RU2214682C2 - Procedure controlling transmission power of ground stations of satellite communication network, facility controlling transmission power of ground station and former of controlling signal - Google Patents

Abstract

FIELD: radio engineering, satellite communication systems. SUBSTANCE: technical result of invention lies in raised noise immunity, reliability and carrying capacity of multichannel communication systems. With this in mind control over transmission power of ground station is carried out with use of information signal in the capacity of test signal and controlling action is formed depending on quality of operation of corresponding channel. Controlling signal is formed thanks to delay of information signal with the help of delay line and thanks to its modulo two summation with same information signal relayed by satellite station in adder. From output of former controlling signal acts on controlling input of power amplifier of transmitter. EFFECT: raised noise immunity, reliability and carrying capacity of multichannel communication systems. 4 cl, 1 6 dwg

Description

 The proposed group of inventions is united by a single inventive concept, relates to the field of radio engineering and is intended for satellite communications systems. The proposed invention can also be used in radio, radio relay and tropospheric communication. The proposed technical solutions expand the arsenal of tools for this purpose.

 A known method of controlling the transmission power of earth stations in a satellite communications network, implemented in a device for regulating the electrical transmission power in a ground station of a satellite communications system (see patent JP 6052882, class 5 H 04 B 7/155, 1997), which consists in controlling the power of the transmitters of each earth station is based on the results of comparing the levels of the beacon signal generated at the satellite communications station and the satellite returned test signal transmitted by each of the earth stations through the station putnikovoy connection.

 The disadvantages of this method are the low noise immunity of the network, due to the fact that in the presence of external interference at one of the earth stations, an increase in the power of its transmitter is necessary. This, in turn, leads to disruption of the operation of other lines formed by satellite communication stations due to the suppression of strong signals by weaker ones. The known method also has a relatively low throughput of the satellite communications network, caused by the need to place a special beacon on the satellite to operate the network and allocate a frequency resource for it and for test signals of earth stations.

 Also known is a method for controlling the power of earth stations in a satellite communications network, implemented in a device for adjusting transmission power in a ground station of a satellite communications system (see JP 6066719, CL 5 H 04 B 7/15, 1997), namely, that power control the transmitter of each of the earth stations is carried out by comparing the levels of the beacon and the satellite-returned pilot signal and the test signal transmitted by the earth station to the satellite individually or together.

 The disadvantages of this method are the relatively low noise immunity and bandwidth, as well as significant differences in signal levels at the input of a satellite communication station due to possible fluctuations in the signals of a satellite beacon, resulting in different signal levels in the receiving path of each of the earth stations. In addition, in the known method, an additional frequency resource is required for transmission of pilot signals by earth stations.

 A device for controlling transmit power (see patent JP 5076211, class 5 H 04 1/04, 1996), consisting of two branches, one of which includes a detector, two amplifiers and a gain control circuit and is a gain feedback, and the second, consisting of two detectors, an amplitude limiter, an amplifier, and a comparator, is designed to eliminate distortion when the input signal level exceeds a predetermined threshold.

 A disadvantage of the known device is low noise immunity due to the fact that the processing of amplitude modulation signals and setting the minimum transmit power is determined not only by the level of the input signal, but also depends on the noise level at the input of the device.

 Also known is a device for regulating the transmission power in a ground station of a satellite communications system (see JP 6052882, CL 5 H 04 B 7/155, 1997), including a first receiver receiving a beacon signal from a space station, a signal transmitter to a space station, and a second a receiver that receives a response signal from the transmitter, a device for controlling the output level of the signal, comprising a frequency response deviation control unit, a correction unit, and a level controller.

 The disadvantages of this device are the relatively low adjustment accuracy due to the control of the transmission power of earth stations by test signals that are not always adequately related to the quality of information signals, as well as the relatively low network bandwidth due to the fact that the formation of special test signals requires an additional resource.

 A known driver of the control signal (see USSR author's certificate 4641950, class 5H 03 G 3/20, 1991. Automatic gain control device), consisting of an amplifier with adjustable gain, an amplitude detector, a switch, a two-threshold comparator, a reversible counter, a decoder, code conversion unitary unit, optocoupler unit, clock pulse generator, variable resistor unit, transistor switch unit, voltage source, inverter, light emitters, resistors and photodetectors.

 The disadvantages of the known device are the relatively low reliability, due to the additional introduction of a large number of elements, and the relatively low noise immunity, due to the fact that even in the absence of a signal at the output of the device, noise amplification occurs.

 A control signal driver is also known (see USSR author's certificate 4677184, class 5 Н 03 G 3/20, 1991. Automatic gain control device), consisting of an amplifier with adjustable gain, an amplitude detector, a sampling device, a clock generator, two amplitude selectors, delay lines, key, comparator, reverse counter.

 The disadvantages of this device are the low accuracy of regulation relative to the information signal, as well as the relatively low noise immunity associated with the amplification of noise in the absence of a signal at the input of the device.

 Closest in technical essence to the proposed one is a method of controlling the power of earth stations implemented in a power control system of earth stations of a satellite communications network (see US patent 4910792, CL N 04 B 7/185, 1997), in which the satellite communications network contains at least one satellite station relaying the signals of earth stations, and several earth stations, one of which is taken as the base. The method consists in generating a test signal at the base station and transmitting it to the satellite station, where the level of the received signal from the base station is measured and stored and taken as the reference one. Test signals are generated at each earth station and the generated test signals are transmitted to the satellite station. At a satellite station, the level of the received test signals is measured and two (own and reference) levels of test signals recorded at the satellite station are transmitted to each earth station. The corresponding earth stations receive them and compare the levels of their own and reference test signals at each earth station, form a control signal by which the power of each earth station is adjusted until the indicated difference between the levels of the own and reference signals becomes zero.

However, the prototype method has disadvantages:
- a relatively high probability of deterioration in communication quality when the load at the entrance of the satellite station changes. This is because an increase in the input load leads to a redistribution of the transmit power of the satellite station between the emitted signals, and therefore, the transmit power of the satellite station per each earth station decreases, which affects the quality of communication between earth stations, and in the worst case, it can become the reason for blocking the service of satellite network users;
- relatively low noise immunity and reliability of the satellite communications network. This is due to the fact that when the interference from the test signal of the base station or its failure occurs, the network may stop working, and the transmission power control of earth stations by test signals spaced in frequency or time from information signals is not always adequately related to the quality of information signals;
- relatively low network bandwidth, due to the fact that the formation of special test signals involves additional frequency and energy resources.

