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BeiDou Signal Plan: Difference between revisions
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Taking into account both aforementioned signal components, the complex envelope of the B2a signal is: | Taking into account both aforementioned signal components, the complex envelope of the B2a signal is: | ||
S<sub>B2a</sub> (t) = S<sub>B2a_data</sub>(t)+jS S<sub>B2a_pilot</sub> (t) | S<sub>B2a</sub> (t) = S<sub>B2a_data</sub>(t)+jS S<sub>B2a_pilot</sub> (t) | ||
Where, the data component is generated from the navigation message data (D<sub>B2a_data</sub>(t)) modulated with the ranging code C<sub>B2a_data</sub>(t), while the pilot component contains the ranging code C<sub>B2a_Pilot</sub>(t) only. They both adopt BPSK(10) modulation. The power ratio of the data component to the pilot component is 1:1. | Where, the data component is generated from the navigation message data (D<sub>B2a_data</sub>(t)) modulated with the ranging code C<sub>B2a_data</sub>(t), while the pilot component contains the ranging code C<sub>B2a_Pilot</sub>(t) only. They both adopt BPSK(10) modulation. The power ratio of the data component to the pilot component is 1:1.< /br> | ||
As also done for the rest of GNSS bands, we show in the next figure all the systems together. | As also done for the rest of GNSS bands, we show in the next figure all the systems together. | ||
In the next table appear phase relationship, as well as the power ratio of each component. | In the next table appear phase relationship, as well as the power ratio of each component. |
Revision as of 11:50, 15 October 2019
Fundamentals | |
---|---|
Title | BeiDou Signal Plan |
Author(s) | J.A Ávila Rodríguez, University FAF Munich, Germany. |
Level | Advanced |
Year of Publication | 2011 |
Presently, the in-orbit operational BDS satellites providing open services include 5 GEO satellites, 7 IGSO satellites and 21 MEO satellites, which can be further divided as 15 BDS-2 satellites ( 5 BDS-2G, 7 BDS-2I, 3 BDS-2M) and 18 BDS-3 satellites (BDS-3M). In addition to B1I and B2I signals, the B1C and B2a ones have started broadcasting by the BDS-3M satellites[1].
BeiDou B1I Band
The B1I signal is composed of the carrier frequency, ranging code and navigation message. The ranging code and navigation message are modulated on carrier. The B1I signal is expressed as follows[2]:
SjB1I (t) = AB1ICjB1I(t)DjB1I(t)cos(2πf1t + ѰjB1I)
Where:
• Superscript j: satellite number.
• AB1I : amplitude of B1I.
• CB1I : ranging code of B1I.
• DB1I : data modulated on ranging code of B1I.
• f1 : carrier initial phase of B1I.
• ѰB1I : carrier initial phase of B1I.
To conclude some technical characteristics of the BeiDou B1 signals are given next:
Technical KPI | High Level Description |
---|---|
Carrier Frequency | 1561.098 MHz |
Modulation Mode | Binary Phase Shift Keying (BPSK) |
Polarization Mode | Right-Hand Circularly Polarized (RHCP) |
Carrier Phase Noise | Third-order phase locked loop with 10 Hz one-sided noise bandwidth |
Received Power Levels on Ground | -163 dBW (measured at the output of a 0 dBi RHCP user receiving antenna when the satellites are above a 5-degree elevation angle) |
Signal Multiplexing Mode | Code Division Multiple Access (CDMA) |
Signal Bandwidth | 4092 MHz (centered at the carrier frequency) |
Spurious | Shall not exceed -50dBc |
Signal Coherence | The random jitters of the ranging code phase differentials between B1I, B2I and B3I shall be less than 1ns (1σ). |
The random jitter of the initial phase differential between the ranging code and the corresponding carrier shall be less than 3° (1σ). | |
Equipment Group Delay Differential | TGD1 (less than 1ns) |
BeiDou B1C Band
This section defines the characteristics of the open service signal B1C transmitted by the Medium Earth Orbit (MEO) satellites and the Inclined GeoSynchronous Orbit (IGSO) satellites of BDS-3 for providing open service, and shall not be transmitted by the Geostationary Earth Orbit (GEO) satellites. The signal characteristics described in this chapter pertain to the B1C signal contained within the 37.736 MHz bandwidth with a center frequency of 1575.42MHz. The carrier frequencies, modulations and symbol rates of the B1C signal are shown in the following table.[4]
Signal | Signal component | Carrier frequency (MHz) | Modulation | Symbol rate (sps) |
---|---|---|---|---|
B1C | Data component B1C_data | 1575.42 | BOC(1,1) | 100 |
Pilot component B1C_pilot | QMBOC(6, 1, 4/33) | 0 |
The complex envelope of the B1C signal is expressed as:
SB1C(t) = SB1C_data(t)+jS SB1C_pilot (t)
Where the SB1C_data(t) is the data component, which is generated from the navigation message data DSB1C_data(t) and the ranging code CSB1C_data(t) modulated with the sine-phase BOC(1,1) subcarrier scSB1C_data(t). SB1C_pilot(t) is generated from the ranging code CB1C_pilot(t), modulated with the QMBOC(6,1,4/33) subcarrier scB1C_pilot(t). The power ratio of the data component to the pilot component is 1:3.
