RU2307465C1 - Device for controlling transmission power of satellite communication ground station - Google Patents

Abstract

FIELD: radio engineering, possible use in systems of satellite, radio relay and troposphere.

SUBSTANCE: device consists of transmitter, receiving-transmitting antenna, radio-receiver of test signal, radio-receiver of information signal, generator of control signal, delay line, turbo-coder of information signal, turbo-coders of test and information series. Control signal for controlling transmission power of satellite communication ground station is created for a time corresponding to time of transmission of one code block.

EFFECT: creation of device for controlling transmission power of satellite communication ground station, ensuring reduced time needed for generation of control signal for adjusting transmission power of satellite communication ground station.

2 cl, 8 dwg

Description

The invention relates to radio engineering and can be used in satellite, radio relay and tropospheric communication systems.

A device for regulating the transmission power in a ground station of a satellite communications system (see JP 6052882, cl. 5 HB04/155, 1997), comprising a first receiver receiving a beacon signal from a space station, a signal transmitter to a space station, a second receiver, which receives a response signal from the transmitter, a device for regulating the output signal level, 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 satellite communications network earth station device implemented in a satellite communications system is also known (see RF patent 2090003, cl. 6 Н04В 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 a radio receiver. 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.

The disadvantages of this device are the inability to assess the quality of communication to control the transmission power of signals in the earth station, as well as the inability to control the transmission power of the earth station taking into account the quality of communication.

Closest to the proposed device is a device for regulating the transmit power of an earth station (see RF patent 2214682 C2, CL HB04/005, 2003), consisting of a transmitter whose output is connected to the input of the transceiver antenna, the output of which is connected to the input of the radio receiver, element a delay line, the input of which is connected to the input of the transmitter, and the output is connected to the first input of the adder modulo two, the driver of the control signal, the output of which is connected to the control input of the transmitter, and the input is connected to the output of the adder about module two, the radio of the test signal, the input of which is connected to the output of the transceiver antenna, and the output is to the second input of the adder modulo two, the output of the radio receiver and the input of the transmitter are respectively the information output and the information input of the device.

Compared with analogs, the prototype device improves the accuracy of regulating the transmit power of the satellite earth station and throughput, ensuring the required quality of the information channels of the satellite communications network.

The disadvantage of the prototype is the relatively long time to regulate the transmit power of the earth station of satellite communications (SSSS), due to the need to calculate the error rate per bit, which ultimately can lead to a decrease in the quality of communication and even to its failure.

The aim of the claimed invention is the development of a device for regulating the transmission power of the SSSS, which reduces the time it takes to generate a control signal for regulating the transmission power of the SSSS.

This goal is achieved by the fact that in the known device for regulating the transmit power of the SSSS containing a transceiver antenna (PAP), the output of which is connected to the radio of the test signal (RPTS) and the radio of the information signal (RPIS), the transmitter, the output of which is connected to the input of the transmitter power amplifier and the output of the power amplifier of the transmitter is connected to the input of the PAP, the driver of the control signal (FCS), the output of which is connected to the control input of the power amplifier, and a delay line (LZ), input One of which is connected to the transmitter input, the turbo encoder of the information signal (TKIS), turbo decoders of the test (TDTP) and information (TDIP) sequences are additionally introduced, with the input of the TKIS being the information input of the device and the output of the TKIS connected to the input of the transmitter, the output of the RPTS connected to the channel input TDTP, the installation input of the TDTP is connected to the output of the LZ, and the output of the TDTP is connected to the input of the FUS, the output of the RPIS is connected to the channel input of the TDIP, the output of which is the information output of the device.

The FUS consists of the elements of the initial state installation (EECS) and transmission quality assessment (EECP), the switch, the sensors of the initial code (DNA), the transmit power control code (DCMP) and the quality assessment thresholds (DOCC), and the output of the EECS is connected to the trigger input of the switch and the nulling input DKUMP, the output of which is the information output of the FUS, the output of the DPOK is connected to the installation input of the EOSF, the input of which is the information input of the FUS, and the output of the EOS is connected to the information input of the switch, the output of which is connected DKUMP data input, the input to the installation of which is coupled DNA.

Thanks to the new combination of essential features and the introduction of SCIS, TDIP and TDTP into this combination, the control signal for regulating the transmit power of the SSSC is generated in a time corresponding to the transmission time of one code block, which ensures its significant reduction.

The analysis of the prior art made it possible to establish that analogues that are characterized by a combination of features that 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".