 Closest to the proposed device is the device of the earth stations of the satellite communications network, implemented in a satellite communications system (see RF patent 2090003, CL 6 H 04 B 7/185, 1997), consisting of a transceiver antenna, the input of which is connected to the output of the transmitter, and its output is connected to the input of the radio. The output of the radio is connected to the first input of the equipment of temporary association and separation, the second input of which is the information input of the device. The first output of the equipment of temporary association and separation is connected simultaneously with the input of the transmitter and the input of the delay line, the output of which is connected to the first input of the adder modulo two. The output of the adder modulo two is the information output of the device, and its second input is connected to the second output of the equipment of temporary association and separation.

 Compared with analogues, the prototype device provides increased noise immunity and a reduction in the frequency resource used.

However, the prototype device has disadvantages:
- the inability to assess the quality of communication to control the transmission power of signals in the earth station;
- the impossibility of regulating the transmit power of the earth station, taking into account the quality of communication.

 Closest to the proposed shaper is a shaper of the control signal (see USSR author's certificate 4620478, class 5 Н 03 G 3/20, 1991. Device for automatic gain control) containing an adjustable amplifier, detector, first, second and third comparators, first and second one-shots, delay line, key, first and second AND elements, clock generator and reversible counter. The input of the adjustable amplifier is informational, and its output is connected to the output of the circuit and the input of the detector. The detector output is connected to the inputs of the first, second, and third comparators. The output of the third comparator is connected to the input of the second one-shot, the output of which is connected to the input of the delay line. The outputs of the delay line and the second comparator are connected respectively to the first and second inputs of the key, the output of which is connected to the second input of the first element I. The second input of the second element And is connected to the output of the first one-shot. The first inputs of the first and second elements AND are connected to the output of the clock generator. The outputs of the first and second elements And, respectively, are connected to the first and second input of the reversible counter, the output of which is connected to the second input of the adjustable amplifier.

 Compared with analogues, the shaper prototype has a higher noise immunity.

However, the prototype shaper has disadvantages:
- low accuracy of regulation relative to the information signal, since power regulation is carried out not by assessing the quality of the signal, but by measuring its input level;
- limited scope associated with the processing of only low-frequency signals.

 The aim of the proposed method is to develop a method for controlling the transmit power of earth stations in a satellite communications network, which has higher noise immunity, reliability, bandwidth with the required quality of information channels of a satellite communications network.

 The aim of the proposed device is the development of a device for regulating the transmission power of earth stations in a satellite communications network, which has high control accuracy and bandwidth while ensuring the required quality of information channels of a satellite communications network.

 The aim of the proposed shaper is to develop a shaper of the control signal with higher control accuracy while ensuring the required quality of the information signal, which has a wider scope.

In the proposed method, the goal is achieved by the fact that in the known method of regulating the transmission power of earth stations in a satellite communication network, namely, that at each earth station a test signal is generated, test signals are transmitted from earth stations to a satellite station, relayed to earth stations, receive relayed test signals by the corresponding earth stations, at each earth station a control signal is generated, by which the transmit power is adjusted, previously for a network with utnikovoy connection set minimum k _min k _max and maximum channel quality coefficients communication at a predetermined time interval t _{is measured.} The test signal generated at each earth station is delayed while it travels to the satellite station and vice versa. A signal for controlling the power of the transmitter by each earth station is generated by bitwise addition modulo two received relayed and delayed test signals. The current quality factor of the communication channel k _tech is calculated by counting the number of mismatched elements between the received relayed and delayed test signals. The calculated communication channel quality factor is compared with the previously established minimum and maximum communication channel quality factors, when the conditions k _tech > k _max or k _tech <k _min are met, a control signal is generated to decrease or increase the transmission power, respectively, and the transmission power control process is carried out up to achievement of the condition k _min <k _tech <k _max . As a test signal at each earth station, its information signal is used.

 Thanks to a new set of essential features, which ensures constant quality control of all satellite communication lines included in the common communication network and the formation of a control action that takes into account the individual state of operation of each line, optimal redistribution of the power of the satellite repeater is achieved under conditions of possible changes in the total load at its input. With this control of the transmission power of earth stations in a satellite communication network, higher noise immunity, reliability, and throughput are ensured with the required quality of information channels of the satellite communication network.

 In the proposed device, the goal is achieved by the fact that in the known device of earth stations in a satellite communication network containing a transmitter, the output of which is connected to the input of the transceiver antenna, the output of which is connected to the input of the radio receiver, an element of the delay line, the input of which is connected to the input of the transmitter, and the output is connected modulo two to the first input of the adder, an additional driver of the control signal is introduced, the output of which is connected to the control input of the transmitter, and the input is connected to the output of the adder Odulov two test signal receiver having an input connected to the output of receive antenna and an output to a second input of the adder of modulo two, the output of a radio receiver and transmitter are respectively input data output and data input devices.

 Thanks to a new set of essential features, which provides constant monitoring of the quality of the satellite communication line while controlling the transmission power of the earth stations in the satellite communication network, high regulation accuracy and throughput are ensured with the required quality of the information channels of the satellite communication network.

 In the proposed shaper, the goal is achieved by the fact that in the known driver of the control signal containing the clock generator, the first and second single vibrators are additionally introduced, an input element, an error analyzer, a resolution block, a synchronization block, a memory block, a state estimation unit, an evaluation threshold generator qualities, switch, code generator, initial code generator, and initial state setting unit. The first output of the initial state installation unit is connected to the installation input of the memory unit, which triggers the input of the switch, and to the zeroing input of the code generator. The second output of the initial state setting unit is connected to the enable input of the code generator. The setup input of the code generator is connected to the output of the initial code generator. The output of the quality assessment threshold generator is connected to the installation input of the state evaluation unit, the information input of which is connected to the output of the memory unit. The clock input of the memory block is connected to the first output of the synchronization block. The second output of the synchronization unit is connected to the input of the second one-shot and to the enable inputs of the memory unit and the switch. The information input of the switch is connected to the output of the state assessment unit. The first and second outputs of the switch are connected respectively to the information and switching inputs of the code generator. The output of the second one-shot is connected to the enable and zero inputs, respectively, of the resolution unit and the error analyzer. The output of the error analyzer is connected to the information input of the memory block. The output of the clock generator is connected to the clock inputs of the synchronization block, input element, and resolution block. The output of the resolution block is connected to the input of the first one-shot, the output of which is connected to the resolution inputs of the error analyzer, synchronization block, and input element. The output of the input element is connected to the information input of the error analyzer. The information input of the input element and the output of the shaper code are respectively the input and output of the shaper control signal.

