RU177277U1 - DEVICE FOR MEASURING THE GENERAL Fading DEPTH COEFFICIENT IN THE TRANSIONOSPHERIC COMMUNICATION CHANNEL AT TWO-FREQUENCY OPERATION MODE OF SATELLITE RADIO NAVIGATION SYSTEMS - Google Patents

Abstract

The utility model relates to the field of measurement technology and can be used in satellite radio navigation systems, in satellite communication systems, as well as in ionosphere monitoring systems. The essence of the utility model: a device is developed for measuring the depth coefficient of total fading in a transionospheric communication channel with a two-frequency operating mode of satellite radio navigation systems taking into account small-scale inhomogeneities of the ionosphere. The proposed device includes: a receiving antenna (1), a receiver (2), a reference generator and a frequency synthesizer (3), an analog-to-digital preprocessing processor (4), a phase path calculator Di D (5), a TEC I calculator (6) ), a calculator of the standard deviation of the total electronic content σ (7), a calculator of the depth coefficient of total fading γ (8), an information output device (9). 2 of FIG.

Description

The proposed utility model relates to satellite communications and navigation, and can also be used in monitoring systems for the state of the parameters of the communication channel.

As you know [Dolukhanov M.P. Fluctuation processes during the propagation of radio waves - M .: Svyaz, 1971. - 183 pp.], The ionosphere is a heterogeneous medium with varying parameters, which has a significant impact on the propagation of radio waves. The change in the ionosphere parameters is explained by the influence of a number of factors on it: solar radiation, the influence of meteors, earthquakes, etc. A change (increase) in the ionosphere parameters (the total electronic content and intensity of inhomogeneities) can cause an increase in the absorption, refraction, polarization, dispersion, and scattering (diffraction) properties of the ionosphere [Pashintsev VP, Solchatov ME, Gakhov RP The influence of the ionosphere on the characteristics of space-based information transfer systems: Monograph. - M .: Fizmatlit, 2006. - 184 p.]. The latter lead to the appearance at the receiving point of fading signals of various types, which significantly impair the noise immunity of satellite information transmission systems.

Quantitatively, fading is estimated by the coefficient of their depth (γ ² ), which is calculated according to the expression [Pashintsev V.P., Solchatov M.E., Gakhov R.P. The influence of the ionosphere on the characteristics of space-based information transfer systems: Monograph. - M .: Fizmatlit, 2006. - 184 p.]

80.8 - constant coefficient [m ³ / s ² ];

σ _ΔI is the standard deviation of the fluctuations of the total electronic content of the ionosphere [e / m ² ];

c is the speed of light in vacuum [m / s];

f _1,2 - carrier frequency [GHz].

среднего значения полного электронного содержания

и его флуктуаций (ΔI), определяемых среднеквадратическим отклонением (σ_ΔI).Since the ionosphere is an inhomogeneous medium (with fluctuations in the electron concentration relative to its average value), the value of the total electronic content of the ionosphere is defined as the sum

average full electronic content

and its fluctuations (ΔI), determined by the standard deviation (σ _ΔI ).

A device is known for measuring the total electronic content of the ionosphere at a two-frequency mode of operation of satellite radio navigation systems (figure 1) [Pashintsev VP, Galushko Yu.I., Spirin A.M., Koval S.A. A device for measuring the total electronic content of the ionosphere in the dual-frequency mode of operation of satellite radio navigation systems. Utility Model Patent No. 81340 of 03/10/2008].

The device comprises a receiving antenna (1), a receiver (2), a reference generator and a frequency synthesizer (3), an analog-to-digital primary processing processor (4), a phase path calculator D _f1 and D _f2 (5), a computer for the total electronic content I ( 6) and an information output device (7).

The principle of operation of this device: the antenna (1) receives electromagnetic waves emitted by navigation satellites (NS). From the output of the antenna (1), the voltage u _in (t) is supplied to the input of the receiver (2). From its output, the vector of digital signals estimation y (t _j ) with a sampling step T _d = t _j -t _j-1 = 25 ns (consisting of the signals of each of n visible NS) is fed to the input of the analog-to-digital primary processing processor (4) . The reference generator and frequency synthesizer (3) generates the nominal values of the operating frequencies f ₁ and f ₂ at the inputs of the receiver (2), analog-digital processor (4) and navigation processor (5). An analog-to-digital primary processing processor (4) implements search and tracking schemes for signal parameters. From the output of the analog-to-digital processor (4), estimates of the propagation phase time τ _f (t _k ) are received at the input of the phase path calculator of signal (5) that implements the algorithm D _f1,2 (t _k ) = cτ _f1,2 (t _k ) s in steps of T = t _k -t _k-1 = 0.1 s. The values of Д _ф1,2 (t _k ) are fed to the input of the total electronic content calculator I (6) with an unchanged step T = 0.1 s, which provides measurement of small-scale inhomogeneities (since the measurement period T <ΔT _mn is the period of small-scale ionospheric inhomogeneities ) Further, data on the full electronic content is displayed on the information output device (7).