The 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 claimed device is illustrated by drawings, which show:

figure 1 - device for regulating the transmission power of an earth station in satellite communications;

figure 2 - driver control signal (FUS);

figure 3 is an element of the assessment of transmission quality (EOKP);

figure 4 - sensor thresholds for assessing quality (QPS);

figure 5 - switch;

figure 6 - sensor code control power transmission (DCMP);

figure 7 - sensor initial code (DNA);

on Fig - element setting the initial state (EUNS);

The transmission power control device ZSSS shown in figure 1, contains a transmitter 1, PAP 2, RPTS 3, RPIS 4, FUS 5, LZ 6, TKIS 7, TDTP 8 and TDIP 9. The output of the transmitter 1 is connected to the input of the PAP 2, the output which is connected to the input RPIS 4. The input LZ 6 is connected to the input of the transmitter 1. The output of the FCS 5 is connected to the control input of the transmitter 1. The input RPTS 3 is connected to the output of the control panel 2. The input TKIS 7 is the information input of the device, and its output is connected to the input of the transmitter 1. The output of the RPTS 3 is connected to the channel input of the TDTP 8. The installation input of the TDTP 8 is connected to the output LZ 6. Yield tdtp 8 connected to the input 5. Yield RPIS SCF 4 is connected to channel input TDIP 9, whose output is the data output device.

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

The driver signal 5 is designed for discrete control of the transmit power of the SSSC depending on the quality of communication and can be implemented in various ways. In particular, the FUS shown in FIG. 2 consists of EUNS 5.1, EOKP 5.4, switch 5.3, DNA 5.5, DKUMP 5.2 and DPOK 5.6. The output of EUNS 5.1 is connected to the trigger input of the switch 5.3 and the resetting input of the DCUMP 5.2. The output of DKUMP 5.2 is the information output of the FSF 5. The output of the DPK 5.6 is connected to the installation input of the EOKP 5.4, the input of which is the information input of the FSF 5. The output of the EKP 5.4 is connected to the information input of the switch 5.3. The output of switch 5.3 is connected to the information input of DCUMP 5.2, to the installation input of which DNA 5.5 is connected.

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

Evaluating transmission quality element 5.4 is designed to compare the current value of the module log-likelihood ratio Λ _Requires required Λ _des. The circuit of the element can be implemented in various ways, in particular, as shown in figure 3, on the basis of a comparator made on integrated circuits described, for example, in the book: B.V. Tarabrin, L.F. Lunin, Yu.N. Smirnov et al. Integrated circuits / Handbook, 2nd edition, isp. - M .: Energoatomizdat, 1985, p. 285.

A-inputs of the comparator are the information input of EOKP 5.4. B-inputs of the comparator are the installation input of EOKP 5.4. The third and first outputs of the comparator are the output of EOKP 5.4, which is a two-bit bus.

The threshold sensor for quality assessment 5.6 is designed to set the required value of the module of the logarithm of the likelihood ratio Λ _req . The circuit of the element can be implemented in various ways, in particular, as shown in figure 4, on the basis of resistive matrices on integrated circuits described, for example, in the book: B.V. Tarabrin, L.F. Lunin, Yu.N. Smirnov et al. Integrated circuits / Handbook, 2nd edition, isp. - M .: Energoatomizdat, 1985, p. 190.

The outputs of the resistive matrices make up the output of the DPOK 5.6, which is an eight-bit bus.

Switch 5.3 is designed to supply information and control signals to DCUMP 5.2. The switch circuit can be implemented in various ways, in particular, as shown in figure 5, on the elements OR, AND, AND, NOT, described, for example, in the reference book: Digital integrated circuits. - M .: Radio and communications, 1994, p.234-237, and a single vibrator, which can be used as standby multivibrators, which are described in the book: V.A. Batushev, V.I. Veniaminov, V.G. Kovaleva and other microcircuits and their application. - M .: Energy, 1978, p.193 or V.P. Shilo. Line integrated circuits. - M .: Soviet Radio, 1979, p. 210-214.

The first and second inputs of the OR 5.3.1 element, connected respectively to the input of the AND-NOT 5.3.2 element and the second input of the AND 5.3.3 element, correspond to the information input of the switch 5.3. The output of the AND-NOT 5.3.2 element is connected to the first input of the AND 5.3.3 element, the output of which is the second output of the 5.3 switch. The output of the OR 5.3.1 element is connected to the second input of the AND 5.3.4 element, the first input of which corresponds to the enable input of the 5.3 switch. The output of the AND 5.3.4 element is connected to the second input of the OR 5.3.5 element, the output of which is the first output of the 5.3 switch. The first input of the OR 5.3.5 element is connected to the output of the single-shot 5.3.6, the input of which is the trigger input 3 '' of the switch 5.3.