 Thanks to a new set of essential features providing a constant assessment of the quality of the information signal, the accuracy of regulation is increased.

 The analysis of the prior art made it possible to establish that analogues, characterized by a combination of features, are identical to all the features of the proposed technical solution, are absent, which indicates the compliance of the proposed group of inventions with the condition of patentability "novelty".

 Search results for known solutions in this and related fields of technology in order to identify features that match the distinctive features of the prototypes of the proposed group of inventions have shown that they do not follow explicitly from the prior art. The prior art also did not reveal the popularity of the influence provided by the essential features of the proposed group of inventions of the transformations to achieve the specified technical result. Therefore, the proposed group of inventions meets the condition of patentability "inventive step".

The proposed group of inventions is illustrated by the following drawings:
figure 1 - structure of a satellite communications network;
figure 2 - dependence of the measurement error from a sample of measurements;
figure 3 - temporary diagrams explaining the proposed method;
FIG. 4 is a block diagram of a transmission power control device of an earth station in a satellite communications network;
5 is a structural diagram of a driver of a control signal;
6 is a structural diagram of an input element;
7 is a structural diagram of an error analyzer;
Fig. 8 is a block diagram of a memory unit;
Fig.9 is a structural diagram of a state assessment unit;
figure 10 is a structural diagram of a synchronization unit;
11 is a structural diagram of a shaper thresholds for assessing quality,
12 is a structural diagram of a code generator;
Fig is a structural diagram of a switch;
Fig - structural diagram of the shaper initial code;
Fig. 15 is a block diagram of an initial state setting unit;
Fig. 16 is a block diagram of a resolution block.

 The feasibility of the proposed method is explained by the following. In communication systems with multiple access (mainly multiple access with frequency division of signals), the quality of communication between corresponding subscriber stations is determined by the energy parameters of the lines, which depend on the transmission power of the subscriber and base stations, the distribution of the output power of the base station between all operating subscriber stations, and antenna gain feeder devices and noise characteristics of the receiving paths of both subscriber and base station, signal processing, the degree of absorption of radio waves in the propagation medium.

где Р_вхi - мощность сигнала на входе базовой станции от i-й абонентской станции, P_выхБС - выходная мощность передачи базовой станции, P_БСi - мощность базовой станции, расходуемая на излучение сигнала i-й абонентской станции, n - количество одновременно работающих абонентских станций (для МДЧР).In turn, the distribution of the transmit power of the base station depends on the number of subscriber stations working through it and on the strength of the signals received from each subscriber station (see, for example, Military Radio Relay and Troposphere Communication Systems / Ed. By E.A. Volkov. -L .: YOU, 1982, p. 362), i.e.:

where P _ini is the signal power at the input of the base station from the i-th subscriber station, P _exhaust is the output power of the base station, P _BSi is the power of the base station spent on signal emission from the i-th subscriber station, n is the number of simultaneously operating subscriber stations (for FDMA).

(см. , например, Справочник по спутниковой связи и вещанию / Под ред. Л. Я. Кантора. - М.: Радио и связь, 1997, с.94).When these factors change, the quality of communication between individual subscriber stations will change. In particular, these changes can lead to a deterioration in the quality of communication in some radio links. To restore the required quality of communication in these conditions, optimal control of the transmitting power of subscriber stations is necessary. Optimization of regulation consists in the need to simultaneously take into account, on the one hand, the required quality of communication between the corresponding subscriber stations, on the other hand, a more even distribution of the transmitting power of the base station between all operating subscriber stations is possible. The last requirement is determined by the fact that, with a substantially uneven distribution of the transmit power of the base station, mutual suppression of simultaneously operating stations is possible. The degree of suppression of weaker signals strong characterizes the suppression coefficient K _P defined by the expression:

(see, for example, Handbook of satellite communications and broadcasting / Edited by L. Ya. Kantor. - M: Radio and communications, 1997, p. 94).

 The ability to control transmission power is further limited by the maximum equivalent radiated power of the base station.

 Thus, the required quality of operation of the entire system is possible due to the acceptable distribution of the transmission power of the base station between all operating offsetting subscriber stations while monitoring the quality of communication between them.

 These requirements are implemented in the proposed method for regulating the transmit power of earth stations in a satellite communications network. The process of adjusting the transmitting power of subscriber stations can be illustrated by the example of a satellite communication system, a generalized diagram of which is shown in figure 1. The system includes a satellite station (base station), which in the general case can represent a single-channel communication repeater with multiple access without signal processing on board with frequency division multiplexing (FDMA) and a set of n ground-based offset earth stations (subscriber stations).

где

где

- среднее арифметическое элементов выборки, σ_к - выборочная дисперсия, k_текi - элементы выборки.When organizing communications at each earth station, the minimum and maximum coefficients of the quality of the communication channel k _min , k _{max are} pre-set. In digital transmission systems, channel quality indicators are set, as a rule, in the form of a quality criterion - error per bit (see, for example, Handbook of Satellite Communications and Broadcasting / Edited by L. Ya. Kantor. - M.: Radio and Communications, 1997, p. 85), which is defined as the error coefficient k _tech and is the current quality factor of the communication channel:
k _tech = K _NP / K _OP , (1)
where K _NP - the number of incorrectly received characters. To _OP - the total number of characters transmitted. Experimental studies, the results of which are shown in figure 2, show that in order for the measurement error of the probability of occurrence of a single symbol does not exceed 10% with a normal distribution of errors, the selection of measurements should be N≥20. The values of the quality factors of the communication channel k _min and k _max are found experimentally, in advance by the formulas:

Where

Where

is the arithmetic mean of the elements of the sample, σ _k is the sample variance, k _techi are the elements of the sample.