но не позволяет определить коэффициент глубины общих замираний (γ²) трансионосферного канала связи при двухчастотном режиме работы систем спутниковой радионавигации.The disadvantage of this device, in our opinion, is that the device measures the total electronic content of the ionosphere

but it does not allow to determine the depth coefficient of total fading (γ ² ) of the transionospheric communication channel in the dual-frequency mode of operation of satellite radio navigation systems.

The purpose of this utility model is to develop a device that allows you to measure the depth of the total fading of the transionospheric communication channel with a dual-frequency mode of operation of satellite radio navigation systems.

The proposed device (figure 2) is implemented on the basis of a device for measuring the total electronic content of the ionosphere at two-frequency operation of satellite radio navigation systems [Pashintsev VP, Galushko Yu.I., Spirin AM, Koval S.A. A device for measuring the full electronic content of the ionosphere in the dual-frequency mode of operation of satellite radio navigation systems, patent for utility model No. 81340 of 03/10/2008]. The device for measuring the depth of general fading contains a receiving antenna (1), a receiver (2), a reference generator and a frequency synthesizer (3), an analog-to-digital primary processing processor (4), a phase path calculator D _ф1 and Д _ф2 (5), a full computer electronic content I (6), calculator of standard deviation of the total electronic content σ _ΔI (7), calculator of the coefficient of total fading depth γ ² (8), information output device (9).

The principle of operation of this device: the antenna (1) receives electromagnetic waves emitted by navigation satellites (NS). From the output of the antenna (1), the voltage u _in (t) is supplied to the input of the receiver (2). From its output, the vector of digital signals estimation y (t _j ) with a sampling step T _d = t _j -t _j-1 = 25 ns (consisting of the signals of each of n visible navigation satellites) is fed to the input of the analog-to-digital primary processing processor (4) ) The reference generator and frequency synthesizer (3) generates the values of the operating frequencies f ₁ and f ₂ at the inputs of the receiver (2), analog-digital processor (4), a computer for the total electronic content of the ionosphere (6), and a computer for the depth of total fading γ ² (8) . An analog-to-digital primary processing processor (4) implements search and tracking schemes for signal parameters. From the output of the analog-digital processor (4), estimates of the phase propagation time τ _f1,2 (t _k ) are received at the input of the phase path calculator of the signal (5) that implements the algorithm D _f1,2 (t _k ) = cτ _f1,2 (t _k ) with a step T = t _k -t _k-1 = 0.1 s. The values of Д _ф1,2 (t _k ) are fed to the input of the TEC calculator I (6) with an unchanged step T = 0.1 s, which provides for the measurement of small-scale inhomogeneities (since the measurement period T <ΔT _mn is the period of small-scale ionospheric inhomogeneities). Further, the estimates of the total electronic content (I) go to the input of the calculator of the standard deviation of the total electronic content σ _ΔI (7), where centering, squaring, averaging, and square root extraction are performed [Smirnov NN, Fedosov VP, Tsvetkov F.V. Measurement of characteristics of random processes / Under. ed. V.P. Fedosova: Textbook. manual for universities. - M .: SAYNS-PRESS, 2004. - 64 p.]. Then, the values of the standard deviation of the total electronic content are fed to the input of the calculator of the depth coefficient of the total fading of the communication channel (8), where γ ² is calculated in accordance with expression (1). At the second input of the calculator, the fading depth coefficient (8) from the frequency synthesizer (3) receives the carrier frequency values (f _1,2 ). The calculated value of the depth coefficient of total fading (γ ² ) is displayed in the information output device (9).

Claims (1)

The device for measuring the depth coefficient of total fading in a transionospheric communication channel with a two-frequency mode of operation of satellite radio navigation systems includes a receiving antenna (1) connected to the input of a two-frequency radio navigation receiver (2), the radio navigation receiver is connected to the output of the reference generator and frequency synthesizer block (3) and with the input of the analog-digital processor (4), the analog-digital processor is connected to the output of the block of the reference generator and frequency synthesizer and to the input of the phase path calculator signal (5), the phase signal path calculator is connected to the input of the calculator of the total electronic content of the ionosphere (6), which is connected to the output of the reference generator block and the frequency synthesizer, the output of the total electron content calculator (6) is connected to the input of the standard deviation calculator (7), calculating the standard deviation of the output (7) connected to the input depth coefficient calculator general fading γ ² (8), a second input coupled to an output of the reference generator block and a frequency synthesizer (3), Exit coefficient calculator general fading depth γ ² (8) connected to the information output device (9).

Images