UA140822U - SYSTEM WITH MANY INPUTS AND MANY EXITS (MIMO) WITH THE POSSIBILITY OF SELF-LEARNING - Google Patents

Abstract

The system with multiple inputs and multiple outputs (MIMO) with the possibility of self-learning includes a transmitting part, a receiving part, the transmitting part contains a data source, an encoder, a low frequency modulator, a buffer device, the first channel of the transmitting part, the second channel of the transmitting part. the first channel of the transmitting part includes a high frequency (HF) modulator of the first channel of the transmitting part, a frequency synthesizer of the first channel of the transmitting part, and the second channel of the transmitting part contains a HF modulator of the second channel of the transmitting part, the data source output is connected. with the input of the encoder, the output of which is connected to the input of the low frequency modulator, the output of the low frequency modulator is connected to the input of the buffer device whose output is connected to the input of the first channel of the transmitting part and the input of the second channel of the transmitting part with antenna devices, receiving part It includes a first receiving part channel, a second receiving part channel, a receiving part buffer device, a receiving part quadrature converter, a receiving part decoder, a data receiver, and a receiving part channel status assessment module.

Description

The utility model belongs to the field of communication, in particular to special communication technology, namely, to data transmission systems by means of special purpose wireless communication.

A known neural network filter containing a receiving part and a transmitting part, and the receiving and transmitting parts of the neural network filter are connected by a feedback line (11.

The disadvantages of the well-known neural network filter, which was chosen as an analogue, include low efficiency under the simultaneous influence of intentional interference and signal fading, which does not provide the necessary speed of information transmission and interference protection.

The closest technical solution chosen as an analogue is a system with multiple inputs and multiple outputs (MIMO) containing a transmitting part, a receiving part, while the transmitting part contains a data source, an encoder, a low-frequency modulator, a buffer device, the first channel of the transmitting part , the second channel of the transmission part, while the first channel of the transmission part contains a high-frequency modulator of the first channel of the transmission part, a frequency synthesizer of the first channel of the transmission part, and the second channel of the transmission part contains a high-frequency modulator of the second channel of the transmission part, a frequency synthesizer of the second channel of the transmission part, and the output data sources are connected to the input of the encoder, the output of which is connected to the input of the low-frequency modulator, the output of the low-frequency modulator is connected to the input of the buffer device, the output of which is connected to the input of the first channel of the transmission part and the input of the second channel of the transmission part, outputs which are connected to the antenna and devices, the receiving part contains the first channel of the receiving part, the second channel of the receiving part, the buffer device of the receiving part, the quadrature converter of the receiving part, the decoder of the receiving part, the data receiver, the evaluation module of the state of the channel of the receiving part, while the first channel of the receiving part contains the demodulator of the first channel of the receiving part, the frequency synthesizer of the first channel of the receiving part, and the second channel of the receiving part contains the demodulator of the second channel of the receiving part, the frequency synthesizer of the second channel of the receiving part, and the output of the first channel of the receiving part and the output of the second channel of the receiving part are connected to the input of the buffer device of the receiving part , the output of which is connected to the quadrature converter of the receiving part, the output of which is connected to the input of the decoder of the receiving part and to the first input of the channel state estimation module of the receiving part, the output of which is connected to the second input of the decoder of the receiving part, in the output of which is connected to the input of the data receiver and the second input of the channel state evaluation module of the receiving part (21.

The disadvantages of the known system with multiple inputs and multiple outputs (MIMO) include low immunity and the inability to adapt to the signal and interference environment.

The basis of a useful model is the task of providing the possibility of self-learning, increasing immunity and the speed of information transmission, and as a result, increasing the stability of the operation of the military communication system .