 After entering into communication between the corresponding earth stations, information is exchanged in digital sequences (see, for example, Fig. 3a), where F are the guard interval bits, SK are the clock synchronization recovery bits, SIF are the service information bits, IF are the information message bits.

A test signal is generated at each earth station. Moreover, in the proposed method, its own information signal is used as a test signal (Fig.3b). Test signals at transmission frequencies i, are emitted by earth station antennas towards a satellite station with a certain transmission power level P _0i . At the same time, a test signal generated at each earth station is delayed for the time it passes to the satellite station and back t _delay (Fig. 3d).

Test signals from all ground stations at the appropriate frequencies are fed to the input of the relay, where they are amplified and relayed to the side of the corresponding earth station at the frequency of its reception f _i '.

Thus, at each earth station, a test signal relayed from the satellite station and a corresponding delayed test signal are simultaneously received. Using these two signals, a control signal is generated at each earth station, according to which the transmit power is adjusted. For this, the received relay test signal (Fig. 3c, on which bits are shaded that may be received incorrectly) are added modulo two with the delayed test signal (Fig. 3d). If two bits coincide in the added sequences, the total bit takes the value "0", and if they do not match, it will be "1". Measuring the interval t _{is measured} count the number of symbol errors in _NP K total sequence containing _OP K symbols, i.e. the amount of "1" (see fig.3d). Then calculate k _tech by the formula (1). The calculated k _{tech is} compared with the previously established k _min and k _max . When the conditions k _tech > k _max or k _tech <k _min are met, a control signal is generated to decrease or increase the transmit power, respectively. The control signal, in particular, may be formed in each cycle of a single pulse of a positive polarity at a constant _exercise duration τ and amplitude U _exercise (see., E.g., 3e) with the proviso that _flowed k <k _min, with a negative polarity the same amplitude at k _tech > k _max , and U _yпp = 0 when the condition:
k _min <k _tech <k _max . (2)
The impact of the control pulse in this measurement cycle causes a discrete increase (decrease) in the transmission power of subscriber stations. In the next measurement cycle, if condition (2) is not met, the control signal is re-generated, etc. In the current measurement interval, the transmit power of earth stations does not change. The corresponding regulation according to the results of evaluating the quality of the communication channel is performed at the end of the time interval t _meas . The next measurement begins at the end of the duration of the control pulse. The transmission power control process is carried out until conditions (2) are reached. Considering that all earth stations establish common values of k _min and k _max , at the input of a satellite station the signal levels from different stations will differ and, therefore, after their amplification at the output of a satellite station, this difference will increase, i.e. there is a redistribution of the transmission power of the satellite station in favor of radio lines with the most unfavorable value of k _tech before the start of regulation.

 The transmit power control device of the satellite earth station shown in Fig. 4 comprises a transmitter 1, a transceiver antenna 2, a radio receiver 3, a driver of a control signal 4. The output of the transmitter 1 is connected to the input of the transceiver antenna 2, the output of which is connected to the input of the radio receiver 3. Output shaper control signal 4 is connected to the control input of the transmitter 1. The input of the transmitter 1 and the output of the radio 3 are respectively the information input and output of the device. An additional radio receiver of test signals 5, an adder modulo two 6 and a delay line 7 are additionally introduced into the device. An input of the delay line 7 is connected to the information input of the transmitter 1. The first and second inputs of the adder modulo two 6 are connected respectively to the outputs of the delay line 7 and the radio receiver of test signals 5. The output of the adder modulo 6 is connected to the input of the driver of the control signal 4. The input of the radio of the test signals 5 is connected to the output of the transceiver antenna 2.

 The elements included in the general structure of the transmission power control device are typical and can be technically implemented at present using the available element base.

 As the transceiver antenna 2 can be used any known highly directional parabolic antennas, for example, described in the directory: Satellite communications and broadcasting / Ed. L.Ya. Cantor. - M.: Radio and Communications, 1997, p. 397-409. The transceiver antenna is used in conjunction with a duplex device, which is not shown in Fig. 4. Such devices are known (see, for example, the reference book: Satellite communications and broadcasting / Edited by L.Ya. Kantor. - M .: Radio and communications, 1997, pp. 397-409) and provide transmission and reception simultaneously through one and the same antenna feed at different transmission frequencies.

 The radio receiver 3 and the radio receiver of the test signal 5 are typical radio receivers, described, for example, in the book: Military systems of radio relay and tropospheric communication / Ed. E.A. Volkova. - L .: YOU, 1982, p. 388-389).

 As the transmitter 1, any known transmitter may be used, including an exciter 1.1 and a power amplifier 1.2 with an adjustable gain. General circuits of such transmitters are known and described, for example, in the book: Military Radio Relay and Troposphere Communication Systems / Ed. E.A. Volkova. - L .: YOU, 1982, p.382 - 388. Also known are power amplifiers with adjustable gain, see, for example, RF Patent 2115275 for the invention of "Redundant amplifier".

 As an adder modulo two 6 can be used the adder described in the book: V.A. Batushev, V.N. Veniaminov, V.G. Kovaleva et al. Microcircuits and their application. - M .: Energy, 1978, p.178-180.

 Delay line 7 can be implemented by applying a binary-discrete delay line described in the book: Antennas. Digest of articles. Issue 26 / Ed. A.A. Pistolcors. - M .: Communication, 1978, p. 170-120.

 Shaper control signal 4 is intended for discrete control of transmit power depending on the quality of communication and will be described below.

 A device for controlling the transmit power of earth stations in a satellite communications network operates as follows.

Previously, at the earth station of the satellite communications network in the transmission power control unit, the minimum k _min and maximum k _max communication channel quality coefficients are set for a given time interval t _meas .

 A test signal is generated at the earth station, and its information signal is used as a test signal (Fig. 3b). The information signal from the input of the device simultaneously enters the delay line 7 and the pathogen 1.1. In the exciter 1.1, the signal is transferred to the operating frequency range. The generated microwave signal is amplified in the power amplifier 1.2 to the level necessary for operation, and enters through the duplexing device into antenna 2, where it is radiated towards the satellite station.

