/N, ionosphere, etc. The length limitation to 80 characters of RINEX Versions 1 and 2 has been removed. RINEX Version 3.01 Description 14 rinex301_2009_06_22.doc 23.06.2009 11:03 6.4 Blank fields In view of future modifications we recommend to carefully skip any fields currently defined to be blank (format fields nX), because they may be assigned to new contents in future versions. 6.5 Order of the header records, order of data records As the record descriptors in columns 61-80 are mandatory, the programs reading a RINEX Version 3 header are able to decode the header records with formats according to the record descriptor, provided the records have been first read into an internal buffer. We therefore propose to allow free ordering of the header records, with the following exceptions: – The RINEX VERSION / TYPE record must be the first record in a file – The SYS / # / OBS TYPES record(s) should precede any SYS / DCBS APPLIED and SYS / SCALE FACTOR records. – The # OF SATELLITES record (if present) should be immediately followed by the corresponding number of PRN / # OF OBS records. (These records may be handy for documentary purposes. However, since they may only be created after having read the whole raw data file we define them to be optional. – The END OF HEADER of course is the last header in the record Data records: We explicitly exclude multiple epoch data records with identical time tags (exception: Event records). Epochs have to appear ordered in time. 6.6 Missing items, duration of the validity of values Items that are not known at the file creation time can be set to zero or blank or the respective record may be completely omitted. Consequently items of missing header records will be set to zero or blank by the program reading RINEX files. Trailing blanks may be truncated from the record. Each value remains valid until changed by an additional header record. 6.7 Unknown / Undefined observation types and header records It is a good practice for a program reading RINEX files to make sure that it properly deals with unknown observation types, header records or event flags by skipping them and/or reporting them to the user. The program should also check the RINEX version number in the header record and take proper action if it cannot deal with it. 6.8 Event flag records The “number of satellites” also corresponds to the number of records of the same epoch following the EPOCH record.. Therefore it may be used to skip the appropriate number of data records if certain event flags are not to be evaluated in detail. RINEX Version 3.01 Description 15 rinex301_2009_06_22.doc 23.06.2009 11:03 6.9 Receiver clock offset A receiver-derived clock offset can optionally be reported in the RINEX observation files. In order to remove uncertainties if the data (epoch, pseudorange, phase) have been previously corrected or not by the reported clock offset, RINEX Versions 2.10 onwards requests a clarifying header record: RCV CLOCK OFFS APPL. It would then be possible to reconstruct the original observations, if necessary. 6.10 Two-digit years RINEX version 2 stores the years of data records with two digits only. The header of observation files contains a TIME OF FIRST OBS record with the full four-digit year, the GPS nav messages contain the GPS week numbers. From these two data items the unambiguous year can easily be reconstructed. A hundred-year ambiguity occurs in the met data and GLONASS and GEO nav messages: Instead of introducing a new TIME OF FIRST OBS header line it is safe to stipulate that any two-digit years in RINEX Version 1 and Version 2.xx files are understood to represent 80-99: 1980-1999 00-79: 2000-2079 Full 4-digit year fields are/will be defined in the RINEX version 3 files. 6.11 Fit interval (GPS navigation message file) Bit 17 in word 10 of subframe 2 is a “fit interval” flag which indicates the curve-fit interval used by the GPS Control Segment in determining the ephemeris parameters, as follows (see ICD-GPS-200, 20.3.3.4.3.1): 0 = 4 hours 1 = greater than 4 hours. Together with the IODC values and Table 20-XII the actual fit interval can be determined. The second value in the last record of each message shall contain the fit interval in hours determined using IODC, fit flag, and Table 20-XII, according to the Interface Document ICD-GPS-200. 6.12 Satellite health (GPS navigation message file) The health of the signal components (bits 18 to 22 of word three in subframe one) are included from version 2.10 on into the health value reported in the second field of the sixth nav mess records. A program reading RINEX files could easily decide if bit 17 only or all bits (17-22) have been written: RINEX Value: 0 Health OK RINEX Value: 1 Health not OK (bits 18-22 not stored) RINEX Value: >32 Health not OK (bits 18-22 stored)
6.13 Transmission time of message (GPS navigation message file)
The transmission time of message can be shortly before midnight Saturday/Sunday, the ToE and ToC of the
message already in the next week.
As the reported week in the RINEX nav message (BROADCAST ORBIT – 5 record) goes with ToE (this
is different from the GPS week in the original satellite message!), the transmission time of message should
be reduced by 604800 (i.e., will become negative) to also refer to the same week.
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6.14 Antenna references, phase centers
We distinguish between
– The marker, i.e. the geodetic reference monument, on which an antenna is mounted directly with
forced centering or on a tripod.
– The antenna reference point (ARP), i.e., a well-defined point on the antenna, e.g., the center of the
bottom surface of the preamplifier. The antenna height is measured from the marker to the ARP and
reported in the ANTENNA: DELTA H/E/N header record. Small horizontal eccentricities of the
ARP w/r to the marker can be reported in the same record. On vehicles the position of the ARP is
reported in the body-fixed coordinate system in an ANTENNA: DELTA X/Y/Z header record.
– The average phase center: A frequency- and minimum elevation-dependent position of the average
phase center above the antenna reference point. It’s position is important to know in mixed-antennae
networks. It can be given in an absolute sense or relative to a reference antenna. Optional header record:
ANTENNA: PHASECENTER. For fixed stations the components are in north/east/up direction,
on vehicles the position is reported in the body-fixed system X,Y,Z. For more precise applications
an elevation- or elevation and azimuth-dependent phase center variation (pcv) model for the
antenna (referring to the agreed-upon ARP) should be used. For special applications it might be useful
to generate RINEX files with these variations already been applied. This can be reported by special
header records SYS / PCVS APPLIED pointing to the file containing the pcv correction
models.
– The orientation of the antenna: The “zero direction” is usually oriented towards north on fixed stations.
Deviations from the north direction can be reported with the azimuth of the zero-direction in
an ANTENNA: ZERODIR AZI header record. On vehicles the zero-direction is reported as a unit
vector in the body-fixed coordinate system in an ANTENNA: ZERODIR XYZ header record. The
zero direction of a tilted antenna on a fixed station can be reported as unit vector in the left-handed
north/east/up local coordinate system in an ANTENNA: ZERODIR XYZ header record.
– The bore-sight direction of an antenna on a vehicle: The “vertical” symmetry axis of the antenna
pointing towards the GNSS satellites. It can be reported as unit vector in the body-fixed coordinated
system in the ANTENNA: B.SIGHT XYZ record. A tilted antenna on a fixed station could be reported
as unit vector in the left-handed north/east/up local coordinate system in the same header record.
To be able to interpret the various positions correctly it is important that the MARKER TYPE record is
included in the RINEX header.
7. RINEX UNDER ANTISPOOFING (AS)
Some receivers generate code (pseudorange) delay differences between the first and second frequency using
cross-correlation techniques when AS is on and may recover the phase observations on L2 in full cycles.
Using the C/A code delay on L1 and the observed difference it is possible to generate a code delay observation
for the second frequency. Other receivers recover P code observations by breaking down the Y code
into P and W code.
Most of these observations may suffer from an increased noise level. In order to enable the post-processing
programs to take special actions, such AS-infected observations have been flagged in RINEX Version 2
using bit number 2 of the Loss of Lock Indicators (i.e. their current values are increased by 4). In Version 3
there are special attributes for the observation type to more precisely characterize the observable (codeless,
semi-codeless, Z-tracking or similar techniques when AS on, L2C, P-code when AS off, Y-code tracking),
making the AS flag obsolete.
