RU110841U1 - DEVICE FOR MEASURING THE INTENSITY OF IONOSPHERIC HETEROGENEITY - Google Patents

Abstract

 A device for measuring the intensity of ionospheric inhomogeneities includes a receiving antenna (1), the output of which is connected to the first input of the radio frequency unit (2); the output of the RF block is connected to the first input of the analog-to-digital primary processing processor (4); the output of the reference generator and frequency synthesizer (3) is connected to the second input of the radio frequency block (2), the second input of the analog-to-digital primary processing processor (4) and the second input of the block for calculating the total electronic content of the ionosphere (5); the output of the analog-to-digital primary processing processor (4) is connected to the first input of the block for calculating the total electronic content of the ionosphere (5); the outputs of the unit for calculating the total electronic content of the ionosphere (5) with the input of the output device information (6), characterized in that the unit includes a unit for calculating the standard deviation of the total electronic content of the ionosphere (7), a unit for calculating the mathematical expectation of the full electronic content of the ionosphere (8), the inputs of which are connected to the outputs of the unit for calculating the total electronic content of the ionosphere (5), and the outputs to the inputs of the unit for calculating the intensity of ionospheric inhomogeneities (9); a unit for calculating the intensity of ionospheric inhomogeneities (9), the output of which is connected to the input of the information output device (6).

Description

The proposed utility model relates to satellite radio navigation and communications and can be used in monitoring systems for the state of the ionosphere.

As is known, the impact on the ionosphere of a number of factors caused by solar activity, such as ionospheric magnetic storms and bursts of absorption, lead to a change in its basic parameters and have a significant effect on the propagation of radio waves [1, 2].

One of the main parameters of the ionosphere that affects the propagation of radio waves is its total electronic content I, the value of which can be measured in single-frequency operation of satellite navigation systems [3]. In the general case, I is defined as the sum the average value of the total electronic content of the ionosphere I and fluctuations of the total electronic content of the ionosphere ΔI. The latter is estimated by the value of rms; deviations or intensities of ionospheric inhomogeneities (β ~ σ _ΔI / ) [2].

It is known [1] that with a normal ionosphere the intensity of inhomogeneities is β = 10 ^-3 ... 10 ^-2 , and under conditions of ionospheric disturbances it can increase to β = 10 ^-1 ... 1 [2]. The value β determines the depth and frequency and spatial correlation intervals of fading of received signals in satellite radio navigation and communication systems [2].

The aim is to develop a device that allows you to determine the value of the intensity of the inhomogeneities of the ionosphere β depending on the change in the values of the standard deviation σ _ΔI and mathematical expectation the total electronic content of the ionosphere according to the results of single-frequency measurements of the total electronic content of the ionosphere I.

The technical result that can be obtained using the proposed utility model is reduced to measuring the depth and frequency and spatial correlation intervals of interference fading in transionospheric communication channels, which strongly depend on the intensity of the ionospheric inhomogeneities.

A device for measuring the total electronic content of the ionosphere I at a single-frequency mode of operation of satellite radio navigation systems [3], which includes: a receiving antenna (1), a radio frequency unit (2), a reference generator and frequency synthesizer (3), an analog-to-digital primary processor processing (4), a unit for calculating the total electronic content of the ionosphere (5), an information output device (6) (figure 1). The disadvantage of this device is that it estimates the total electronic content of the ionosphere , but does not allow us to estimate the magnitude of the intensity of heterogeneities of the ionosphere β.

The known device for measuring the total electronic content of the ionosphere at a single-frequency mode of operation of satellite navigation systems works as follows. The receiving antenna (1) receives electromagnetic waves emitted by navigation satellites. From the output of the receiving antenna (1), the voltage u _BX (t) is supplied to the input of the radio-frequency block (2), designed to amplify and select the received signals, as well as lower the carrier frequency. From the output of the radio frequency block (2), the input of the analog-to-digital primary processing processor (4) is fed with a vector for evaluating digital signals y (t _j ), consisting of signals j = 1 ... n of visible navigation satellites. The reference generator and frequency synthesizer (3) forms a set of harmonic oscillations necessary for the operation of the radio frequency unit (2), the analog-to-digital primary processing processor (4), and the unit for calculating the total electronic content of the ionosphere I (5). In the analog-to-digital primary processing processor (4), search and tracking schemes for signal parameters are implemented, and a navigation message is transmitted that is transmitted at a frequency of 50 Hz (period T _k = 0.02 s). From the output of the analog-to-digital primary processing processor (4), the phase (t _f ,) and code (t _k ) estimates of the signal propagation time with a period T _k = 0.02 s are received at the input of the block for calculating the total electronic content of the ionosphere (5). In the block for calculating the total electronic content of the ionosphere (5), the calculation of the total electronic content of I occurs with an interval T _k = 0.02 s. From the output of the unit for calculating the full electronic content of the ionosphere (5), the data is fed to the information output device (6).

The implementation of the proposed device, which allows to determine the value of the intensity of inhomogeneities of the ionosphere β depending on the change in the values of the standard deviation σ _ΔI and mathematical expectation full electronic content of the ionosphere I, will allow you to implement a device for measuring the intensity of inhomogeneities of the ionosphere, a diagram of which is shown in Figure 2. The expression for calculating the intensity of ionospheric inhomogeneities has the form [2]:

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

h _E is the equivalent thickness of the ionospheric layer (h _E = 5 · 10 ⁵ m);

l _S is the characteristic scale of inhomogeneities (l _S = 400 m);

- mathematical expectation (average value) of the full electronic content of the ionosphere [e / m ² ].