 The microwave signal from the correspondent through the satellite station enters the antenna 2 of the earth station and through the duplexing device to the receiving path, where the preliminary amplification, selection of microwave radio signals and their demodulation are carried out. The received signal is fed to the information output of the device.

 After entering into communication between the corresponding earth stations, an information exchange of digital sequences is carried out (see, for example, FIG. 3a).

 At the same time, its microwave signal relayed by the satellite station enters through the antenna path to the test signal receiver 5, which is a typical receiver tuned to the frequency of reception of the correspondent. After transformations in the receiver, the information signal enters the second input of the adder modulo two 6, the first input of which receives the delayed information signal, where they are bitwise added.

If two bits coincide in the added sequences, the total bit takes the value "0", and if they do not match, it will be "1". Measuring the interval t _{is measured} count the number of symbol errors in _NP K total sequence containing _OP K symbols, i.e. the amount of "1" (see Fig. 3d). Then calculate k _tech by the formula (1). The calculated k _{tech is} compared with the previously established k _min and k _max. When the condition k _tech > k _max or k _tech <k _{min is} met, a control signal is generated to decrease or increase the transmit power, respectively. The control signal, in particular, can be generated in each cycle in the form of a single pulse of positive polarity with a constant duration τ _CPR and amplitude U _CPR (see, for example, Fig. 3e), provided that k _tech <k _{min of} negative polarity with the same amplitude at k _tech > k _max , and U = 0 when condition (2) is satisfied.

The impact of the control pulse in this measurement cycle causes a discrete increase (decrease) in the transmit power of the earth station. In the next measurement cycle, if condition (2) is not met, the control signal is re-generated, etc. In the current measurement interval, the transmit power of the earth station does not change. The corresponding regulation according to the results of evaluating the quality of the communication channel is performed at the end of the time interval t _meas . The next measurement begins at the end of the duration of the control pulse. The transmission power control process is carried out until conditions (2) are reached.

 The control signal generator shown in Fig. 5 comprises a clock generator 3, a first 4 and a second 13 single vibrators, additionally introduced, an input element 1, an error analyzer 2, a resolution block 14, a synchronization block 5, a memory block 6, a state estimation unit 7 , the driver of quality assessment thresholds 8, the switch 9, the driver of the code 10, the driver of the initial code 11 and the initial state setting unit 12. The first output of the initial state setting unit 12 is connected to the installation input of the memory unit 6, which triggers the comm input tator 9, and to the zeroing input of the code shaper 10. The second output of the initial state setting unit 12 is connected to the enable input of the code shaper 10. The installation input of the code shaper 10 is connected to the output of the initial code shaper 11. The output of the quality assessment threshold generator 8 is connected to the installation input of the block state assessment 7, the information input of which is connected to the output of the memory unit 6. The clock input of the memory unit 6 is connected to the first output of the synchronization unit 5. The second output of the synchronization unit 5 is connected to the ode of the second one-shot 13 and to the enabling inputs of the memory unit 6 and the switch 9. The information input of the switch 9 is connected to the output of the state evaluation unit 7. The first and second outputs of the switch 9 are connected respectively to the information and switching inputs of the code generator 10. The output of the second one-shot 13 is connected to resolving and zeroing inputs, respectively, of resolution block 14 and error analyzer 2. The output of the error analyzer 2 is connected to the information input of the memory block 6. The output of the clock generator 3 is connected is connected to the clock inputs of the synchronization block 5, the input element 1 and the resolution block 14. The output of the resolution block 14 is connected to the input of the first one-shot, the output of which is connected to the resolving inputs of the error analyzer 2, synchronization block 5, and input element 1. The output of input element 1 is connected to the information input of the error analyzer 2. The information input of the input element 1 and the output of the code generator 10 are respectively the input and output of the gain control device.

 The elements included in the general structure of the shaper are typical and can be technically implemented at present using the available element base.

 The input element 1 is designed to highlight the information sequence from a long series of sequences of signals of the same sign. In particular, it can be implemented on a three-input element And (Fig.6). Such elements are known and described, for example, in the book: V.Yu. Lavrienko. Handbook of semiconductor devices. - Kiev: Technique, 1980, p.399, Fig. 173.

 The first, second and third inputs of the element And are respectively information 1.1, clock 1.2 and allowing 1.3 inputs of the input element 1, and the output of the element And is the output of the input element 1.

The error analyzer 2, shown in Fig.7, is designed to calculate k _tech (counting incorrectly received bits of the information sequence). It can be implemented on binary counters built using digital integrated circuits, described, for example, in the reference book: Digital integrated circuits. - M.: Radio and Communications, 1994, p. 68.

The combined inputs V ₁ and HE-V _{2 of the} binary counter are the resolving input 2.1 of the error analyzer 2. The synchronization input C and the installation input R of the binary counter correspond to the information 2.2 and zeroing 2.3 inputs of the error analyzer 2. Q-outputs of the binary counter correspond to the output of the error analyzer 2, which is a four-digit tire.

 Clock Generator (GTI) 3 provides synchronous operation of all units of the device. The circuits of such generators are known and are given, for example, in the book: Handbook of Integrated Circuits / Ed. V.V. Gibberish - M.: Energy, 1980, p. 588 pic. 5.35; 5.36.

The first one-shot 4 is designed to set the measurement interval t _meas (pulse formation of the required duration). As the first one-shot 4, standby multivibrators can be used, which are described, for example, in the book: V.A. Batushev, V.N. Veniaminov. V.G. Kovaleva et al. Microcircuits and their application. - M .: Energy, 1978, p.193 or V.P. Awl. Line integrated circuits. - M .: Soviet Radio, 1979, p. 210-214.

 The synchronization unit 5, shown in figure 10, is designed to write and read information into the memory unit 7, as well as to control the switch 9. In particular, it can be implemented on the elements AND, AND, NOT, described, for example, in the directory: Digital integrated circuits. - M .: Radio and communications, 1994, p.234-237.

 The second input of the AND 5.1 element is the clock input 5 'of the synchronization block 5. The first input of the And 5.1 element connected to the input of the AND-NOT 5.2 element is the enable input 5 "of the synchronization block 5. The outputs of the AND 5.1 and AND-NOT 5.2 elements are respectively the first 5 "" and second 5 "" outputs of the synchronization unit 5.