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8. DEALING WITH DIFFERENT SATELLITE SYSTEMS
8.1 Time system identifier
GPS time runs, apart from small differences (<< 1 microsecond), parallel to UTC. It is a continuous time scale, i.e. it does not insert any leap seconds. GPS time is usually expressed in GPS weeks and GPS seconds past 00:00:00 (midnight) Saturday/Sunday. GPS time started with week zero at 00:00:00 UT (midnight) on January 6, 1980. Between 1980 and 2006 14 leap seconds have been introduced to UTC. The GPS week is transmitted by the satellites as a 10 bit number. It has a roll-over after week 1023. The first roll.-over happened on August 22, 1999, 00:00:00 GPS time. In order to avoid ambiguities the GPS week reported in the RINEX navigation message files is a continuous number without roll-over, i.e. …1023, 1024, 1025, … We use GPS as time system identifier for the reported GPS time. GLONASS is basically running on UTC (or, more precisely, GLONASS system time linked to UTC(SU)), i.e. the time tags are given in UTC and not GPS time. It is not a continuous time, i.e. it introduces the same leap seconds as UTC. The reported GLONASS time has the same hours as UTC and not UTC+3 h as the original GLONASS System Time! We use GLO as time system identifier for the reported GLONASS time. Galileo runs on Galileo System Time (GST), which is, apart from small differences (tens of nanoseconds), nearly identical to GPS time: · The Galileo second starts at midnight Saturday/Sunday at the same second as the GPS second. · The GST week as transmitted by the satellites is a 12 bit value with a roll-over after week 4095. The GST week started at zero at the first roll-over of the broadcast GPS week after 1023, i.e. at Sun, 22- Aug-1999 00:00:00 GPS time In order to remove possible misunderstandings and ambiguities the Galileo week reported in the RINEX navigation message files is a continuous number without roll-over, i.e., …4095,4096,4097,… and it is aligned to the GPS week. We use GAL as time system identifier for this reported Galileo time. GPS broadcast GPS RINEX GST GAL 0 … 1023 0 … 1023 0 … 1023 0 … 1023 0 … 1023 0 … 0 … 1023 1024 … 2047 2048 … 3071 3072 … 4095 4096 … 5119 5120 … 0 … 1023 1024 … 2047 2048 … 3071 3072 … 4095 0 … 1024 … 2047 2048 … 3071 3072 … 4095 4096 … 5119 5120 … Table 10: Relations between GPS, GST, and GAL weeks The header records TIME OF FIRST OBS and (if present) TIME OF LAST OBS in pure GPS, GLONASS or Galileo observation files can, in mixed GPS/GLONASS/Galileo observation files must contain the time system identifier defining the system that all time tags in the file are referring to: · GPS to identify GPS time, · GLO to identify the GLONASS UTC time system · GAL to identify Galileo time. RINEX Version 3.01 Description 18 rinex301_2009_06_22.doc 23.06.2009 11:03 Pure GPS observation files default to GPS, pure GLONASS files default to GLO, pure Galileo files default to GAL. Apart from the small errors in the realizations of the different time systems, the relations between the systems are: GLO = UTC = GPS – DtLS GPS = GAL = UTC + DtLS DtLS: Delta time between GPS and UTC due to leap seconds, as transmitted by the GPS satellites in the almanac (2005: DtLS = 13, 2006: DtLS = 14). In order to have the current number of leap seconds available we recommend to include DtLS by a LEAP SECOND line into the RINEX file headers. If there are known non-integer biases between “GPS receiver clock”, “GLONASS receiver clock” or “Galileo receiver clock” in the same receiver, they should be applied in the process of RINEX conversion. In this case the respective code and phase observations have to be corrected, too (c * bias if expressed in meters). Unknown such biases will have to be solved for during the post processing The small differences (modulo 1 second) between Galileo system time, GLONASS system time, UTC(SU), UTC(USNO) and GPS system time have to be dealt with during the post-processing and not before the RINEX conversion. It may also be necessary to solve for remaining differences during the post-processing. 8.2 Pseudorange definition The pseudorange (code) measurement is defined to be equivalent to the difference of the time of reception (expressed in the time frame of the receiver) and the time of transmission (expressed in the time frame of the satellite) of a distinct satellite signal. In a mixed-mode GPS/GLONASS/Galileo receiver referring all pseudorange observations to one receiver clock only, – the raw GLONASS pseudoranges will show the current number of leap seconds between GPS/GAL time and GLONASS time if the receiver clock is running in the GPS or GAL time frame – the raw GPS and Galileo pseudoranges will show the negative number of leap seconds between GPS/GAL time and GLONASS time if the receiver clock is running in the GLONASS time frame In order to avoid misunderstandings and to keep the code observations within the format fields, the pseudoranges must be corrected in this case as follows: PR(GPS) := PR(GPS) + c * DtLS if generated with a receiver clock running in the GLONASS time frame PR(GAL) := PR(GAL) + c * DtLS if generated with a receiver clock running in the GLONASS time frame PR(GLO) := PR(GLO) – c * DtLS if generated with a receiver clock running in the GPS or GAL time frame to remove the contributions of the leap seconds from the pseudoranges. DtLS is the actual number of leap seconds between GPS/GAL and GLO time, as broadcast in the GPS almanac and distributed in Circular T of BIPM. RINEX Version 3.01 Description 19 rinex301_2009_06_22.doc 23.06.2009 11:03 8.3 RINEX navigation message files The header section of the RINEX version 3.00 navigation message files have been slightly changed compared to the previous version 2. The format of the header section is identical for all satellite systems, i.e., GPS, GLONASS, Galileo, SBAS. The data portion of the navigation message files contain records with floating point numbers. The format is identical for all satellite systems, the number of records per message and the contents, however, are satellite system-dependent. The format of the version 3 data records has been changed slightly, the satellite codes now contain also the satellite system identifier. It is possible to generate mixed navigation message files, i.e. files containing navigation messages of more than one satellite system. Header records with system-dependent contents have to be repeated for each satellite system, if applicable. Using the satellite system identifier of the satellite code the reading program can determine the number of data records to be read for each message block. The time tags of the navigation messages (e.g., time of ephemeris, time of clock) are given in the respective satellite time systems! It is recommended to avoid storing redundant navigation messages (e.g., the same message upload broadcast at different times) into the RINEX file. 8.3.1 RINEX navigation message files for GLONASS The header section and the first data record (epoch, satellite clock information) are equal to the GPS navigation file. The following three records contain the satellite position, velocity and acceleration, the clock and frequency biases as well as auxiliary information as health, satellite frequency (channel), age of the information. The corrections of the satellite time to UTC are as follows: GPS: Tutc = Tsv – af0 – af1 *(Tsv-Toc) – … – A0 – … – DtLS GLONASS: Tutc = Tsv + TauN – GammaN*(Tsv-Tb) + TauC In order to use the same sign conventions for the GLONASS corrections as in the GPS navigation files, the broadcast GLONASS values are stored as -TauN, +GammaN, -TauC. The time tags in the GLONASS navigation files are given in UTC (i.e. not Moscow time or GPS time). File naming convention: See above. 8.3.2 RINEX navigation message files for Galileo The Galileo Open Service allows access to two navigation message types: F/NAV (Freely Accessible Navigation) and I/NAV (Integrity Navigation). The contents of the two messages differs in various items, however, in general it is very similar to the contents of the GPS navigation, e.g. the orbit parameterization is the same. The data blocks of the Galileo RINEX navigation messages are identical to a large extent. RINEX Version 3.01 Description 20 rinex301_2009_06_22.doc 23.06.2009 11:03 There are items in the navigation message that depend on the origin of the message (F/NAV or I/NAV): The SV clock parameters actually define the satellite clock for the dual-frequency ionosphere-free linear combination. F/NAV reports the clock parameters valid for the E5a-E1 combination, the I/NAV reports the parameters for the E5b-E1 combination. The second parameter in the Broadcast Orbit 5 record (bits 8 and 9) indicate the frequency pair the stored clock corrections are valid for. Some parameters contain the information stored bitwise. The interpretation is as follows: – Convert the floating point number read from the RINEX file into the nearest integer – Extract the values of the requested bits from the integer Example: 0.170000000000D+02 -> 17 = 24+20 -> Bits 4 and 0 are set, all others are zero
As mentioned above, the GAL week in the RINEX navigation message files is a continuous number, it has
been aligned to the GPS week by the program creating the RINEX file.
8.3.3 RINEX navigation message files for GEO satellites
As the GEO broadcast orbit format differs from the GPS message a special GEO navigation message file
format has been defined which is nearly identical with the GLONASS navigation message file format.
The header section contains information about the generating program, comments, and the difference between
the GEO system time and UTC.
The first data record contains the epoch and satellite clock information, the following records contain the
satellite position, velocity and acceleration and auxiliary information such as health, age of the data, etc.
The time tags in the GEO navigation files are given in the GPS time frame, i.e. not UTC.
The corrections of the satellite time to UTC are as follows:
GEO: Tutc = Tsv – aGf0 – aGf1 *(Tsv-Toe) – W0 – DtLS
W0 being the correction to transform the GEO system time to UTC. Toe, aGf0, aGf1 see below in the format
definition tables.
The Transmission Time of Message (PRN / EPOCH / SV CLK header record) is expressed in GPS seconds
of the week. It marks the beginning of the message transmission. It has to refer to the same GPS week
as the Epoch of Ephemerides. It has to be adjusted by – or + 604800 seconds, if necessary (which would
make it lower than zero or larger than 604800, respectively). It is a redefinition of the Version 2.10 Message
frame time.
Health shall be defined as follows:
– bits 0 to 3 equal to health in Message Type 17 (MT17)
– bit 4 is set to 1 if MT17 health is unavailable
– bit 5 is set to 1 if the URA index is equal to 15
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8.4 RINEX observation files for GEO satellites
A separate satellite system identifier has been defined for the Satellite-Based Augmentation System (SBAS)
payloads: S, to be used in the RINEX VERSION / TYPE header line and in the satellite identifier snn,
nn being the GEO PRN number minus 100.
e.g.: PRN = 120 ⇒ snn = S20
In mixed dual frequency GPS satellite / single frequency GEO payload observation files the fields for the
second frequency observations of SBAS satellites remain blank, are set to zero values or (if last in the record)
can be truncated.
The time system identifier of GEO satellites generating GPS signals defaults to GPS time.
In the SBAS message definitions bit 3 of the health is currently marked as reserved. In case of bit 4 set to 1,
it is recommended to set bits 0,1,2,3 to 1, too.
User Range Accuracy (URA):
The same convention for converting the URA index to meters is used as with GPS. Set URA = 32767 meters
if URA index = 15.
Issue Of Data Navigation (IODN)
The IODN is defined as the 8 first bits after the message type 9, called IODN in RTCA DO229, Annex A
and Annex B and called spare in Annex C.
The CORR TO SYSTEM TIME header record has been replaced by the more general record D-UTC
A0,A1,T,W,S,U in Version 2.11.
9. MODIFICATIONS FOR VERSION 3.01
9.1 Phase Cycle Shifts
Carrier phases tracked on different signal channels or modulation bands of the same frequency may differ in
phase by 1/4 (e.g., GPS: P/Y-code-derived L2 phase vs. L2C-based phase) or, in some exceptional cases, by
other fractional parts of a cycle .
In order to facilitate data processing, phases stored in the RINEX files have to be consistent across all satellites
of a satellite system and a specific frequency within the current RINEX file with respect to such cycle
shifts:
Either one or the other group of phase observations have to be shifted by the respective fraction of a
cycle, either directly by the receiver or by a correction program or the RINEX conversion program,
prior to RINEX file generation, to align them to each other.
The applied corrections are to be reported in a new SYS / PHASE SHIFT header record to allow the
reconstruction of the original values, if needed. The uncorrected group of observations is not reported in the
SYS / PHASE SHIFT records.
In case the reported phase correction of an observation type does not affect all satellites of the same system,
the header record allows to also indicate a list of the respective satellites.
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The SYS / PHASE SHIFT header is mandatory. If the file does not contain any observation pairs affected
by phase shifts or if (exceptionally) the applied corrections are not known, the observation code field
and the rest of the SYS / PHASE SHIFT header record field of the respective satellite system(s) are left
blank.