The well-known expression (1) is more conveniently written as

Where - constant dimensionless coefficient.

To solve this problem, in the well-known (Figure 1) device for measuring the total electronic content of the ionosphere at a single-frequency operating mode of satellite radio navigation systems [3], the following blocks were added: a unit for calculating the standard deviation of the total electronic content of the ionosphere (7), a unit for calculating the mathematical expectation of full electronic content ionosphere (average value of the total electronic content) (8) and a unit for calculating the intensity of ionospheric inhomogeneities (9).

The proposed device (figure 2) works as follows. The receiving antenna (1) receives electromagnetic waves emitted by navigation satellites. From the output of the receiving antenna (1), the voltage u _BX (t) is supplied to the input of the radio-frequency block (2), designed to amplify and select the received signals, as well as lower the carrier frequency. From the output of the radio frequency block (2), the input of the analog-to-digital primary processing processor (4) is fed with a vector for evaluating digital signals y (t _j ), consisting of signals j = 1 ... n of visible navigation satellites.

The reference generator and frequency synthesizer (3) forms a set of harmonic oscillations necessary for the operation of the radio frequency unit (2), the analog-to-digital primary processing processor (4), and the unit for calculating the total electronic content of the ionosphere I (5). An analog-to-digital primary processing processor (4) searches for and monitors the signal parameters, and also highlights a navigation message transmitted at a frequency of 50 Hz (period T _k = 0.02 s). From the output of the analog-to-digital primary processing processor (4), the phase (t _f ) and code (t _k ) estimates of the signal propagation time in increments of T _k = 0.02 s are received at the input of the block for calculating the total electronic content of the ionosphere I (5). In the block for calculating the total electronic content of the ionosphere I (5), the calculation of the total electronic content of the ionosphere in increments of T _k = 0.02 s. Then, from the output of the block for calculating the total electronic content of the ionosphere I (5), the estimates of the total electronic content arrive at the input of the unit of calculation of the standard deviation of the total electronic content of the ionosphere σ _ΔI (7), where according to the formula operations of centering, squaring, averaging and square root extraction [4] and the input of the mathematical expectation block of the full electronic content of the ionosphere (average value of the total electronic content) (8) [4]. From the output of the unit for calculating the standard deviation of the total electronic content of the ionosphere σ _ΔI (7) and the output of the unit for calculating the mathematical expectation of the full electronic content of the ionosphere (8) the standard deviation of the total electronic content of the ionosphere σ _ΔI and the mathematical expectation of the total electronic content of the ionosphere arrive at the inputs of the unit for calculating the intensity of inhomogeneities of the ionosphere β (9). In the unit for calculating the intensity of the inhomogeneities of the ionosphere β (9), the value of the intensity of the inhomogeneities of the ionosphere is determined according to the expression (2) Where . The calculated value of the intensity of inhomogeneities of the ionosphere β is displayed in the information output device (6).

Thus, in the developed device (Figure 2) based on the values of standard deviation σ _ΔI and mathematical expectation the total electronic content of the ionosphere I according to the well-known [2] expression Where the value of the intensity of the inhomogeneities of the ionosphere β is determined with a step T _to = 0.02 s.

Brief Description of the Drawings

Figure 1 presents a functional diagram of a known device for measuring the total electronic content of the ionosphere at a single-frequency mode of operation of satellite radio navigation systems [3]; figure 2 presents a functional diagram of the proposed device for measuring the intensity of inhomogeneities of the ionosphere.

List of sources used

1. Grudinskaya G.P. Propagation of radio waves. Study Guide for Radio Tech. specialist. universities. Ed. 2nd, rev. and add. Moscow, "Higher. School ", 1975 - 280 p.

2. Pashintsev V.P., Solchatov M.E., Gakhov R.P. The influence of the ionosphere on the characteristics of space-based information transfer systems: Monograph. - Moscow: Fizmatlit, 2006 .-- 184 p.

3. Galushko Yu.I., Pashintsev V.P., Spirin A.M. A device for measuring the total electronic content of the ionosphere at a single-frequency operating mode of satellite radio navigation systems. Utility Model Patent No. 76462 of 09/20/2008

4. 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.

Claims (1)

A device for measuring the intensity of ionospheric inhomogeneities includes a receiving antenna (1), the output of which is connected to the first input of the radio-frequency unit (2); the output of the RF block is connected to the first input of the analog-to-digital primary processing processor (4); the output of the reference generator and frequency synthesizer (3) is connected to the second input of the radio frequency block (2), the second input of the analog-to-digital primary processing processor (4) and the second input of the block for calculating the total electronic content of the ionosphere (5); the output of the analog-to-digital primary processing processor (4) is connected to the first input of the block for calculating the total electronic content of the ionosphere (5); the outputs of the unit for calculating the total electronic content of the ionosphere (5) with the input of the output device information (6), characterized in that the unit includes a unit for calculating the standard deviation of the total electronic content of the ionosphere (7), a unit for calculating the mathematical expectation of the full electronic content of the ionosphere (8), the inputs of which are connected to the outputs of the unit for calculating the total electronic content of the ionosphere (5), and the outputs to the inputs of the unit for calculating the intensity of inhomogeneities of the ionosphere (9); a unit for calculating the intensity of ionospheric inhomogeneities (9), the output of which is connected to the input of the information output device (6).