The memory unit 6 is designed to store calculation results of the analyzer 2 errors in the transmission power control at each measuring interval t _meas. In particular, it can be implemented on the shift register 6.1 and the elements AND 6.2-6.5 (Fig.8). The schemes of such registers are known and described, for example, in the reference book: Digital Integrated Circuits. - M .: Radio and communications, 1994, p. 62, Fig. 2.49a. Circuits of elements And are also known and described, for example, in the reference book: Digital integrated circuits. - M .: Radio and communications, 1994, p.234-237.

регистра сдвига 6.1 является установочным входом 6'"' блока памяти 6. Q₁-Q₄ выходы регистра сдвига 6.1 соответственно соединены с первыми входами элементов И 6.2-6.5, выходы которых являются выходом блока памяти 6. Информационный вход 6"' и выход блока памяти 6 представляют собой четырехразрядную шину.The second inputs of the elements And 6.2-6.5 are connected and are a 6 'enabling input of the memory block 6. Synchronization input C and the information D ₁ -D ₄ inputs of the shift register 6.1 are respectively 6 "and information 6" inputs of the memory block 6. Installation input

the shift register 6.1 is the installation input 6 '"' of the memory block 6. Q ₁ -Q _{4 the} outputs of the shift register 6.1 are respectively connected to the first inputs of the elements And 6.2-6.5, the outputs of which are the output of the memory block 6. Information input 6"'and the output of the block memory 6 is a four-bit bus.

The state assessment unit 7 shown in FIG. 9 is intended to compare k _tech with k _min and k _max . In particular, it can be implemented on comparators made on integrated circuits described, for example, in the book: B.V. Tarabrin, L.F., Lunin, Yu.N. Smirnov et al. Integrated circuits / Reference. - 2nd ed., Spanish. - M .: Energoatomizdat, 1985, p. 285.

 The A inputs of the comparator 7.1, connected respectively to the inputs of the comparator 7.2, are the information input 7 "of the state evaluation unit 7. The inputs of the comparators 7.1 and 7.2 are the installation input 7 'of the state evaluation unit 7. The third and first outputs of the comparators 7.1 and 7.2 are the output of the state assessment unit 7, which is a two-bit bus.

Shaper of thresholds for assessing quality 8 is intended for setting values of k _min and k _max . In particular, as a shaper of quality assessment thresholds 8 (Fig. 11), resistive matrices on integrated circuits can be used, described, for example, in the book: B.V. Tarabrin, L.F. Lunin, Yu.N., Smirnov et al. Integrated circuits / Reference. - 2nd ed., Spanish. - M .: Energoatomizdat, 1985, p. 190.

 The outputs of the resistive matrices make up the output of the threshold shaper, which is an eight-bit bus.

 The switch 9 shown in Fig.13, is designed to supply information and control signals to the shaper code 10 and start the second one-shot 13. In particular, it can be implemented on the elements OR, AND, NAND, described, for example, in the directory: Digital integrated circuits. - M.: Radio and communications, 1994, p.234-237, and a single vibrator, which can be used in standby multivibrators, which are described in the book: V. A. Batushev, V. I. Veniaminov. V.G. Kovaleva et al. Microcircuits and their application. - M .: Energy, 1978, p.193 or V.P. Awl. Line integrated circuits. - M .: Soviet Radio, 1979, p. 210-214.

 The first and second inputs of the OR element 9.1, connected respectively to the input of the AND-NOT element 9.2 and the second input of the AND 9.3 element, correspond to the information input 9 'of the switch 9. The output of the AND-9.2 element is connected to the first input of the AND 9.3 element, the output of which is the second the output of the switch 9. The output of the OR element 9.1 is connected to the second input of the And 9.4 element, the first input of which corresponds to the enable input 9 "of the switch 9. The output of the And 9.4 element is connected to the second input of the OR element 9.5, the output of which is the first output of the switch 9. First input element OR 9.5 is connected to the output of a single-shot 9.6, the input of which is the trigger input 9 '' 'of the switch 9.

 The shaper code 10, shown in Fig.12, is designed to generate a control signal for regulating the gain of the PA. In particular, it can be implemented on binary counters built using integrated circuits, described, for example, in the reference book: Digital integrated circuits. - M .: Radio and communications, 1994, p.143, fig. 3.78a.

 D-inputs of the binary counter are the setting input 10.1 of the code generator 10. The addition / subtraction ± 1 and synchronization inputs from the binary counter are respectively switching 10.2 and the information 10.3 inputs of the code generator 10. The setting R and enabling E inputs are respectively zeroing 10.4 and allowing 10.5 inputs shaper code 10. The outputs of the counter are the output of the shaper code 10. The installation input 10.1 and the output of the shaper code 10 are a four-bit bus.

Shaper initial code 11 (Fig) is designed to generate a signal corresponding to the code of the initial value of the transmit power P ₀ . In particular, it can be implemented using resistive matrices described, for example, in the book: B.V. Tarabrin, L.F. Lunin, Yu.N. Smirnov et al. Integrated circuits / Reference. - 2nd ed., Spanish. - M .: Energoatomizdat, 1985, p. 190.

 The initial state setting unit 12 shown in FIG. 15 is intended to initialize the error analyzer 2, the memory unit 6, the code generator 10 and the initial start of the updater 4. In particular, it can be implemented using resistive elements described, for example In the book: B.V. Tarabrin, L.F. Lunin, Yu.N. Smirnov et al. Integrated circuits / Reference. - 2nd ed., Spanish. - M .: Energoatomizdat, 1985, p. 190.

 The second one-shot 13 is designed to generate signals with a duration corresponding to the time of transmission power regulation. In particular, standby multivibrators, described, for example, in the book: V.A., can be used as the second one-shot 13. Batushev, V.N. Veniaminov. V.G. Kovaleva et al. Microcircuits and their application. - M .: Energy, 1978, p.193 or V.P. Shilo. Line integrated circuits. - M .: Soviet Radio, 1979, p. 210-214.

 The permission unit 14 (Fig. 16) is designed to start the first one-shot 4. In particular, it can be implemented on the elements NAND, AND, described, for example, in the reference book: Digital integrated circuits. - M .: Radio and communications, 1994, p.234-237.