Sign of the correction Df:
fRINEX = foriginal + Df
foriginal: Uncorrected, i.e. as sent by the satellite
Df: Phase correction to align the phase to other phases of the same
frequency but different channel / modulation band
Example (Definition see Table A1):
—-|—1|0—|—2|0—|—3|0—|—4|0—|—5|0—|—6|0—|—7|0—|—8|
G L2S -0.25000 03 G15 G16 G17 SYS / PHASE SHIFTS
9.2 Galileo: BOC-Tracking of an MBOC-Modulated Signal
Galileo L1 will be modulated by the so-called MBOC modulation. Obviously it is possible for a
receiver to track the signal also in a BOC mode, leading to different noise characteristics, though.
In order to keep this non-standard tracking mode of a MBOC signal apart, bit 2 of the loss-of-lock
indicator LLI (the antispoofing flag not used for Galileo) in the observation data records is used.
Non-standard BOC tracking of an MBOC-modulated signal: Increase the LLI by 4.
Example: Satellite E11, BOC tracking on L1C, LLI = 4:
G 5 C1C L1W L2W C1W S2W SYS / # / OBS TYPES
R 2 C1C L1C SYS / # / OBS TYPES
E 2 L1C L5I SYS / # / OBS TYPES
S 2 C1C L1C SYS / # / OBS TYPES
18.000 INTERVAL
END OF HEADER
> 2006 03 24 13 10 36.0000000 0 5 -0.123456789012
G06 23629347.915 .300 8 -.353 4 23629347.158 24.158
G09 20891534.648 -.120 9 -.358 6 20891545.292 38.123
G12 20607600.189 -.430 9 .394 5 20607600.848 35.234
E11 .32448 .178 7
S20 38137559.506 335849.135 9
9.3 Compass Satellite System Code
A satellite system code for Compass/Beidou has been defined (C), see Table 1.
9.4 New Observation Codes for GPS L1C and Compass
New observation codes for GPS L1C and Compass observables have been defined, see Table 5.
9.5 Header Records for Glonass Slot and Frequency Numbers
In order to make available a cross-reference list between the Glonass slot numbers used in the RINEX files
to designate the Glonass satellites and the allotted frequency numbers, an optional observation file header
RINEX Version 3.01 Description 23
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record is assigned. This allows processing of Glonass files without having to get this information from
Glonass navigation message files or other sources.
RINEX Version 3.01 Description 24
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Example (Definition see Table A1):
—-|—1|0—|—2|0—|—3|0—|—4|0—|—5|0—|—6|0—|—7|0—|—8|
18 R01 1 R02 2 R03 3 R04 4 R05 5 R06 -6 R07 -5 R08 -4 GLONASS SLOT / FRQ #
R09 -3 R10 -2 R11 -1 R12 0 R13 1 R14 2 R15 3 R16 4 GLONASS SLOT / FRQ #
R17 5 R18 -5 GLONASS SLOT / FRQ #
9.6 GNSS Navigation Message File: Leap Seconds Record
The optional LEAP SECONDS record was modified to also include TLS, WNLSF (adjusted to continuous
week number) and DN.
9.7 Clarifications in the Galileo Navigation Message File:
Some clarifications in the Galileo BROADCAST ORBIT – 5 and BROADCAST ORBIT – 6 records were
added (see Table A7).
9.8 RINEX Meteorological Data Files
The version number is adjusted to 3.01.
RINEX Version 3.01 Description 25
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10. REFERENCES
Evans, A. (1989): “Summary of the Workshop on GPS Exchange Formats.” Proceedings of the Fifth International
Geodetic Symposium on Satellite Systems, pp. 917ff, Las Cruces.
Gurtner, W., G. Mader, D. Arthur (1989): “A Common Exchange Format for GPS Data.” CSTG GPS Bulletin
Vol.2 No.3, May/June 1989, National Geodetic Survey, Rockville.
Gurtner, W., G. Mader (1990a): “The RINEX Format: Current Status, Future Developments.” Proceedings
of the Second International Symposium of Precise Positioning with the Global Positioning system, pp. 977ff,
Ottawa.
Gurtner, W., G. Mader (1990b): “Receiver Independent Exchange Format Version 2.” CSTG GPS Bulletin
Vol.3 No.3, Sept/Oct 1990, National Geodetic Survey, Rockville.
Gurtner, W. (1994): “RINEX: The Receiver-Independent Exchange Format.” GPS World, Volume 5, Number
7, July 1994.
Gurtner, W. (2002): “RINEX: The Receiver Independent Exchange Format Version 2.10”.
ftp://igscb.jpl.nasa.gov/igscb/data/format/rinex210.txt
Gurtner, W., L. Estey (2002),: “RINEX Version 2.20 Modifications to Accommodate Low Earth Orbiter
Data”. ftp://ftp.unibe.ch/aiub/rinex/rnx_leo.txt
Gurtner, W., L. Estey (2005): “RINEX: The Receiver Independent Exchange Format Version 2.11”.
ftp://igscb.jpl.nasa.gov/igscb/data/format/rinex211.txt
Gurtner, W., L. Estey (2007): “RINEX: The Receiver Independent Exchange Format Version 3.00”.
ftp://igscb.jpl.nasa.gov/igscb/data/format/rinex300.pdf
Hatanaka, Y (2008): “ A Compression Format and Tools for GNSS Observation Data”. Bulletin of the Geographical
Survey Institute, Vol. 55, pp 21-30, Tsukuba, March 2008.
http://www.gsi.go.jp/ENGLISH/Bulletin55.html
Ray, J., W. Gurtner (1999): “RINEX Extensions to Handle Clock Information”.
ftp://igscb.jpl.nasa.gov/igscb/data/format/rinex_clock.txt.
Ray, J. (2005): “Final update for P1-C1 bias values & cc2noncc”. IGSMail 5260
Rothacher, M., R. Schmid (2005): “ANTEX: The Antenna Exchange Format Version 1.3”.
ftp://igscb.jpl.nasa.gov/pub/station/general/antex13.txt.
Schaer, S., W. Gurtner, J. Feltens (1998): “IONEX: The Ionosphere Map Exchange Format Version 1“.
ftp://igscb.jpl.nasa.gov/igscb/data/format/ionex1.pdf
Suard, N., W. Gurtner, L. Estey (2004): “Proposal for a new RINEX-type Exchange File for GEO SBAS
Broadcast Data”. ftp://igscb.jpl.nasa.gov/igscb/data/format/geo_sbas.txt
Document RTCA DO 229, Appendix A
Document GAL OS SIS ICD/D.0: Galileo Interface Control Document, Revision 0, 23/05/2006, chapter 9.
RINEX Version 3.01 Appendix A1
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APPENDIX: RINEX FORMAT DEFINITIONS AND EXAMPLES
A 1 GNSS Observation Data File – Header Section Description
+—————————————————————————-+
| TABLE A1 |
| GNSS OBSERVATION DATA FILE – HEADER SECTION DESCRIPTION |
+——————–+——————————————+————+
| HEADER LABEL | DESCRIPTION | FORMAT |
| (Columns 61-80) | | |
+——————–+——————————————+————+
|RINEX VERSION / TYPE| – Format version : 3.01 | F9.2,11X, |
| | – File type: O for Observation Data | A1,19X, |
| | – Satellite System: G: GPS | A1,19X |
| | R: GLONASS | |
| | E: Galileo | |
| | S: SBAS payload | |
| | M: Mixed | |
+——————–+——————————————+————+
|PGM / RUN BY / DATE | – Name of program creating current file | A20, |
| | – Name of agency creating current file | A20, |
| | – Date and time of file creation | |
| | Format: yyyymmdd hhmmss zone | A20 |
| | zone: 3-4 char. code for time zone. | |
| | UTC recommended! | |
| | LCL if local time with unknown | |
| | local time system code | |
+——————–+——————————————+————+
*|COMMENT | Comment line(s) | A60 |*
+——————–+——————————————+————+
|MARKER NAME | Name of antenna marker | A60 |
+——————–+——————————————+————+
*|MARKER NUMBER | Number of antenna marker | A20 |*
+——————–+——————————————+————+
|MARKER TYPE | Type of the marker: | A20,40X |
| | | |
| | GEODETIC : Earth-fixed, high- | |
| | precision monumentation | |
| | NON_GEODETIC : Earth-fixed, low- | |
| | precision monumentation | |
| | NON_PHYSICAL : Generated from network | |
| | processing | |
| | SPACEBORNE : Orbiting space vehicle | |
| | AIRBORNE : Aircraft, balloon, etc. | |
| | WATER_CRAFT : Mobile water craft | |
| | GROUND_CRAFT : Mobile terrestrial vehicle| |
| | FIXED_BUOY : “Fixed” on water surface | |
| | FLOATING_BUOY: Floating on water surface | |
| | FLOATING_ICE : Floating ice sheet, etc. | |
| | GLACIER : “Fixed” on a glacier | |
| | BALLISTIC : Rockets, shells, etc | |
| | ANIMAL : Animal carrying a receiver| |
| | HUMAN : Human being | |
| | | |
| | Record required except for GEODETIC | |
| | and NON_GEODETIC marker types. | |
| | | |
| | Users may define other project-dependent | |
| | keywords. | |
+——————–+——————————————+————+
|OBSERVER / AGENCY | Name of observer / agency | A20,A40 |
+——————–+——————————————+————+
|REC # / TYPE / VERS | Receiver number, type, and version | 3A20 |
| | (Version: e.g. Internal Software Version)| |
+——————–+——————————————+————+