The transmitter power control code sensor 5.2 is designed to generate a control signal for regulating the gain of the power amplifier. The circuit of an element can be implemented in various ways, in particular, as shown in FIG. 6, on binary counters constructed using integrated circuits described, for example, in the reference manual: Digital integrated circuits. - M .: Radio and communications, 1994, p.143, fig. 3.78a.

D-inputs of the binary counter are the installation input of DCUMP 5.2. The addition / subtraction ± 1 and synchronization inputs from the binary counter are the switching and information inputs of DCUMP 5.2, respectively. The installation R and enabling E inputs are respectively zeroing and enabling inputs of DCUMP 5.2. The outputs of the counter are the output of DCUMP 5.2. The installation input and output of the DCUMP 5.2 is a four-digit bus.

The sensor initial code 5.5 is designed to generate a signal corresponding to the code of the initial value of the transmit power P ₀ . The circuit of the element can be implemented in various ways, in particular, as shown in Fig. 7, on the basis of resistive matrices described, for example, in the book: B.V. Tarabrin, L.F. Lunin, Yu.N. Smirnov, etc. Integrated Circuits / Handbook, 2nd Edition, Spanish - M .: Energoatomizdat, 1985, p. 190.

The outputs of the resistive matrices make up the 5.6 DNA output, which is an eight-bit bus.

The element for setting the initial state 5.1 is intended for initializing the DCUMP 5.2 and for managing the switch 5.3. The circuit of the element can be implemented in various ways, in particular, as shown in Fig. 8, on the basis of resistive elements described, for example, in the book: B.V. Tarabrin, L.F. Lunin, Yu.N. Smirnov, etc. Integrated Circuits / Handbook, 2nd Edition, Spanish - M .: Energoatomizdat, 1985, p. 190.

The outputs of the resistive matrices comprise the outputs of the EUNS 5.1, which are single-bit buses, and are connected to the DCUMP 5.2 and the switch 5.3.

The transceiver antenna 2 is designed to convert an electrical signal coming from the transmitter into an electromagnetic wave and its radiation into the environment during transmission and inverse conversion during reception. As PPA 2 can be used any known highly directional parabolic antennas, described, for example, in the reference book: Satellite communications and broadcasting / Ed. L.Ya. Kantora. - M.: Radio and Communications, 1997, p. 397-409. PAP 2 is used together with a duplexing device, which is not shown in Fig. 1. Such devices are also known and described, for example, in the directory: Satellite Communications and Broadcasting / Ed. L.Ya. Kantora. - M .: Radio and communications, 1997, p.397-409, and provide transmission and reception simultaneously through the same antenna feed at different transmission and reception frequencies.

The radio signal information signal 4 is intended for pre-amplification, selection of the microwave signal and its demodulation. RPIS 4 is a typical radio receiving device, described, for example, in the book: Military systems of radio relay and tropospheric communications / Ed. E.A. Volkova. - L .: YOU, 1982, p. 388-389.

The radio of the test signal 3 is intended for pre-amplification, selection of the microwave signal and its demodulation. RPTS 3 is a typical radio receiving device, described, for example, in the book: Military systems of radio relay and tropospheric communication / Ed. E.A. Volkova. - L .: YOU, 1982, p. 388-389.

The transmitter 1 is designed to transfer the signal to the operating frequency range and amplify it to the level necessary for operation. 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. The general schemes 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".

Delay line 6 is designed to delay the information signal for the time required for its passage to the communication relay and back. LZ 6 can be implemented by applying a binary-discrete delay line described in the book: Antennas. Digest of articles. Issue 26 / Ed. A.A. Pistolkors. - M .: Communication, 1978, p. 170-120.

The turbo encoder information signal 7 is designed to encode the information signal according to a given algorithm. General schemes of such turbo encoders are known and described, for example, in the book: Sklyar B. Digital communication. Theoretical Foundations and Practical Application, 2nd Edition - M .: Williams, 2003, pp. 510-515. The specific scheme of SCIS 7 will depend on the selected coding rule and the code used.

Turbo decoder information sequence 9 is designed to decode a signal coming from a demodulator. General schemes of such turbo decoders are known and described, for example, in the book: Sklyar B. Digital communication. Theoretical Foundations and Practical Application, 2nd Edition - M.: Williams, 2003, pp. 515-518. The specific decoder circuitry will depend on the encoding rule chosen and the code used.