 The second input of the AND element 14.2 is the information input 14 'of the permission block 14. The input of the AND-NOT element 14.1 is the enable input 14 "of the permission block 14. The output of the AND-NOT element 14.1 is connected to the first input of the AND element 14.2, the output of which is the output of the permission block 14 .

 The work of the proposed shaper can be divided into two stages: the first stage corresponds to the installation of the device in its original state, the second - direct work.

The installation of the device in its initial state involves the following steps: setting thresholds for assessing the signal quality k _min and k _max , preparing for the operation of the code generator 10, preparing for installing the code corresponding to the initial transmit power of the PA P ₀ , zeroing the memory block 6.

The thresholds for evaluating the quality of the signal k _min and k _max are set by connecting the installation input 7 'of the state estimation unit 7 (Fig. 9) through the resistance R of the resistive matrices of the driver of the thresholds for assessing the quality 8 (Fig. 11) to the power source E.

 In this case, a code is generated that is determined by connecting the installation inputs of the comparators 7.1 and 7.2 (Fig. 9), relative to which the current signal quality is evaluated and, subsequently, the transmission power is adjusted.

Preparation of the code shaper 10 to generate the initial transmit power code of the PA P _{0 is} carried out by connecting the setting inputs 10.1 of the binary counter of the code shaper 10 (Fig. 12) through the resistance R of the resistive matrix of the shaper of the initial code 11 (Fig. 14) to the power source E, as well as by feeding to the enable input 9.5 of the driver of the code 10 of the signal corresponding to the logical "1" generated in the initial state setting unit 12 (output 2, Fig. 15) by connecting the resistance R to the power source E.

 The reset of the counter of the code shaper 10 (Fig. 12) is carried out by supplying to the resetting input 9.4 (Fig. 12) a logical "1" generated in the initial state setting unit 12 (output 1, Fig. 15) by connecting the resistance R to the power source E .

 The reset of the previous states corresponding to the zeroing of the register in the memory block 6 (Fig. 8) is carried out by applying the signal corresponding to the logical "1" by connecting the power supply E through the resistor R of the initial state setting unit 12 (output 1, Fig. 15) to the installation input 6 " "memory block 6 (Fig.8).

 The set of actions described above prepares the device for direct operation.

The generated signal in the initial state setting unit 12, corresponding to the logical “1”, from the output 12.1 (Fig. 12) is supplied to the triggering input 9 ″ of the switch 9 (Fig. 13). This signal triggers the one-shot 9.6 (Fig.13) generating a pulse signal, which through the OR element 9.5 of the switch 9 (Fig. 13) through its first output is fed to the information input 10.3 of the code generator 10 (Fig.12). This signal provides a record in the binary counter (Fig. 12) of the generated code in the generator of the initial code 11 (Fig. 14) at the stage of installation of the device in its initial state. As a result, at the output of the code generator 10, the initial transmission power code of the PA P _{0 is set} , with respect to which the output signal of the PA is further regulated. This defines a further algorithm for the operation of the gain control device.

The conformity of the output power of the PA with the required quality of the generated signal is assessed over a period of time _{tmeasurements} sufficient for a set of statistical data on the error coefficient corresponding to the current signal quality. The required time interval t is _measured by the first one-shot 4, which starts when there is no signal at the resolution 14 "and information 14 'inputs of the resolution block 14 (Fig. 16), respectively, from the outputs of the second one-shot 13 and GTI 3.

 The signal generated by the first one-shot 4, simultaneously fed to the enable inputs of the input element 1 (input 1.3, Fig.6), error analyzer 2 (input 2.1, Fig.7), synchronization unit 5 (input 5 "of Fig.10), performs a number of functions : sets the counting time of single pulses arriving at the information input of input element 1 (input 1.1, Fig. 6), the logic of which is determined by a three-input element And (Fig. 6). The signal at the output of input element 1 appears during the signal generated by the first one-shot 4 with the arrival of the information signal Ala corresponding logical "1" with the frequency of the GTI 3 supplied to the clock input 1.2 of the input element 1 (Fig.6) from the GTI 3.

 Information signals from the output of the input element 1 are fed to the information input 2.1 of the error analyzer 2, which is the synchronizing input of the binary counter (Fig.7). Since the write-enabled inputs 2.1 of the binary counter of the error analyzer 2 (Fig. 7) are connected to the output of the first one-shot 4, this provides a count of incoming pulses to the information input 2.2 of the error analyzer 2 only during the operation of the first one-shot 4. The binary counter (Fig. 7), having counted the number of information pulses, generates an information signal at its output in the form of a binary code, which according to the signals generated in synchronization block 5 (Fig. 10, element I 5.1, output 5 "") with a pulse repetition rate in the GTI 3, supplied to the first input of the And 5.1 element, during the operation of the first one-shot 4, whose signals are fed to the input 5 "of the And 5.1 element, are recorded in the memory unit 6. The recorded information in the memory unit 6 is stored until the next receipt of information signals from the output error analyzer 2. During operation of error analyzer 2, information is not read from the memory block 6. This is ensured by the fact that during operation of the first one-shot 4 in the synchronization block 5 at the output of the AND-NOT 5.2 element (Fig. 10) th signal of logic "0", which, acting on the enable input 6 'of the storage unit 6 (Figure 8, the first inputs of AND gates 6.2-6.5), provides a logic "0" at the output of these elements and the storage unit 6 as a whole. The same inhibitory signal blocks the promotion of information from the output of the state estimation unit 7 through the elements of the switch 9 to the input of the code generator 10. Blocking is carried out by supplying a logical "0" to the second input of the element And 9.4 (Fig. 13), corresponding to the allow input 9 "of the switch 9.

 Upon completion of the operation of the first one-shot 4 at the output of the AND-NOT 5.2 element (Fig. 10), an enable signal is generated corresponding to the logical "1", which ensures the reading of information from memory unit 6 and the recording of information through switch 9 (logical "1" at the second input element And 9.4, Fig. 13) on the shaper code 10, and also provides the launch of the second one-shot 13.