|ANT # / TYPE | Antenna number and type | 2A20 |
+——————–+——————————————+————+
|APPROX POSITION XYZ | Geocentric approximate marker position | 3F14.4 |
| | (Units: Meters, System: ITRS recommended)| |
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| | Optional for moving platforms | |
+——————–+——————————————+————+
|ANTENNA: DELTA H/E/N| – Antenna height: Height of the antenna | F14.4, |
| | reference point (ARP) above the marker | |
| | – Horizontal eccentricity of ARP | 2F14.4 |
| | relative to the marker (east/north) | |
| | All units in meters | |
+——————–+——————————————+————+
*|ANTENNA: DELTA X/Y/Z| Position of antenna reference point for | 3F14.4 |*
| | antenna on vehicle (m): | |
| | XYZ vector in body-fixed coord. system | |
+——————–+——————————————+————+
*|ANTENNA: PHASECENTER| Average phase center position w/r to | |*
| | antenna reference point (m) | |
| | – Satellite system (G/R/E/S) | A1, |
| | – Observation code | 1X,A3, |
| | – North/East/Up (fixed station) or | F9.4, |
| | X/Y/Z in body-fixed system (vehicle) | 2F14.4 |
+——————–+——————————————+————+
*|ANTENNA: B.SIGHT XYZ| Direction of the “vertical” antenna axis | 3F14.4 |*
| | towards the GNSS satellites. | |
| | Antenna on vehicle: | |
| | Unit vector in body-fixed coord. system | |
| | Tilted antenna on fixed station: | |
| | Unit vector in N/E/Up left-handed system| |
+——————–+——————————————+————+
*|ANTENNA: ZERODIR AZI| Azimuth of the zero-direction of a | F14.4 |*
| | fixed antenna (degrees, from north) | |
+——————–+——————————————+————+
*|ANTENNA: ZERODIR XYZ| Zero-direction of antenna | 3F14.4 |*
| | Antenna on vehicle: | |
| | Unit vector in body-fixed coord. system | |
| | Tilted antenna on fixed station: | |
| | Unit vector in N/E/Up left-handed system| |
+——————–+——————————————+————+
*|CENTER OF MASS: XYZ | Current center of mass (X,Y,Z, meters) of| 3F14.4 |*
| | vehicle in body-fixed coordinate system. | |
| | Same system as used for attitude. | |
+——————–+——————————————+————+
|SYS / # / OBS TYPES | – Satellite system code (G/R/E/S) | A1, |
| | – Number of different observation types | 2X,I3, |
| | for the specified satellite system | |
| | – Observation descriptors: | 13(1X,A3) |
| | – Type | |
| | – Band | |
| | – Attribute | |
| | | |
| | Use continuation line(s) for more than | 6X, |
| | 13 observation descriptors. | 13(1X,A3) |
| | | |
| | In mixed files: Repeat for each | |
| | satellite system. | |
| | | |
| | These records should precede any | |
| | SYS / SCALE FACTOR records (see below). | |
| | | |
| | The following observation descriptors | |
| | are defined in RINEX Version 3.00: | |
| | | |
| | Type: | |
| | C = Code / Pseudorange | |
| | L = Phase | |
| | D = Doppler | |
| | S = Raw signal strength | |
| | I = Ionosphere phase delay | |
| | X = Receiver channel numbers | |
| | Band: | |
| | 1 = L1 (GPS,SBAS) | |
| | G1 (GLO) | |
| | E2-L1-E1 (GAL) | |
| | 2 = L2 (GPS) | |
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| | G2 (GLO) | |
| | 5 = L5 (GPS,SBAS) | |
| | E5a (GAL) | |
| | 6 = E6 (GAL) | |
| | 7 = E5b (GAL) | |
| | 8 = E5a+b (GAL) | |
| | 0 for type X (all) | |
| | Attribute: | |
| | P = P code-based (GPS,GLO) | |
| | C = C code-based (SBAS,GPS,GLO) | |
| | Y = Y code-based (GPS) | |
| | M = M code-based (GPS) | |
| | N = codeless (GPS) | |
| | A = A channel (GAL) | |
| | B = B channel (GAL) | |
| | C = C channel (GAL) | |
| | I = I channel (GPS,GAL) | |
| | Q = Q channel (GPS,GAL) | |
| | S = M channel (L2C GPS) | |
| | L = L channel (L2C GPS) | |
| | X = B+C channels (GAL) | |
| | I+Q channels (GPS,GAL) | |
| | M+L channels (GPS) | |
| | W = based on Z-tracking (GPS) | |
| | (see text) | |
| | Z = A+B+C channels (GAL) | |
| | blank : for types I and X (all) | |
| | or unknown tracking mode | |
| | | |
| | All characters in uppercase only! | |
| | | |
| | Units : Phase : full cycles | |
| | Pseudorange : meters | |
| | Doppler : Hz | |
| | SNR etc : receiver-dependent | |
.| | Ionosphere : full cycles | |
| | Channel # : See text | |
| | | |
| | Sign definition: See text. | |
| | | |
| | The sequence of the observations in the | |
| | observation records has to correspond to | |
| | the sequence of the types in this record | |
| | of the respective satellite system. | |
| | | |
| | The attribute can be left blank if not | |
| | known. See text! | |
+——————–+——————————————+————+
*|SIGNAL STRENGTH UNIT| – Unit of the signal strength | A20,40X |*
| | observables Snn (if present) | |
| | | |
| | DBHZ : S/N given in dbHz | |
| | … | |
+——————–+——————————————+————+
*|INTERVAL | Observation interval in seconds | F10.3 |*
+——————–+——————————————+————+
|TIME OF FIRST OBS | – Time of first observation record | 5I6,F13.7, |
| | (4-digit-year, month,day,hour,min,sec) | |
| | – Time system: GPS (=GPS time system) | 5X,A3 |
| | GLO (=UTC time system) | |
| | GAL (=Galileo System Time)| |
| | Compulsory in mixed GNSS files | |
| | Defaults: GPS for pure GPS files | |
| | GLO for pure GLONASS files | |
| | GAL for pure Galileo files | |
+——————–+——————————————+————+
*|TIME OF LAST OBS | – Time of last observation record | 5I6,F13.7, |*
| | (4-digit-year, month,day,hour,min,sec) | |
| | – Time system: Same value as in | 5X,A3 |
| | TIME OF FIRST OBS record | |
+——————–+——————————————+————+
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*|RCV CLOCK OFFS APPL | Epoch, code, and phase are corrected by | I6 |*
| | applying the realtime-derived receiver | |
| | clock offset: 1=yes, 0=no; default: 0=no | |
| | Record required if clock offsets are | |
| | reported in the EPOCH/SAT records | |
+——————–+——————————————+————+
*|SYS / DCBS APPLIED | – Satellite system (G/R/E/S) | A1, |*
| | – Program name used to apply | 1X,A17, |
| | differential code bias corrections | |
| | – Source of corrections (URL) | 1X,A40 |
| | | |
| | Repeat for each satellite system. | |
| | | |
| | No corrections applied: Blank fields or | |
| | record not present. | |
+——————–+——————————————+————+
*|SYS / PCVS APPLIED | – Satellite system (G/R/E/S) | A1, |*
| | – Program name used to apply | 1X,A17, |
| | phase center variation corrections | |
| | – Source of corrections (URL) | 1X,A40 |
| | | |
| | Repeat for each satellite system. | |
| | | |
| | No corrections applied: Blank fields or | |
| | record not present. | |
+——————–+——————————————+————+
*|SYS / SCALE FACTOR | – Satellite system (G/R/E/S) | A1, |*
| | – Factor to divide stored observations | 1X,I4, |
| | with before use (1,10,100,1000) | |
| | – Number of observation types involved. | 2X,I2, |
| | 0 or blank: All observation types | |
| | – List of observation types | 12(1X,A3) |
| | | |
| | Use continuation line(s) for more than | 10X, |
| | 12 observation types. | 12(1X,A3) |
| | | |
| | Repeat record if different factors are | |
| | applied to different observation types. | |
| | | |
| | A value of 1 is assumed if record is | |
| | missing. | |
+——————–+——————————————+————+
|SYS / PHASE SHIFTS | Phase shift correction used to generate | |
| | phases consistent w/r to cycle shifts | |
| | – Satellite system (G/R/E/S/C) | A1,1X, |
| | – Carrier phase observation code | A3,1X, |
| | – Type | |
| | – Band | |
| | – Attribute | |
| | – Correction applied (cycles) | F8.5 |
| | – Number of satellites involved | 2X,I2.2, |
| | 0 or blank: All satellites of system | |
| | – List of satellites | 10(1X,A3) |
| | | |
| | Use continuation line(s) for more than | 18X, |
| | 10 satellites. | 10(1X,A3) |
| | | |
| | Repeat the record for all affected codes.| |
| | | |
| | Leave observation code and rest of the | |
| | field blank if applied corrections for | |
| | the respective satellite system are | |
| | unknown. | |
| | | |
| | phase(RINEX) = phase(orig) + correction | |
| | | |
| | See chapter 9.1! | |
+——————–+——————————————+————+
*|GLONASS SLOT / FRQ #| Glonass slot and frequency numbers | |*
| | – Number of satellites in list | I3,1X, |
| | – List of | |