The turbo decoder of the test sequence 8 is designed to calculate the current average value of the logarithm of the likelihood ratio of the test sequence Λ _tech . General schemes of such turbo decoders are known and described, for example, in the book: Sklyar B. Digital communication. Theoretical Foundations and Practical Application, 2nd Edition - M.: Williams, 2003, pp. 515-518. The installation input and output of the TDTP 8 are formed as a result of the feedback gap shown in the general diagram of the turbo decoder.

The device for regulating the transmission power of the SSSS operates as follows. Pre ZSSS set for all the desired average value of the modulus of the logarithm of the likelihood ratio Λ _{is required} at the output of the turbo decoder for the test sequence with the code used and the number of iterations for decoding of the number of transmitted symbols n.

A test signal is generated at the SSSS, and its information signal is used as a test signal. The information signal from the input of the device goes to the SCIS 7, where encoding is performed, in the general case, by a generalized cascade code, from the output of the SCIS 7, the signal goes to LZ 6 and the pathogen 1.2. In the exciter 1.2, the signal is transferred to the operating frequency range. The generated microwave signal is amplified in the power amplifier 1.1 to the level necessary for operation. Next, the signal enters through the duplexing device in the PAP 2, where it is radiated towards the repeater.

The microwave signal from the correspondent through the repeater enters the antenna of the receiving station and through the duplexing device to the receiving path, where it is pre-amplified, selected and demodulated. The received signal is fed to the TDIP 9, where it is decoded and then the decoded information is fed to the information output of the device.

After entering the communication between the corresponding stations, an information exchange of digital sequences is carried out.

At the same time, on each satellite earth earth station, its microwave signal is transmitted through the antenna path to RPTS 3, which is a typical receiver tuned to the frequency of reception of the correspondent, whose demodulator gives “soft” output decisions. After transformations in the receiver, the signal is fed to the channel input of the TDTP 8, to the installation input of which, as an a priori information, the delayed information signal from the output of the TKIS 7 is received. The TDTP 8 iteratively decodes the “soft” decisions in the form of the logarithm of the likelihood ratio of hypotheses about the values of the transmitted blocks Λ _tech symbols characterizing the reliability of the received information. From the output of the TDTP 8, the value of the module of the logarithm of the likelihood ratio is fed to the input of the FCS 5.

With good channel quality (large signal / (noise plus noise) ratio) at the output of TDP 8, the likelihood ratio logarithm module takes large values, and at low ratios the signal / (interference plus noise) in the channel is smaller. FUS 5 compares Λ _tech with previously established Λ _req . When Λ _{tech is} greater than Λ _demand and Λ _{tech is} less than Λ _demand form a control signal, respectively, to reduce or increase the transmit power.

The impact of the control pulse in this measurement cycle causes a discrete increase (decrease) in the transmit power of the SSSS. In the next measurement cycle, the control signal, etc., is re-formed.

The work of FUS 5 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 a threshold for assessing the signal quality Λ _required , preparing for operation DCUMP 5.2, preparing for setting the code corresponding to the initial transmit power of the amplifier R ₀ .

The threshold for assessing the signal quality Λ _{required is} made by connecting the installation input of the EOKP 5.4 (figure 3) through the resistance R of the resistive matrices DPOK 5.6 (figure 4) to the power source E.

In this case, a code is generated that is determined by connecting the installation inputs of the comparator (Fig. 3), with respect to which the current signal quality is assessed and, subsequently, the transmission power is adjusted.

Preparation of DCUMP 5.2 to the formation of the initial transmit power code of UM R _{0 is} carried out by connecting the installation inputs of the binary counter DCUMP 5.2 (Fig. 6) through the resistance R of the resistive DNA matrix 5.6 (Fig. 4) to the power source E, as well as by applying it to the enabling input of DCUMP 5.2 the signal corresponding to the logical "1" generated in EUNS 5.1 (output 1.2, Fig.8), by connecting the resistance R to the power source E.

Zeroing the counter DKUMP 5.2 (Fig.6) is carried out by supplying to its zeroing input a logical "1", formed in EUNS 5.1 (output 1.1, Fig.8), by connecting the resistance R to the power source E.