The essence of a utility model in a self-learning multiple input multiple output (MIMO) system comprising a transmitting part 1, a receiving part 2, wherein the transmitting part includes a data source 7, an encoder 8, a low frequency modulator 9, a buffer device 10, the first channel of the transmission part 3, the second channel of the transmission part 4, while the first channel of the transmission part C contains the high-frequency (HF) modulator of the first channel of the transmission part 11, the frequency synthesizer of the first channel of the transmission part 13, and the second channel of the transmission part 4 contains the HF modulator of the second channel of the transmission part 14, the frequency synthesizer of the second channel of the transmission part 13, and the output of the data source 7 is connected to the input of the encoder 8, the output of which is connected to the input of the low-frequency modulator 9, the output of the low-frequency modulator 9 is connected to the input of the buffer device 10, the output of which is connected to the input of the first channel of the transmission part

With and input of the second channel of the transmitting part 4, the outputs of which are connected to antenna devices, the receiving part contains the first channel of the receiving part 5, the second channel of the receiving part 6, the buffer device of the receiving part 23, the quadrature converter of the receiving part 24, the decoder of the receiving part 25, data receiver 26, module for evaluating the state of the channel of the receiving part 27, while the first channel of the receiving part 5 contains a demodulator of the first channel of the receiving part 18, a frequency synthesizer of the first channel of the receiving part 19, and the second channel of the receiving part 6 contains a demodulator of the second channel of the receiving part 21, a synthesizer frequencies of the second channel of the receiving part 22, because the output of the first channel of the receiving part 5 and the output of the second channel of the receiving part 6 are connected to the input of the buffer device of the receiving part 23, the output of which is connected to the quadrature converter of the receiving part 24, the output of which is connected with the input of the decoder of the receiving part 25, and with the first input of the channel state evaluation module of the receiving part 27, the output of which is connected to the second input of the decoder of the receiving part 25, the output of which is connected to the input of the data receiver 26 and the second input of the channel state evaluation module of the receiving part 26, differs in that the system additionally includes a neural network filter of the first channel of the transmitting part 12, a neural network filter of the second channel of the transmitting part 15, a neural network filter of the first channel of the receiving part 17, a neural network filter of the second channel of the receiving part 20, and the neural network filter of the first channel of the transmitting part 12 is located in the first channel of the transmitting part C and connected to the output of the frequency synthesizer of the first channel of the transmitting part 13, the neural network filter of the second channel of the transmitting part 15 is located in the second channel of the transmitting part 4 and connected to the output of the frequency synthesizer of the second channel of the transmitting part 16, the neural network filter of the first channel receives part 17 is located in the first channel of the receiving part 5 and is connected to the output of the frequency synthesizer of the first channel of the receiving part 19, the neural network filter of the second channel of the receiving part 20 is located in the second channel of the receiving part b and is connected to the output of the frequency synthesizer of the second channel of the receiving part 22, while the inputs of the first channel of the receiving part and the second channel of the receiving part are connected to antenna devices.

The essence of the useful model is explained with the help of drawings, where in fig. 1 shows the functional scheme of the proposed system.

A system with multiple inputs and multiple outputs (MIMO) with the possibility of self-learning structurally contains (see Fig. 1) the transmitting part 1, the receiving part 2, the first channel of the transmitting part C, the second channel of the transmitting part 4, the first channel of the receiving part 5, the second channel of the receiving part b, data source 7, encoder 8, low-frequency (LF) modulator 9, buffer device 10, HF modulator of the first channel of the transmitting part 11, neural network filter of the first channel of the transmitting part 12, frequency synthesizer of the first channel of the transmitting part 13, HF modulator second channel

From the transmitting part 14, the neural network filter of the second channel of the transmitting part 15, the frequency synthesizer of the second channel of the transmitting part 16, the neural network filter of the first channel of the receiving part 17, the demodulator of the first channel of the receiving part 18, the frequency synthesizer of the first channel of the receiving part 19, the neural network filter of the second channel of the receiving part 20, a demodulator of the second channel of the receiving part 21, a frequency synthesizer of the second channel of the receiving part 22, a buffer device of the receiving part 23, a quadrature converter of the receiving part 24, a decoder of the receiving part 25, a data receiver 26 and a module for evaluating the state of the receiving part 27.