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| | – Satellite numbers (system code, slot)| 8(A1,I2.2, |
| | – Frequency numbers (-7…+6) | 1X,I2) |
| | | |
| | Use continuation lines for more than | 4X,8(A1, |
| | 8 Satellites | I2.2,1X,I2)|
+——————–+——————————————+————+
*|LEAP SECONDS | – Number of leap seconds since 6-Jan-1980| I6, |*
| | as transmitted by the GPS almanac t_LS| |
| | – Future or past leap seconds t_LSF | I6, |
| | – Respective week number WN_LSF | I6, |
| | (continuous number) | |
| | – Respective day number DN | I6 |
| | (see ICD-GPS-200C 20.3.3.5.2.4) | |
| | Zero or blank if not known | |
+——————–+——————————————+————+
*|# OF SATELLITES | Number of satellites, for which | I6 |*
| | observations are stored in the file | |
+——————–+——————————————+————+
*|PRN / # OF OBS | Satellite numbers, number of observations| 3X, |*
| | for each observation type indicated | A1,I2.2, |
| | in the SYS / # / OBS TYPES record. | 9I6 |
| | | |
| | If more than 9 observation types: | |
| | Use continuation line(s) | 6X,9I6 |
| | | |
| | In order to avoid format overflows, | |
| | 99999 indicates >= 99999 observations | |
| | in the RINEX file. | |
| | | |
| | This record is (these records are) | |
| | repeated for each satellite present in | |
| | the data file | |
+——————–+——————————————+————+
|END OF HEADER | Last record in the header section. | 60X |
+——————–+——————————————+————+
Records marked with * are optional
A 2 GNSS Observation Data File – Data Record Description
+—————————————————————————-+
| TABLE A2 |
| GNSS OBSERVATION DATA FILE – DATA RECORD DESCRIPTION |
+—————————————————————+————+
| DESCRIPTION | FORMAT |
+—————————————————————+————+
| | |
| EPOCH record | |
| | |
| – Record identifier : > | A1, |
| – Epoch : | |
| – year (4 digits) | 1X,I4, |
| – month,day,hour,min (two digits) | 4(1X,I2.2),|
| – sec | F11.7, |
| – Epoch flag | 2X,I1, |
| 0: OK | |
| 1: power failure between previous and current epoch | |
| >1: Special event | |
| – Number of satellites observed in current epoch | I3, |
| (reserved) | 6X, |
| – Receiver clock offset (seconds, optional) | F15.12, ||
+—————————————————————+————+
| | |
| Epoch flag = 0 or 1: OBSERVATION records follow | |
| | |
| – Satellite number | A1,I2.2, |
| | |
| – Observation | repeat within record for each observation| m(F14.3, |
| – LLI | type (same sequence as given in the | I1, |
| – Signal strength | respective SYS / # / OBS TYPES record) | I1) |
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| | |
| This record is repeated for each satellite having been | |
| observed in the current epoch. The record length is given by | |
| the number of observation types for this satellite. | |
| | |
| Observations: Definition see text. | |
| Missing observations are written as 0.0 or blanks. | |
| Phase values overflowing the fixed format F14.3 have to be | |
| clipped into the valid interval (e.g add or subtract 10**9),| |
| set bit 0 of LLI indicator. | |
| | |
| Loss of lock indicator (LLI). | |
| 0 or blank: OK or not known | |
| Bit 0 set : Lost lock between previous and current | |
| observation: Cycle slip possible. | |
| For phase observations only. | |
| Bit 1 set : Half-cycle ambiguity/slip possible. | |
| Software not capable of handling half cycles | |
| should skip this observation. | |
| Valid for the current epoch only. | |
| Bit 2 set : Galileo BOC-tracking of an MBOC-modulated signal| |
| (may suffer from increased noise). | |
| Signal strength projected into interval 1-9: | |
| 1: minimum possible signal strength | |
| 5: average S/N ratio | |
| 9: maximum possible signal strength | |
| 0 or blank: not known, don’t care | |
| Standardization for S/N values given in dbHz: See text. | |
| | |
+—————————————————————+————+
| | |
| Epoch flag 2-5: EVENT: Special records may follow | |
| | |
| – Epoch flag | [2X,I1] |
| 2: start moving antenna | |
| 3: new site occupation (end of kinem. data) | |
| (at least MARKER NAME record follows) | |
| 4: header information follows | |
| 5: external event (epoch is significant, | |
| same time frame as observation time tags) | |
| | |
| – “Number of satellites” contains number of special records | [I3] |
| to follow. 0 if no special records follow. | |
| Maximum number of records: 999 | |
| | |
| For events without significant epoch the epoch fields in | |
| the EPOCH RECORD can be left blank | |
+—————————————————————+————+
| | |
| Epoch flag = 6: EVENT: Cycle slip records follow | |
| | |
| – Epoch flag | [2X,I1] |
| 6: cycle slip records follow to optionally report | |
| detected and repaired cycle slips (same format as | |
| OBSERVATIONS records; | |
| – slip instead of observation; | |
| – LLI and signal strength blank or zero) | |
+—————————————————————+————+
A 3 GNSS Observation Data File – Example
+——————————————————————————+
| TABLE A3 |
| GNSS OBSERVATION DATA FILE – EXAMPLE |
+——————————————————————————+
—-|—1|0—|—2|0—|—3|0—|—4|0—|—5|0—|—6|0—|—7|0—|—8|0-
3.01 OBSERVATION DATA M RINEX VERSION / TYPE
G = GPS R = GLONASS E = GALILEO S = GEO M = MIXED COMMENT
RINEX Version 3.01 Appendix A7
rinex301_2009_06_22.doc 23.06.2009 11:03
XXRINEXO V9.9 AIUB 20060324 144333 UTC PGM / RUN BY / DATE
EXAMPLE OF A MIXED RINEX FILE VERSIOIN 3.01 COMMENT
The file contains L1 pseudorange and phase data of the COMMENT
geostationary AOR-E satellite (PRN 120 = S20) COMMENT
A 9080 MARKER NAME
9080.1.34 MARKER NUMBER
BILL SMITH ABC INSTITUTE OBSERVER / AGENCY
X1234A123 GEODETIC 1.3.1 REC # / TYPE / VERS
G1234 ROVER ANT # / TYPE
4375274. 587466. 4589095. APPROX POSITION XYZ
.9030 .0000 .0000 ANTENNA: DELTA H/E/N
0 RCV CLOCK OFFS APPL
G 5 C1C L1W L2W C1W S2W SYS / # / OBS TYPES
R 2 C1C L1C SYS / # / OBS TYPES
E 2 L1B L5I SYS / # / OBS TYPES
S 2 C1C L1C SYS / # / OBS TYPES
18.000 INTERVAL
G APPL_DCB xyz.uvw.abc//pub/dcb_gps.dat SYS / DCBS APPLIED
DBHZ SIGNAL STRENGTH UNIT
2006 03 24 13 10 36.0000000 GPS TIME OF FIRST OBS
END OF HEADER
> 2006 03 24 13 10 36.0000000 0 5 -0.123456789012
G06 23629347.915 .300 8 -.353 4 23629347.158 24.158
G09 20891534.648 -.120 9 -.358 6 20891545.292 38.123
G12 20607600.189 -.430 9 .394 5 20607600.848 35.234
E11 .324 8 .178 7
S20 38137559.506 335849.135 9
> 2006 03 24 13 10 54.0000000 0 7 -0.123456789210
G06 23619095.450 -53875.632 8 -41981.375 4 23619095.008 25.234
G09 20886075.667 -28688.027 9 -22354.535 7 20886076.101 42.231
G12 20611072.689 18247.789 9 14219.770 6 20611072.410 36.765
R21 21345678.576 12345.567 5
R22 22123456.789 23456.789 5
E11 65432.123 5 48861.586 7
S20 38137559.506 335849.135 9
> 2006 03 24 13 11 12.0000000 2 2
*** FROM NOW ON KINEMATIC DATA! *** COMMENT
TWO COMMENT LINES FOLLOW DIRECTLY THE EVENT RECORD COMMENT
> 2006 3 24 13 11 12.0000000 0 4 -0.123456789876
G06 21110991.756 16119.980 7 12560.510 4 21110991.441 25.543
G09 23588424.398 -215050.557 6 -167571.734 6 23588424.570 41.824
G12 20869878.790 -113803.187 8 -88677.926 6 20869878.938 36.961
G16 20621643.727 73797.462 7 57505.177 2 20621644.276 15.368
> 3 4
A 9081 MARKER NAME
9081.1.34 MARKER NUMBER
.9050 .0000 .0000 ANTENNA: DELTA H/E/N
–> THIS IS THE START OF A NEW SITE <– COMMENT > 2006 03 24 13 12 6.0000000 0 4 -0.123456987654
G06 21112589.384 24515.877 6 19102.763 4 21112589.187 25.478
G09 23578228.338 -268624.234 7 -209317.284 6 23578228.398 41.725
G12 20625218.088 92581.207 7 72141.846 5 20625218.795 35.143
G16 20864539.693 -141858.836 8 -110539.435 2 20864539.943 16.345
> 2006 03 24 13 13 1.2345678 5 0
> 4 2
AN EVENT FLAG 5 WITH A SIGNIFICANT EPOCH COMMENT
AND AN EVENT FLAG 4 TO ESCAPE FOR THE TWO COMMENT LINES COMMENT
> 2006 03 24 13 14 12.0000000 0 4 -0.123456012345
G06 21124965.133 0.30213 -0.62614 21124965.275 27.528
G09 23507272.372 -212616.150 7 -165674.789 7 23507272.421 42.124
G12 20828010.354 -333820.093 6 -260119.395 6 20828010.129 37.002
G16 20650944.902 227775.130 7 177487.651 3 20650944.363 18.040
> 4 1
*** LOST LOCK ON G 06 COMMENT
.
.
.