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

The generated signal in EUNS 5.1, corresponding to the logical "1", from the output 1.1 (Fig. 8) is fed to the triggering input 3 "of the switch 5.3 (Fig. 5). This signal triggers a single-shot 5.3.6 (Fig. 5), which generates a pulse signal which, through the first output of the OR element 5.3.5 of the switch 5.3 (Fig. 5), is fed to the information input of the DCUMP 5.2 (Fig. 6) This signal provides a record in the binary counter (Fig. 6) of the generated code in DNA 5.5 (Fig. 7) ) at the stage of installation of the device in its initial state.As a result, the initial power code is set at the output of DCUMP 5.2 Transferring amplifier power P _0, with respect to which produce further regulation of the power amplifier output signal. This algorithm determines the further work of transmission power control device ZSSS.

Evaluation of the correspondence of the output power of the power amplifier to the required quality of the generated signal is carried out at the moment of receipt of the likelihood ratio log module Λ _tech at the FUS 5 information input, which in the form of a code goes to the A-inputs of the comparator corresponding to the information input of the EECP 5.4 (Fig. 3). Since at the mounting comparator inputs (3) is preset code corresponding to the desired threshold signal quality assessment Λ _required, via code comparator producing a comparison data signal from the threshold code. The comparison results in the form of logical signals "1" or "0" from the output of the comparator (Fig. 3) are fed to the information input of the switch 5.3 (Fig. 5), its outputs, depending on the correspondence of the information signal with respect to the selected threshold, are connected to the switching and information inputs DKUMP 5.2 (Fig.6).

Consider the possible cases. If Λ _{tech is} greater than Λ is _required , then at the output "A>B" of the comparator (Fig. 3) there will be a logical signal "1", and at the output "A <B" - "0". These signals are fed to the information input of the switch 5.3 (figure 5), which corresponds to the supply of signals logical "1" and logical "0" to the inputs of the element OR 5.3.1 (figure 5). As a result, a logical “0” signal will be generated at the second output of switch 5.3, which, entering the switching input of DCUMP 5.2, puts its binary counter in the mode of decreasing the count. Upon the arrival of the information signal from the first output of the switch 5.3 to the information input of the DCUMP 5.2, the binary counter reduces the discharge code at its output relative to the previously set one, which corresponds to a decrease in the transmitter power.

If Λ _{tech is} less than Λ _required , at the output of the comparator (Fig. 3) there will be logical “0” and logical “1” signals, respectively, then logical “1” will be generated at the second output of switch 5.3. This signal includes a binary counter DKUMP 5.2 (Fig.6) to increase the counter output code (Fig.6) relative to the previously set, which corresponds to an increase in transmitter power.

In the case of Λ, the _tech is equal to Λ _required ; at the output of the comparator, 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 5.3, which do not change the state of the binary counter DCUMP 5.2 (Fig.6). This corresponds to the fact that the transmitter power remains unchanged.

The next cycle of the device starts when it arrives at the information input of the FSF 5 of the next value Λ _tech and the sequence of operations is repeated.

Thus, the regulation of the transmit power of the earth station occurs at the end of the reception of one block of code symbols, which significantly reduces the regulation time, and accordingly increases the stability of the satellite communication line.

Claims (2)

1. The transmission power control device of a satellite communications earth station containing a transmitting and receiving antenna, the output of which is connected to a test signal radio receiver and an information signal radio receiver, a transmitter whose exciter output is connected to an input of a transmitter power amplifier, and a transmitter amplifier output is connected to a receiver input - a transmitting antenna, a driver of the control signal, the output of which is connected to the control input of the power amplifier, and a delay line, the input of which is connected to the transmitter input, characterized in that the turbo encoder of the information signal, turbo decoders of the test and information sequences are additionally introduced, the input of the turbo encoder of the information signal is the information input of the device, and the output of the turbo encoder of the information sequence is connected to the transmitter input, the output of the test signal radio receiver is connected to the channel input of the test sequence turbo decoder , the test turbo decoder setup input is connected to the line output and delay, and the output of the turbo decoder test sequence is connected to an input of the control signal, the radio data signal output is connected to the input channel turbo decoder information sequence, the output of which is a data output device. 2. The device according to claim 1, characterized in that the driver of the control signal consists of elements for setting the initial state and transmitting quality assessment, a switch, sensors for the initial code, transmit power control code and quality assessment thresholds, the output of the initial setting element being connected to the trigger the input of the switch and the nulling input of the sensor of the transmit power control code, the output of which is the information output of the driver of the control signal, the output of the sensor VA is connected to the installation input of the transmission quality assessment element, the input of which is the information input of the control signal generator, and the output of the transmission quality assessment element is connected to the information input of the switch, the output of which is connected to the information input of the transmit power control code sensor, to the installation input of which the initial sensor is connected code.

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