Information in the form of a code from the output of the memory unit 6 is supplied to the A-inputs of the comparators 7.1,7.2 corresponding to the information input of the evaluation unit 7 (Fig. 9). Since the installation inputs 7 'of the comparators 7.1 and 7.2 (Fig. 9) are pre-installed with a code corresponding to the required thresholds for evaluating the signal quality k _min and k _max , then the comparators 7.1 and 7.2 compare the code of the information signal with the threshold codes. The comparison results in the form of logical signals "1" or "0" from the outputs of the comparators 7.1 and 7.2 (Fig. 9) are fed to the information input 9 'of the switch 9 (Fig.13), which depending on what the information signal corresponds to the selected threshold connects the first and second output of the switch 9 to the switching and to the information inputs of the code generator 10, or only to the information input of the code generator 10 (Fig. 12).

Consider the possible cases. If k _tech > k _max , then the output of the comparator 7.1 (Fig.9) will be a logical signal "0", and at the output of the comparator 7.2 - "1". These signals, arriving at the information input 9 'of the switch 9 (Fig.13), which corresponds to the supply of signals logical "0" and logical "1" to the inputs of the OR element 9.1 (Fig.13). As a result, a logical "1" signal will be generated at the second output of the switch 9, which, entering the switching input 10.2 of the code generator 10, puts the binary counter of the code generator 10 (Fig. 13) into the account increase mode. Upon the arrival of the information signal from the first output of the switch 9 to the information input 10.3 of the code generator 10, the binary counter at its output increases the discharge code relative to the previously set one by one, which corresponds to an increase in the transmitter power.

If k _tech <k _min at the output of the comparators 7.1 and 7.2 (Fig. 9) there will be logical “1” and logical “0” signals, respectively, then logical “1” and logical “0” will be generated at the first and second outputs of switch 9 . These signals include a binary counter of the code generator 10 (Fig. 13) for decreasing the counter output code (Fig. 12) relative to the preset one. This corresponds to a decrease in transmitter power.

In the case of k _min <k _tech <k _max at the outputs of the comparators 7.1 and 7.2, logical 0 signals are generated. This corresponds to the fact that the logical “0” signals are generated at the first and second outputs of the switch 9, which do not change the state of the binary counter of the code generator 10 (Fig. 12). This corresponds to the fact that the transmitter power remains unchanged.

At the time of regulating the transmission power to ensure stable operation of the device and obtain unambiguous results, it is necessary to prohibit the passage of information pulses to the error analyzer 2, prohibit its operation, zero and prepare it for work on the next t _measurement interval. This set of actions is ensured by turning on the second one-shot 13 according to the signal generated in the synchronization block 5 by the AND-NOT 5.2 element (Fig. 10) at the end of the first one-shot 4. The signal from the output of the second one-shot 13 is fed to the resetting input 2.3 of the error analyzer 2 (Fig. 7), zeroes it, and also enters the enable input 14 "of the permission unit 14 (Fig. 16), providing a ban on starting the first one-shot 4. At the end of the second one-shot 13, a signal is generated at the output of the AND-NOT 14.1 element (Fig. 16) corresponding th logical "1", which will be allowing to turn on the first one-shot 4 for the next cycle of work.

Claims (4)

1. A method for controlling the transmit power of earth stations in a satellite communication network, which consists in generating a test signal at each earth station, transmitting test signals from earth stations to a satellite station, relaying them to earth stations, receiving relayed test signals by corresponding earth stations, each earth station form a control signal, which regulate the transmit power level of the earth station, characterized in that previously set for the satellite communications network the minimum k _min and maximum k _max communication channel quality coefficients for a given time interval t _measured , the test signal generated at each earth station is delayed by the time it takes to travel to the satellite station and vice versa, and the transmitter power control signal of each earth station is generated by bitwise addition modulo two received relay and delayed test signals, calculate the current quality factor of the communication channel k _tech by counting the number of mismatched elements between the received signal with the transmitted and delayed test signals, the calculated communication channel quality factor is compared with the previously established minimum and maximum communication channel quality factors, when the conditions k _tech > k _max or k _tech <k _min are met, a control signal is generated to decrease or increase the transmission power, respectively, and the transmission power control process is carried out until the condition k _min <k _tech <k _max .  2. The method according to claim 1, characterized in that its information signal is used as a test signal at each earth station.  3. A transmission power control device for an earth station in a satellite communication system, comprising a transmitter whose output is connected to an input of a transceiver antenna, the output of which is connected to an input of a radio receiver, an element of a delay line whose input is connected to an input of a transmitter, and the output is connected to the first input of an adder modulo two, characterized in that the driver of the control signal is additionally introduced, the output of which is connected to the control input of the transmitter, and the input is connected to the output of the adder modulo two, radio iemnik test signal input is connected to the output of receive antenna and an output to a second input of the adder of modulo two, the radio transmitter output and input are respectively data output and data input devices.  4. The driver signal of the control signal, containing a clock generator, the first and second one-shot, characterized in that the input element, an error analyzer, a resolution unit, a synchronization unit, a memory unit, a state evaluation unit, a quality assessment threshold generator, a switch, a code generator are additionally introduced , the initial code generator and the initial state setting unit, the first output of which is connected to the installation input of the memory block, the triggering input of the switch and to the zeroing input of the former ode, the second output of the initial state setting unit is connected to the enable input of the code generator, the installation input of which is connected to the output of the initial code generator, the output of the quality assessment threshold generator is connected to the installation input of the state evaluation unit, the information input of which is connected to the output of the memory block, whose clock input connected to the first output of the synchronization unit, the second output of the synchronization unit is connected to the input of the second one-shot and to the enabling inputs of the memory unit and the switch RA, the information input of which is connected to the output of the state estimation unit, the first and second outputs of the switch are connected respectively to the information and switching inputs of the code generator, the output of the second one-shot is connected to the enable and zero inputs of the resolution block and the error analyzer, the output of which is connected to the information input of the block memory, the output of the clock generator is connected to the clock inputs of the synchronization block, the input element and the resolution block, the output of which is connected is connected to the input of the first one-shot, the output of which is connected to the resolving inputs of the error analyzer, the synchronization unit, and the input element, the output of which is connected to the information input of the error analyzer, the information input of the input element and the output of the code generator are the input and output of the driver of the control signal.

Images