> 4 1
END OF FILE COMMENT
—-|—1|0—|—2|0—|—3|0—|—4|0—|—5|0—|—6|0—|—7|0—|—8|0-
RINEX Version 3.01 Appendix A8
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A 4 GNSS Navigation Message File – Header Section Description
+—————————————————————————-+
| TABLE A4 |
| GNSS NAVIGATION MESSAGE FILE – HEADER SECTION DESCRIPTION |
+——————–+——————————————+————+
| HEADER LABEL | DESCRIPTION | FORMAT |
| (Columns 61-80) | | |
+——————–+——————————————+————+
|RINEX VERSION / TYPE| – Format version : 3.01 | F9.2,11X, |
| | – File type (‘N’ for navigation data) | A1,19X, |
| | – Satellite System: G: GPS | A1,19X |
| | R: GLONASS | |
| | E: Galileo | |
| | S: SBAS Payload | |
| | M: Mixed | |
+——————–+——————————————+————+
|PGM / RUN BY / DATE | – Name of program creating current file | A20, |
| | – Name of agency creating current file | A20, |
| | – Date and time of file creation | |
| | Format: yyyymmdd hhmmss zone | A20 |
| | zone: 3-4 char. code for time zone. | |
| | ‘UTC ‘ recommended! | |
| | ‘LCL ‘ if local time with un- | |
| | known local time system code | |
+——————–+——————————————+————+
*|COMMENT | Comment line(s) | A60 |*
+——————–+——————————————+————+
*|IONOSPHERIC CORR | Ionospheric correction parameters | |*
| | – Correction type | A4,1X, |
| | GAL = Galileo ai0 – ai2 | |
| | GPSA = GPS alpha0 – alpha3 | |
| | GPSB = GPS beta0 – beta3 | |
| | – Parameters | 4D12.4 |
| | GPS: alpha0-alpha3 or beta0-beta3 | |
| | GAL: ai0, ai1, ai2, zero | |
+——————–+——————————————+————+
*|TIME SYSTEM CORR | Corrections to transform the system time | |*
| | to UTC or other time systems | |
| | – Correction type | A4,1X, |
| | GAUT = GAL to UTC a0, a1 | |
| | GPUT = GPS to UTC a0, a1 | |
| | SBUT = SBAS to UTC a0, a1 | |
| | GLUT = GLO to UTC a0=TauC, a1=zero | |
| | GPGA = GPS to GAL a0=A0G, a1=A1G | |
| | GLGP = GLO to GPS a0=TauGPS, a1=zero | |
| | – a0,a1 Coefficients of 1-deg polynomial | D17.10, |
| | (a0 sec, a1 sec/sec) | D16.9, |
| | CORR(s) = a0 + a1*DELTAT | |
| | – T Reference time for polynomial | I7, |
| | (Seconds into GPS/GAL week) | |
| | – W Reference week number | I5, |
| | (GPS/GAL week, continuous number) | |
| | T and W zero for GLONASS. | |
| | – S EGNOS, WAAS, or MSAS … | 1X,A5,1X |
| | (left-justified) | |
| | Derived from MT17 service provider. | |
| | If not known: Use Snn with | |
| | nn = PRN-100 of satellite | |
| | broadcasting the MT12 | |
| | – U UTC Identifier (0 if unknown) | I2,1X |
| | 1=UTC(NIST), 2=UTC(USNO), 3=UTC(SU), | |
| | 4=UTC(BIPM), 5=UTC(Europe Lab), | |
| | 6=UTC(CRL), >6 = not assigned yet | |
| | S and U for SBAS only. | |
+——————–+——————————————+————+
*|LEAP SECONDS | – Number of leap seconds since 6-Jan-1980| I6, |*
| | as transmitted by the GPS almanac t_LS| |
| | – Future or past leap seconds t_LSF | I6, |
| | – Respective week number WN_LSF | I6, |
RINEX Version 3.01 Appendix A9
rinex301_2009_06_22.doc 23.06.2009 11:03
| | (continuous number) | |
| | – Respective day number DN | I6 |
| | (see ICD-GPS-200C 20.3.3.5.2.4) | |
| | Zero or blank if not known | |
+——————–+——————————————+————+
|END OF HEADER | Last record in the header section. | 60X |
+——————–+——————————————+————+
Records marked with * are optional
A 5 GNSS Navigation Message File – GPS Data Record Description
+—————————————————————————-+
| TABLE A5 |
| GNSS NAVIGATION MESSAGE FILE – GPS DATA RECORD DESCRIPTION |
+——————–+——————————————+————+
| OBS. RECORD | DESCRIPTION | FORMAT |
+——————–+——————————————+————+
|SV / EPOCH / SV CLK | – Satellite system (G), sat number (PRN)| A1,I2.2, |
| | – Epoch: Toc – Time of Clock (GPS)| |
| | – year (4 digits) | 1X,I4, |
| | – month,day,hour,minute,second | 5(1X,I2.2),|
| | – SV clock bias (seconds) | 3D19.12 |
| | – SV clock drift (sec/sec) | |
| | – SV clock drift rate (sec/sec2) | *) |
+——————–+——————————————+————+
| BROADCAST ORBIT – 1| – IODE Issue of Data, Ephemeris | 4X,4D19.12 |
| | – Crs (meters) | |
| | – Delta n (radians/sec) | ***) |
| | – M0 (radians) | |
+——————–+——————————————+————+
| BROADCAST ORBIT – 2| – Cuc (radians) | 4X,4D19.12 |
| | – e Eccentricity | |
| | – Cus (radians) | |
| | – sqrt(A) (sqrt(m)) | |
+——————–+——————————————+————+
| BROADCAST ORBIT – 3| – Toe Time of Ephemeris (sec of GPS week)| 4X,4D19.12 |
| | – Cic (radians) | |
| | – OMEGA0 (radians) | |
| | – Cis (radians) | |
+——————–+——————————————+————+
| BROADCAST ORBIT – 4| – i0 (radians) | 4X,4D19.12 |
| | – Crc (meters) | |
| | – omega (radians) | |
| | – OMEGA DOT (radians/sec) | |
+——————–+——————————————+————+
| BROADCAST ORBIT – 5| – IDOT (radians/sec) | 4X,4D19.12 |
| | – Codes on L2 channel | |
| | – GPS Week # (to go with TOE) | |
| | Continuous number, not mod(1024)! | |
| | – L2 P data flag | |
+——————–+——————————————+————+
| BROADCAST ORBIT – 6| – SV accuracy (meters) | 4X,4D19.12 |
| | – SV health (bits 17-22 w 3 sf 1)| |
| | – TGD (seconds) | |
| | – IODC Issue of Data, Clock | |
+——————–+——————————————+————+
| BROADCAST ORBIT – 7| – Transmission time of message **) | 4X,4D19.12 |
| | (sec of GPS week, derived e.g. | |
| | from Z-count in Hand Over Word (HOW) | |
| | – Fit interval (hours) | |
| | (see ICD-GPS-200, 20.3.4.4) | |
| | Zero if not known | |
| | – spare | |
| | – spare | |
+——————–+——————————————+————+
*) In order to account for the various compilers, E,e,D, and d are allowed letters between the fraction and exponent of
all floating point numbers in the navigation message files. Zero-padded two-digit exponents are required, however.
RINEX Version 3.01 Appendix A10
rinex301_2009_06_22.doc 23.06.2009 11:03
**) Adjust the Transmission time of message by + or – 604800 to refer to the reported week in BROADCAST ORBIT –
5, if necessary. Set value to 0.9999E9 if not known.
A 6 GPS Navigation Message File – Example
+——————————————————————————+
| TABLE A6 |
| GPS NAVIGATION MESSAGE FILE – EXAMPLE |
+——————————————————————————+
—-|—1|0—|—2|0—|—3|0—|—4|0—|—5|0—|—6|0—|—7|0—|—8|
3.01 N: GNSS NAV DATA G: GPS RINEX VERSION / TYPE
XXRINEXN V3 AIUB 19990903 152236 UTC PGM / RUN BY / DATE
EXAMPLE OF VERSION 3.00 FORMAT COMMENT
GPSA .1676D-07 .2235D-07 .1192D-06 .1192D-06 IONOSPHERIC CORR
GPSB .1208D+06 .1310D+06 -.1310D+06 -.1966D+06 IONOSPHERIC CORR
GPUT .1331791282D-06 .107469589D-12 552960 1025 TIME SYSTEM CORR
13 LEAP SECONDS
END OF HEADER
G06 1999 09 02 17 51 44 -.839701388031D-03 -.165982783074D-10 .000000000000D+00
.910000000000D+02 .934062500000D+02 .116040547840D-08 .162092304801D+00
.484101474285D-05 .626740418375D-02 .652112066746D-05 .515365489006D+04
.409904000000D+06 -.242143869400D-07 .329237003460D+00 -.596046447754D-07
.111541663136D+01 .326593750000D+03 .206958726335D+01 -.638312302555D-08
.307155651409D-09 .000000000000D+00 .102500000000D+04 .000000000000D+00
.000000000000D+00 .000000000000D+00 .000000000000D+00 .910000000000D+02
.406800000000D+06 .000000000000D+00
G13 1999 09 02 19 00 00 .490025617182D-03 .204636307899D-11 .000000000000D+00
.133000000000D+03 -.963125000000D+02 .146970407622D-08 .292961152146D+01
-.498816370964D-05 .200239347760D-02 .928156077862D-05 .515328476143D+04
.414000000000D+06 -.279396772385D-07 .243031939942D+01 -.558793544769D-07
.110192796930D+01 .271187500000D+03 -.232757915425D+01 -.619632953057D-08
-.785747015231D-11 .000000000000D+00 .102500000000D+04 .000000000000D+00
.000000000000D+00 .000000000000D+00 .000000000000D+00 .389000000000D+03
.410400000000D+06 .000000000000D+00
—-|—1|0—|—2|0—|—3|0—|—4|0—|—5|0—|—6|0—|—7|0—|—8|
A 7 GNSS Navigation Message File – GALILEO Data Record Description
+—————————————————————————-+
| TABLE A7 |
| GNSS NAVIGATION MESSAGE FILE – GALILEO DATA RECORD DESCRIPTION |
+——————–+——————————————+————+
| OBS. RECORD | DESCRIPTION | FORMAT |
+——————–+——————————————+————+
|SV / EPOCH / SV CLK | – Satellite system (E), satellite number | A1,I2.2, |
| | – Epoch: Toc – Time of Clock GAL| |
| | – year (4 digits) | 1X,I4, |
| | – month,day,hour,minute,second | 5(1X,I2.2),|
| | – SV clock bias (seconds) af0| 3D19.12 |
| | – SV clock drift (sec/sec) af1| |
| | – SV clock drift rate (sec/sec2) af2| *) |
| | (see Br.Orbit-5, data source, bits 8+9)| |
+——————–+——————————————+————+
| BROADCAST ORBIT – 1| – IODnav Issue of Data of the nav batch | 4X,4D19.12 |
| | – Crs (meters) | |
| | – Delta n (radians/sec) | ***) |
| | – M0 (radians) | |
+——————–+——————————————+————+
| BROADCAST ORBIT – 2| – Cuc (radians) | 4X,4D19.12 |
| | – e Eccentricity | |
| | – Cus (radians) | |
| | – sqrt(a) (sqrt(m)) | |
+——————–+——————————————+————+
| BROADCAST ORBIT – 3| – Toe Time of Ephemeris (sec of GAL week)| 4X,4D19.12 |
| | – Cic (radians) | |
| | – OMEGA0 (radians) | |
RINEX Version 3.01 Appendix A11
rinex301_2009_06_22.doc 23.06.2009 11:03
| | – Cis (radians) | |
+——————–+——————————————+————+
| BROADCAST ORBIT – 4| – i0 (radians) | 4X,4D19.12 |
| | – Crc (meters) | |
| | – omega (radians) | |
| | – OMEGA DOT (radians/sec) | |
+——————–+——————————————+————+
| BROADCAST ORBIT – 5| – IDOT (radians/sec) | 4X,4D19.12 |
| | – Data sources (FLOAT –> INTEGER) | |
| | Bit 0 set: I/NAV E1-B | |
| | Bit 1 set: F/NAV E5a-I | |
| | Bit 2 set: I/NAV E5b-I | |
| | Bits 0-2 : non-exclusive | |
| | Bit 3 reserved for Galileo internal use| |
| | Bit 4 reserved for Galileo internal use| |
| | Bit 8 set: af0-af2, Toc, SISA are | |
| | for E5a,E1 | |
| | Bit 9 set: af0-af2, Toc, SISA are | |
| | for E5b,E1 | |
| | – GAL Week # (to go with Toe) | ****) |
| | – spare | |
+——————–+——————————————+————+
| BROADCAST ORBIT – 6| – SISA Signal in space accuracy (meters) | 4X,4D19.12 |
| | Undefined/unknown: -1.0 | |
| | – SV health (FLOAT converted to INTEGER) | *****) |
| | Bit 0: E1B DVS | |
| | Bits 1-2: E1B HS | |
| | Bit 3: E5a DVS | |
| | Bits 4-5: E5a HS | |
| | Bit 6: E5b DVS | |
| | Bits 7-8: E5b HS | |
| | – BGD E5a/E1 (seconds) | |
| | – BGD E5b/E1 (seconds) | |
+——————–+——————————————+————+
| BROADCAST ORBIT – 7| – Transmission time of message **) | 4X,4D19.12 |
| | (sec of GAL week, derived | |
| | from WN and TOW of page type 1) | |
| | – spare | |
| | – spare | |
| | – spare | |
+——————–+——————————————+————+
*) In order to account for the various compilers, E,e,D, and d are allowed letters between the fraction and exponent of
all floating point numbers in the navigation message files. Zero-padded two-digit exponents are required, however.