A self-learning Multiple Input Multiple Output (MIMO) system works as follows.

First, let's consider the design of the proposed system.

The transmitting part consists of: the data source 7 located in the transmitting part is connected in series with the encoder 8, which is connected in series with the low frequency modulator (LF) 9. The output of the LF modulator 9 is connected in series with the buffer device 10; the output of the buffer device 10 is divided into two parts, which is connected to the high-frequency (HF) modulator of the first channel of the transmission part 11 and to the HF modulator of the second channel of the transmission part 14.

Further, structurally, the transmitting part of the system with multiple inputs and multiple outputs (MIMO) with the possibility of self-learning is divided into two channels of the same type, which are identical in terms of functional purpose and constructive execution.

The first channel of the transmission part is composed as follows: the input of the HF modulator of the first channel of the transmission part 11, connected to the output of the frequency synthesizer of the first channel of the transmission part 13; the outputs of the frequency synthesizer of the first channel of the transmission part 13 and the RF modulator of the first channel of the transmission part 11 are connected to the input of the neural network filter of the first channel of the transmission part 12.

The second channel of the transmission part of the system with multiple inputs and multiple outputs (MIMO) with the possibility of self-learning consists as follows: the input of the HF modulator of the second channel of the transmission part 14, connected to the output 60 of the frequency synthesizer of the second channel of the transmission part 16;

the outputs of the frequency synthesizer of the second channel of the transmission part 16 and the RF modulator of the second channel of the transmission part 14 are connected to the input of the neural network filter of the second channel of the transmission part 15.

The receiving part of the system with multiple inputs and multiple outputs (MIMO) with the possibility of self-learning consists constructively of two channels.

The first channel of the receiving part of the system with multiple inputs and multiple outputs (MIMO) with the possibility of self-learning is constructed as follows: the output of the neural network filter of the first channel of the receiving part 17 is connected in series with the input of the demodulator of the first channel of the receiving part 18; the output of the frequency synthesizer of the first channel of the receiving part 19 is connected to the input of the demodulator of the first channel of the receiving part 18, and the second output of the frequency synthesizer of the first channel of the receiving part 19 is connected to the input of the neural network filter of the first channel of the receiving part 17.

The structure and functional purpose of the second channel of the receiving part are similar to the first channel of the receiving part. The structure of the second channel of the receiving part is as follows: the output of the neural network filter of the second channel of the receiving part 20 is connected in series with the input of the demodulator of the second channel of the receiving part 21; the output of the frequency synthesizer of the second channel of the receiving part 22 is connected to the input of the demodulator of the second channel of the receiving part 21, and the second output of the frequency synthesizer of the second channel of the receiving part 22 is connected to the input of the neural network filter of the second channel of the receiving part 20.

The outputs of the demodulator of the first channel of the receiving part 18 and the demodulator of the second channel of the receiving part 21 enter the input of the buffer device of the receiving part 23; the output of the buffer device of the receiving part 23 is connected in series with the input of the quadrature converter of the receiving part 24.

The first output of the quadrature converter of the receiving part 24 is connected to the input of the decoder of the receiving part 25, and the second output is connected to the input of the channel state evaluation module of the receiving part 27. The outputs of the quadrature converter of the receiving part 24 and receiver part decoder 25; the output of the channel status evaluation module of the receiving part 27 is connected to the input of the decoder of the receiving part 25.

The first output of the decoder of the receiving part 25 is connected to the channel state evaluation module of the receiving part 27, and the second output to the data receiver 26.

A self-learning Multiple Input Multiple Output (MIMO) system works like this.

To transmit information from the transmission part 1, the data source 7 is sent to the encoder 8, where the sequence of the message's output symbols (Ци) is converted into a sequence of symbols M (), which determine the law of formation of the primary low-frequency oscillations 5(I) by the LF modulator 9 for further processing.