In the next table appear phase relationship, as well as the power ratio of each component.
Component | Modulation | Phase relationship | Power ratio | |
---|---|---|---|---|
SB1C_data(t) | Sine BOC(1,1) | 0 | 1/4 | |
SB1C_pilot_a (t) | QMBOC (6,1,4/33) | Sine BOC(1,1) | 90 | 29/44 |
SB1C_pilot_b (t) | Sine BOC(6,1) | 0 | 1/11 |
To conclude some technical characteristics of the BeiDou B1C signals are given bellow:
Technical KPI | High Level Description |
---|---|
Carrier Frequency | 1575.42 MHz |
Modulation Mode | BOC/QMBOC |
Polarization Mode | Right-Hand Circularly Polarized (RHCP) |
Carrier Phase Noise | Third-order phase locked loop with 10 Hz one-sided noise bandwidth |
Received Power Levels on Ground | -159 dBW for MEO and -161 dBW for IGSO satellites |
Signal Multiplexing Mode | Code Division Multiple Access (CDMA) |
Signal Bandwidth | 37.736 MHz (centered at the carrier frequency) |
Spurious | Shall not exceed -50dBc |
Signal Coherence | The time difference between the ranging code phases of all signal components <= 10 ns. |
Correlation Loss | The correlation loss due to payload distortions <= 0.3 dB |
Data/Code Coherence | The edge of each data symbol is aligned with the edge of the corresponding ranging code chip. The start of the first chip of the periodic ranging codes is aligned with the start of a data symbol. |
The edge of each secondary chip is aligned with the edge of a primary code chip. The start of the first chip of the primary codes is aligned with the start of a secondary code chip. |
BeiDou B2a Band
The signal characteristics described in this point correspond to the B2a signal contained within the 20,64 MHz bandwidth with a center frequency of 1176,45 MHz. The following table shows the carrier frequencies, modulations and symbol rates of the B2a signal [6].
Signal | Signal component | Carrier frequency (MHz) | Modulation | Symbol rate (sps) |
---|---|---|---|---|
B2a | Data component B2a_data | 1176.45 | BPSK(10) | 200 |
Pilot component B2a_pilot | 0 |
Taking into account both aforementioned signal components, the complex envelope of the B2a signal is:
SB2a (t) = SB2a_data(t)+jS SB2a_pilot (t)
Where, the data component is generated from the navigation message data (DB2a_data(t)) modulated with the ranging code CB2a_data(t), while the pilot component contains the ranging code CB2a_Pilot(t) only. They both adopt BPSK(10) modulation. The power ratio of the data component to the pilot component is 1:1.< /br> As also done for the rest of GNSS bands, we show in the next figure all the systems together. In the next table appear phase relationship, as well as the power ratio of each component.
To conclude, some technical characteristics on the BeiDou B2 signals are presented more in detail in the next table:
BeiDou B3 Band
Finally, the spectral characteristics of the BeiDou B3 signals are also shown here. Similar to the B1 and B2 bands, not all the technical aspects of the BeiDou signals are defined yet. Next figure shows the Power Spectral densities of the proposed BeiDou signals in B3:
In order to have a better insight on how the Galileo E6 – BeiDou B3 band looks like, the following figure presents all the planned signals together.
To conclude, some technical characteristics on the BeiDou B3 signals are provided next [Compass ITU Filing] [7].
References
- ^ [2]BeiDou Navigation Satellite System Signal In Space Interface Control Document Open Service Signal B1I (Version 3.0)
- ^ [3] Beidou B1I signal characteristics
- ^ [4] BeiDou Navigation Satellite System Signal In Space Interface Control Document Open Service Signal B1C (Version 1.0)
- ^ [5] Beidou B1I signal characteristics
- ^ [6] BeiDou Navigation Satellite System Signal In Space Interface Control Document Open Service Signal B2a (Version 1.0).
- ^ a b c Cite error: Invalid
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Credits
The information presented in this NAVIPEDIA’s article is an extract of the PhD work performed by Dr. Jose Ángel Ávila Rodríguez in the FAF University of Munich as part of his Doctoral Thesis “On Generalized Signal Waveforms for Satellite Navigation” presented in June 2008, Munich (Germany)