**) Adjust the Transmission time of message by + or – 604800 to refer to the reported week in BROADCAST ORBIT –
5, if necessary. Set value to 0.9999E9 if not known.
***) Angles and their derivatives transmitted in units of semi-circles and semi-circles/sec have to be converted to radians
by the RINEX generator.
****) The GAL week number is a continuous number, aligned to (and hence identical to) the continuous GPS week
number used in the RINEX navigation message files. The broadcast 12-bit Galileo System Time week has a roll-over
after 4095. It started at zero at the first GPS roll-over (continuous GPS week 1024). Hence GAL week = GST week +
1024 + n*4096 (n: number of GST roll-overs).
*****)
– If bit 0 or bit 2 of Data sources (BROADCAST ORBIT – 5) is set, E1B DVS & HS, E5b DVS & HS and both BGDs are
valid.
– If bit 1 of Data sources is set, E5a DVS & HS and BGD E5a/E1 are valid.
– Non valid parameters are set to 0 and to be ignored
RINEX Version 3.01 Appendix A12
rinex301_2009_06_22.doc 23.06.2009 11:03
A 8 GALILEO Navigation Message File – Example
+——————————————————————————+
| TABLE A8 |
| GALILEO NAVIGATION MESSAGE FILE – EXAMPLE |
+——————————————————————————+
—-|—1|0—|—2|0—|—3|0—|—4|0—|—5|0—|—6|0—|—7|0—|—8|
3.01 N: GNSS NAV DATA E: GALILEO RINEX VERSION / TYPE
XXRINEXN V3 AIUB 20060902 192236 UTC PGM / RUN BY / DATE
EXAMPLE OF VERSION 3.00 FORMAT COMMENT
To be supplied later
—-|—1|0—|—2|0—|—3|0—|—4|0—|—5|0—|—6|0—|—7|0—|—8|
A 9 GNSS Navigation Message File – GLONASS Data Record Description
+—————————————————————————-+
| TABLE A9 |
| GNSS NAVIGATION MESSAGE FILE – GLONASS DATA RECORD DESCRIPTION |
+——————–+——————————————+————+
| OBS. RECORD | DESCRIPTION | FORMAT |
+——————–+——————————————+————+
|SV / EPOCH / SV CLK | – Satellite system (R), satellite number | A1,I2.2, |
| | (slot number in sat. constellation) | |
| | – Epoch: Toc – Time of Clock (UTC)| |
| | – year (4 digits) | 1X,I4, |
| | – month,day,hour,minute,second | 5(1X,I2.2),|
| | – SV clock bias (sec) (-TauN)| 3D19.12 |
| | – SV relative frequency bias (+GammaN)| |
| | – Message frame time (tk+nd*86400)| *) |
| | in seconds of the UTC week | |
+——————–+——————————————+————+
| BROADCAST ORBIT – 1| – Satellite position X (km) | 4X,4D19.12 |
| | – velocity X dot (km/sec) | |
| | – X acceleration (km/sec2) | |
| | – health (0=OK) (Bn)| |
+——————–+——————————————+————+
| BROADCAST ORBIT – 2| – Satellite position Y (km) | 4X,4D19.12 |
| | – velocity Y dot (km/sec) | |
| | – Y acceleration (km/sec2) | |
| | – frequency number(-7…+12) | |
+——————–+——————————————+————+
| BROADCAST ORBIT – 3| – Satellite position Z (km) | 4X,4D19.12 |
| | – velocity Z dot (km/sec) | |
| | – Z acceleration (km/sec2) | |
| | – Age of oper. information (days) (E) | |
+——————–+——————————————+————+
*) In order to account for the various compilers, E,e,D, and d are allowed letters between the fraction and exponent of
all floating point numbers in the navigation message files. Zero-padded two-digit exponents are required, however.
A 10 GNSS Navigation Message File – Example: Mixed GPS / GLONASS
+——————————————————————————+
| TABLE A10 |
| GNSS NAVIGATION MESSAGE FILE – EXAMPLE MIXED GPS/GLONASS |
+——————————————————————————+
—-|—1|0—|—2|0—|—3|0—|—4|0—|—5|0—|—6|0—|—7|0—|—8|
3.01 N: GNSS NAV DATA M: MIXED RINEX VERSION / TYPE
XXRINEXN V3 AIUB 20061002 000123 UTC PGM / RUN BY / DATE
EXAMPLE OF VERSION 3.00 FORMAT COMMENT
GPSA 0.1025E-07 0.7451E-08 -0.5960E-07 -0.5960E-07 IONOSPHERIC CORR
GPSB 0.8806E+05 0.0000E+00 -0.1966E+06 -0.6554E+05 IONOSPHERIC CORR
RINEX Version 3.01 Appendix A13
rinex301_2009_06_22.doc 23.06.2009 11:03
GPUT 0.2793967723E-08 0.000000000E+00 147456 1395 TIME SYSTEM CORR
GLUT 0.7823109626E-06 0.000000000E+00 0 1395 TIME SYSTEM CORR
14 LEAP SECONDS
END OF HEADER
G01 2006 10 01 00 00 00 0.798045657575E-04 0.227373675443E-11 0.000000000000E+00
0.560000000000E+02-0.787500000000E+01 0.375658504827E-08 0.265129935612E+01
-0.411644577980E-06 0.640150101390E-02 0.381097197533E-05 0.515371852875E+04
0.000000000000E+00 0.782310962677E-07 0.188667086536E+00-0.391155481338E-07
0.989010441512E+00 0.320093750000E+03-0.178449589759E+01-0.775925177541E-08
0.828605943335E-10 0.000000000000E+00 0.139500000000E+04 0.000000000000E+00
0.200000000000E+01 0.000000000000E+00-0.325962901115E-08 0.560000000000E+02
-0.600000000000E+02 0.400000000000E+01
G02 2006 10 01 00 00 00 0.402340665460E-04 0.386535248253E-11 0.000000000000E+00
0.135000000000E+03 0.467500000000E+02 0.478269921862E-08-0.238713891022E+01
0.250712037086E-05 0.876975362189E-02 0.819191336632E-05 0.515372778320E+04
0.000000000000E+00-0.260770320892E-07-0.195156738598E+01 0.128522515297E-06
0.948630520258E+00 0.214312500000E+03 0.215165003775E+01-0.794140221985E-08
-0.437875382124E-09 0.000000000000E+00 0.139500000000E+04 0.000000000000E+00
0.200000000000E+01 0.000000000000E+00-0.172294676304E-07 0.391000000000E+03
-0.600000000000E+02 0.400000000000E+01
R01 2006 10 01 00 15 00-0.137668102980E-04-0.454747350886E-11 0.900000000000E+02
0.157594921875E+05-0.145566368103E+01 0.000000000000E+00 0.000000000000E+00
-0.813711474609E+04 0.205006790161E+01 0.931322574615E-09 0.700000000000E+01
0.183413398438E+05 0.215388488770E+01-0.186264514923E-08 0.100000000000E+01
R02 2006 10 01 00 15 0-0.506537035108E-04 0.181898940355E-11 0.300000000000E+02
0.155536342773E+05-0.419384956360E+00 0.000000000000E+00 0.000000000000E+00
-0.199011298828E+05 0.324192047119E+00-0.931322574615E-09 0.100000000000E+01
0.355333544922E+04 0.352666091919E+01-0.186264514923E-08 0.100000000000E+01
—-|—1|0—|—2|0—|—3|0—|—4|0—|—5|0—|—6|0—|—7|0—|—8|
A 11 GNSS Navigation Message File – SBAS Data Record Description
+—————————————————————————-+
| TABLE A11 |
| GNSS NAVIGATION MESSAGE FILE – SBAS DATA RECORD DESCRIPTION |
+——————–+——————————————+————+
| OBS. RECORD | DESCRIPTION | FORMAT |
+——————–+——————————————+————+
|SV / EPOCH / SV CLK | – Satellite system (S), satellite number | A1,I2.2, |
| | (slot number in sat. constellation) | |
| | – Epoch: Toc – Time of Clock (UTC)| |
| | – year (4 digits) | 1X,I4, |
| | – month,day,hour,minute,second | 5(1X,I2.2),|
| | – SV clock bias (sec) (aGf0)| 3D19.12, |
| | – SV relative frequency bias (aGf1)| |
| | – Transmission time of message | *) |
| | (start of the message) | |
| | in GPS seconds of the week | |
+——————–+——————————————+————+
| BROADCAST ORBIT – 1| – Satellite position X (km) | 4X,4D19.12 |
| | – velocity X dot (km/sec) | |
| | – X acceleration (km/sec2) | |
| | – health (0=OK) | |
+——————–+——————————————+————+
| BROADCAST ORBIT – 2| – Satellite position Y (km) | 4X,4D19.12 |
| | – velocity Y dot (km/sec) | |
| | – Y acceleration (km/sec2) | |
| | – Accuracy code (URA, meters)| |
+——————–+——————————————+————+
| BROADCAST ORBIT – 3| – Satellite position Z (km) | 4X,4D19.12 |
| | – velocity Z dot (km/sec) | |
| | – Z acceleration (km/sec2) | |
| | – IODN (Issue of Data Navigation, DO229, | |
| | 8 first bits after Message Type if MT9) | |
+——————–+——————————————+————+
*) In order to account for the various compilers, E,e,D, and d are allowed letters between the fraction and exponent of
all floating point numbers in the navigation message files. Zero-padded two-digit exponents are required, however.
