RU2659351C1 - Modernized glonass satellite navigation system - Google Patents

Abstract

FIELD: radar ranging and radio navigation.

SUBSTANCE: present invention relates to the field of satellite navigation systems and is aimed at improvement of the existing GLONASS satellite navigation system. In the updated GLONASS satellite navigation system, consisting of the existing GLONASS satellite navigation system basic navigation satellites formation N1, for which the first kind M-sequence based signal generation is used, additional navigation spacecrafts formation N2 is introduced, for which the second kind M-sequence based signal generation is used, where N2 of additional navigation spacecrafts represents twenty-four navigation spacecrafts located similar to the initial GLONASS system in three intermediate in the longitude planes relative to the initial GLONASS system orbital planes.

EFFECT: increase in the navigation signal propagation and reception efficiency.

1 cl, 2 dwg, 1 tbl

Description

The present invention relates to the field of satellite navigation systems and is aimed at improving the existing satellite navigation system GLONASS.

There are various directions for improving and modernizing satellite navigation systems, the practical application of which should be the modernization of the GLONASS satellite navigation system. For example, in patent RU2314232 a satellite navigation system is proposed, which is an alternative constellation of spacecraft, orbits are defined for the spacecraft of this satellite system. In turn, in the present invention, it is proposed to solve the existing problem of forming several constellations of spacecraft - in fact basic and additional, and to ensure the effective distribution and reception of the navigation signal.

To overcome the technical problem described above, a modernized GLONASS satellite navigation system is proposed, consisting of the existing grouping N1 of basic navigation spacecraft of the GLONASS satellite navigation system, for which signal generation based on the M-sequence of the first kind is used, a grouping of N2 additional navigation spacecraft has been introduced, for which use signal generation based on the M-sequence of the second type, where N2 additional navigation onnyh spacecraft are twenty-four navigation satellites, arranged in a similar original GLONASS system in the three intermediate longitudinal planes relative to the orbital plane of the original GLONASS.

The practical use of the claimed invention is justified as follows.

An obvious direction in the development of satellite navigation systems, including the GLONASS system, which will improve the accuracy of determining the position of an object, is to increase the number of spacecraft constellations (see analogue). It is also obvious that the increase in the number of spacecraft constellations with a simultaneous change in the structure of the existing satellite navigation system, which can be analyzed as a large system, will lead to its complexity and, consequently, to a decrease in the efficiency of use. Thus, there is an urgent task of creating a more accurate, modernized GLONASS system, built by increasing the grouping of navigation spacecraft without making changes to the already existing configuration of the GLONASS satellite navigation system, consisting of twenty-four navigation spacecraft.

Initially, each of the twenty-four GLONASS navigation spacecraft was assigned its own letter carrier frequency, which was approximately 0.5 MHz apart from neighboring carrier frequencies, and the same M-sequence with a length of 511 binary signals was emitted as a ranging code on each of the twenty-four carrier frequencies units with good autocorrelation properties. With the development of international cooperation, the number of letter carrier frequencies had to be reduced to sixteen, while part of the opposing navigation spacecraft in the same plane (antipodes) began to work in pairs at the same frequency. The presence of antipodes at a single frequency in the system did not affect the work of terrestrial consumers, however, there were problems with the interference of signals from spacecraft — antipodes for spacecraft — consumers with orbit heights above about 209 km, practically from a reference orbit up to the limit for the consumer GLONASS system heights of 2000 km. This problem was successfully solved due to the good autocorrelation properties of the rangefinder M-sequence, and the problem of finding additional carrier frequencies to increase the number of navigational spacecraft constellations in the GLONASS system was not solved.

To solve the above problem, we analyze the possibility of abandoning the multi-frequency principle of constructing a GLONASS system with one range-finding code for all navigation spacecraft and the transition to the single-frequency principle of building a navigation satellite system used in GPS Navstar with an individual range-finding code for each navigation spacecraft. Analyzing the possibility of preference for using frequency or code division in satellite navigation systems, one can pay attention to the absence of a classical frequency division in the GLONASS system. The separation of channels in the GLONASS system occurs solely due to the correlation reception of rangefinder signals. One millisecond length signal is generally received. The width of the spectrum of such a signal at the output of the correlation receiver is ~ 2 kHz. In the presence of a Doppler shift of 10-15 kHz, a separation of the carrier frequencies by 0.5 MHz makes the signals of different navigation spacecraft completely orthogonal, with the exception of navigation spacecraft - antipodes, when the separation of the channels of two navigation spacecraft is ensured by good autocorrelation properties of the range-finding M-sequence of the system GLONASS. These properties of GLONASS signals have clear advantages over a set of GPS signals, in which the level of inter-channel interference increases in proportion to the number of simultaneously visible navigation spacecraft.

The existing advantage of the GLONASS satellite navigation system can be used for its further improvement without changing the existing structure. It is necessary to find at least one M-sequence with a length of 511 units with the same good autocorrelation properties as the M-sequence of the existing GLONASS multi-frequency system, and with good cross-correlation properties of these M-sequences for their code separation. The proposed schemes for the formation of M-sequences of the first (existing M-sequence) and second (new M-sequence) types are shown in FIG. 1. The existing rangefinder code of the GLONASS signal of medium accuracy is used for navigation spacecraft with numbers from 1 to 24. This rangefinder code is an M-sequence of 511 units, 1 ms period, formed by a 9-bit shift register with a tap sequence (5, 9 ) A shift in the register is performed from a cell with a lower number to a cell with a higher number. With a frequency of 1 time in 1 ms, the initial state is set in the register. M-sequence is removed from the last cell of the register. It is proposed to use an additional rangefinder GLONASS signal code of medium accuracy for navigation spacecraft with numbers from 25 to 48. It differs from the existing rangefinder code in that it uses a different tap sequence, for example (2, 4, 7, 9), and a different initial state.

The correlation properties of these two range-finding codes are as follows: the average square of the peak of the periodic cross-correlation function is minus 27.08 dB (calculated for one sample per symbol of the range-finding code); the maximum square of the peak of the periodic cross-correlation function is minus 23.8 dB; the maximum square of the lateral peak of the periodic autocorrelation function is minus 54.17 dB. The obtained cross-correlation properties coincide with the known correlation properties of Gold codes of length 511, and the autocorrelation properties coincide with the known properties of M-sequences. In order to be able to distinguish ranging codes by the first characters in the period, the initial state of the M-sequence of the second kind is supposed to be selected different from the initial state of the M-sequence of the first kind. The proposed tap sequence for the additional ranging code is not unique. Similar non-correlation properties can be obtained using any of the tap sequences shown in Table 1. This allows antipodes for space vehicles to supplement the GLONASS system to select various possible M-sequences with at least four taps, which ensures reliable separation of the signals of the antipodes space vehicles of the complement to single carrier frequency.

The orbital construction of the claimed additional system is similar to the original GLONASS system, but with a rotation of the orbital planes in longitude between the orbital planes of the original GLONASS system by 60º (see Fig. 2).

Claims (1)

The upgraded GLONASS satellite navigation system, including the existing grouping N1 of basic navigation spacecraft of the GLONASS satellite navigation system, for which use signal generation based on the M-sequence of the first kind, characterized in that it includes the grouping N2 of additional navigation spacecraft for which use signal generation on based on the M-sequence of the second kind, where N2 of additional navigation spacecraft represent oboj twenty-four navigation satellites, arranged in a similar original GLONASS system in the three intermediate longitudinal planes relative to the orbital plane of the original GLONASS.

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