RINEX Version 3.01 Appendix A14
rinex301_2009_06_22.doc 23.06.2009 11:03
A 12 SBAS Navigation Message File – Example
+——————————————————————————+
| TABLE A12 |
| SBAS NAVIGATION MESSAGE FILE – EXAMPLE |
+——————————————————————————+
—-|—1|0—|—2|0—|—3|0—|—4|0—|—5|0—|—6|0—|—7|0—|—8|
3.01 N: GNSS NAV DATA S: SBAS RINEX VERSION / TYPE
SBAS2RINEX 3.0 CNES 20031018 140100 PGM / RUN BY / DATE
EXAMPLE OF VERSION 3.00 FORMAT COMMENT
SBUT -.1331791282D-06 -.107469589D-12 552960 1025 EGNOS 5 TIME SYSTEM CORR
13 LEAP SECONDS
This file contains navigation message data from a SBAS COMMENT
(geostationary) satellite, here AOR-W (PRN 122 = # S22) COMMENT
END OF HEADER
S22 2003 10 18 0 1 4-1.005828380585D-07 6.366462912410D-12 5.184420000000D+05
2.482832392000D+04-3.593750000000D-04-1.375000000000D-07 0.000000000000D+00
-3.408920872000D+04-1.480625000000D-03-5.000000000000D-08 4.000000000000D+00
-1.650560000000D+01 8.360000000000D-04 6.250000000000D-08 2.300000000000D+01
S22 2003 10 18 0 5 20-9.872019290924D-08 5.456968210638D-12 5.186940000000D+05
2.482822744000D+04-3.962500000000D-04-1.375000000000D-07 0.000000000000D+00
-3.408958936000D+04-1.492500000000D-03-5.000000000000D-08 4.000000000000D+00
-1.628960000000D+01 8.520000000000D-04 6.250000000000D-08 2.400000000000D+01
S22 2003 10 18 0 9 36-9.732320904732D-08 4.547473508865D-12 5.189510000000D+05
2.482812152000D+04-4.325000000000D-04-1.375000000000D-07 0.000000000000D+00
-3.408997304000D+04-1.505000000000D-03-5.000000000000D-08 4.000000000000D+00
-1.606960000000D+01 8.800000000000D-04 6.250000000000D-08 2.500000000000D+01
S22 2003 10 18 0 13 52-9.592622518539D-08 4.547473508865D-12 5.192110000000D+05
2.482800632000D+04-4.681250000000D-04-1.375000000000D-07 0.000000000000D+00
-3.409035992000D+04-1.518125000000D-03-3.750000000000D-08 4.000000000000D+00
-1.584240000000D+01 8.960000000000D-04 6.250000000000D-08 2.600000000000D+01
—-|—1|0—|—2|0—|—3|0—|—4|0—|—5|0—|—6|0—|—7|0—|—8|
A 13 Meteorological Data File – Header Section Description
+—————————————————————————-+
| TABLE A13 |
| METEOROLOGICAL DATA FILE – HEADER SECTION DESCRIPTION |
+——————–+——————————————+————+
| HEADER LABEL | DESCRIPTION | FORMAT |
| (Columns 61-80) | | |
+——————–+——————————————+————+
|RINEX VERSION / TYPE| – Format version : 3.01 | F9.2,11X, |
| | – File type: M for Meteorological Data | A1,39X |
+——————–+——————————————+————+
|PGM / RUN BY / DATE | – Name of program creating current file | A20, |
| | – Name of agency creating current file | A20, |
| | – Date of file creation | A20 |
+——————–+——————————————+————+
*|COMMENT | Comment line(s) | A60 |*
+——————–+——————————————+————+
|MARKER NAME | Station Name | A60 |
| | (preferably identical to MARKER NAME in | |
| | the associated Observation File) | |
+——————–+——————————————+————+
*|MARKER NUMBER | Station Number | A20 |*
| | (preferably identical to MARKER NUMBER in| |
| | the associated Observation File) | |
+——————–+——————————————+————+
|# / TYPES OF OBSERV | – Number of different observation types | I6, |
| | stored in the file | |
| | – Observation types | 9(4X,A2) |
| | | |
| | The following meteorological observation | |
| | types are defined in RINEX Version 2: | |
| | PR : Pressure (mbar) | |
| | TD : Dry temperature (deg Celsius) | |
RINEX Version 3.01 Appendix A15
rinex301_2009_06_22.doc 23.06.2009 11:03
| | HR : Relative humidity (percent) | |
| | ZW : Wet zenith path delay (mm) | |
| | (for WVR data) | |
| | ZD : Dry component of zen.path delay (mm)| ||
| | ZT : Total zenith path delay (mm) | |
| | WD : Wind azimuth (deg) | |
| | from where the wind blows | |
| | WS : Wind speed (m/s) | |
| | RI : “Rain increment” (1/10 mm): Rain | |
| | accumulation since last measurement | |
| | HI : Hail indicator | |
| | non-zero: Hail detected since last | |
| | measurement | |
| | | |
| | The sequence of the types in this record | |
| | must correspond to the sequence of the | |
| | measurements in the data records | |
| | | |
| | If more than 9 observation types are | |
| | being used, use continuation lines with | |
| | format (6X,9(4X,A2)) | |
+——————–+——————————————+————+
|SENSOR MOD/TYPE/ACC | Description of the met sensor | |
| | – Model (manufacturer) | A20, |
| | – Type | A20,6X, |
| | – Accuracy (same units as obs values) | F7.1,4X, |
| | – Observation type | A2,1X |
| | Record is repeated for each observation | |
| | type found in # / TYPES OF OBSERV record | |
+——————–+——————————————+————+
|SENSOR POS XYZ/H | Approximate position of the met sensor | |
| | – Geocentric coordinates X,Y,Z (ITRF | 3F14.4, |
| | – Ellipsoidal height H or WGS-84)| 1F14.4, |
| | – Observation type | 1X,A2,1X |
| | Set X,Y,Z to zero if not known. | |
| | Make sure H refers to ITRF or WGS-84! | |
| | Record required for barometer, | |
| | recommended for other sensors. | |
+——————–+——————————————+————+
|END OF HEADER | Last record in the header section. | 60X |
+——————–+——————————————+————+
Records marked with * are optional
A 14 Meteorological Data File – Data Record Description
+—————————————————————————-+
| TABLE A14 |
| METEOROLOGICAL DATA FILE – DATA RECORD DESCRIPTION |
+————-+————————————————-+————+
| OBS. RECORD | DESCRIPTION | FORMAT |
+————-+————————————————-+————+
| EPOCH / MET | – Epoch in GPS time (not local time!) | |
| | year (2 digits, padded with 0 if necessary) | 1X,I2.2, |
| | month,day,hour,min,sec | 5(1X,I2), |
| | | |
| | The 2-digit years are understood to represent | |
| | 80-99: 1980-1999 and 00-79: 2000-2079 | |
| | | |
| | – Met data in the same sequence as given in the | mF7.1 |
| | header | |
| | | |
| | More than 8 met data types: Use continuation |4X,10F7.1,3X|
| | lines | |
+————-+————————————————-+————+
RINEX Version 3.01 Appendix A16
rinex301_2009_06_22.doc 23.06.2009 11:03
A 15 Meteorological Data File – Example
+——————————————————————————+
| TABLE A15 |
| METEOROLOGICAL DATA FILE – EXAMPLE |
+——————————————————————————+
—-|—1|0—|—2|0—|—3|0—|—4|0—|—5|0—|—6|0—|—7|0—|—8|
3.01 METEOROLOGICAL DATA RINEX VERSION / TYPE
XXRINEXM V9.9 AIUB 1996-04-02 00:10:12 PGM / RUN BY / DATE
EXAMPLE OF A MET DATA FILE COMMENT
A 9080 MARKER NAME
3 PR TD HR # / TYPES OF OBSERV
PAROSCIENTIFIC 740-16B 0.2 PR SENSOR MOD/TYPE/ACC
HAENNI 0.1 TD SENSOR MOD/TYPE/ACC
ROTRONIC I-240W 5.0 HR SENSOR MOD/TYPE/ACC
0.0 0.0 0.0 1234.5678 PR SENSOR POS XYZ/H
END OF HEADER
96 4 1 0 0 15 987.1 10.6 89.5
96 4 1 0 0 30 987.2 10.9 90.0
96 4 1 0 0 45 987.1 11.6 89.0
—-|—1|0—|—2|0—|—3|0—|—4|0—|—5|0—|—6|0—|—7|0—|—8|

 

 

Rinex 301

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