Next, the signal from the output of the LF modulator 9 enters the input of the buffer device 10. The function of the buffer device is that it accumulates information that comes from the modulator

NU 9 and when the amount of information becomes sufficient for transmission - transmits information to the input of the HF modulator of the first channel of the transmission part 11 and to the input of the HF modulator of the second channel of the transmission part 14 for further processing. From the output of the buffer device 10, transmission 3 and to the second channel of transmission part 4. The first channel of transmission part C and the second channel of transmission part 4 have the same functional purpose and the same design.

The input of the HF modulator of the first channel of the transmission part 11 receives an information sequence from the output of the frequency synthesizer of the first channel of the transmission part 13, which performs the function of forming a grid of highly stable reference frequencies.

From the output of the frequency synthesizer of the first channel of the transmission part 13, information sequences are sent to the input of the neural network filter of the first channel of the transmission part 12, which performs the function of forming the initial (training) sequence, on the basis of which the error in the evaluation of the received signal will be determined and measures to correct the channel parameters will be determined.

The input of the neural network filter of the first channel of the transmission part 12 receives the information sequence formed in the HF modulator of the first channel of the transmission part 11 and the information sequence from the frequency synthesizer of the first channel of the transmission part 13. Because the second channel of the transmission part 4 works as follows:

The input of the HF modulator of the second channel of the transmission part 14 receives an information sequence from the output of the frequency synthesizer of the second channel of the transmission part 16, which performs the function of forming a grid of highly stable reference frequencies.

From the output of the frequency synthesizer of the second channel of the transmission part 16, information sequences are sent to the input of the neural network filter of the second channel of the transmission part 15, which performs the function of forming the initial (training) sequence, on the basis of which the error in the evaluation of the received signal will be determined and measures to correct the channel parameters will be determined.

The input of the neural network filter of the second channel of the transmission part 15 receives the information sequence formed in the HF modulator of the second channel of the transmission part 14, and the information sequence from the frequency synthesizer of the second channel of the transmission part 16.

The information sequence 3 of the output of the neural network filter of the first channel of the transmission part 12 and the neural network filter of the second channel of the transmission part 15 are sent to the antenna device. Antenna devices emit an information sequence through a radio channel to the receiving side of the system.

The signal transmitted by the transmitting part of the system arrives at the antenna devices of the receiving part of the system, namely the antenna device of the first channel of the receiving part 5 and the antenna device of the second channel 6.

On the receiving side of the system, a sequence (series) of reverse transformations of the information sequence, which were carried out on the transmitting side of the system, is carried out.

The first channel of the receiving part 5 and the second channel of the receiving part b are designed identically and functionally have the same purpose.

The received information sequence from the outputs of the antenna devices is sent to the neural network filter of the first channel of the receiving part 17 and the neural network filter of the second channel of the receiving part 20, where the operation of analyzing the distortions formed during transmission over the communication channel and determining the correction algorithm is carried out.

In the demodulator of the first channel of the receiving part 18 and the demodulator of the second channel of the receiving part 21 when the information and service sequence arrives from the output

From the frequency synthesizer of the first channel of the receiving part 19 and the frequency synthesizer of the second channel of the receiving part 22, a useful information sequence is extracted by correlating the received signal with a sample of the signal, which is set as a standard for reception (detection). The frequency synthesizers of the receiving part 19 and 22 are identical in their structure and functional purpose to the synthesizers of the transmitting part 13 and 16 and on the receiving side perform the function of extracting a useful sequence from the entire sequence received at the receiving part of the system.

From the output of the demodulator of the first channel of the receiving part 18 and the demodulator of the second channel of the receiving part 21, the signal enters the input of the buffer device of the receiving part 23, which performs the function of accumulating up to a certain level of information coming from the output of the demodulator of the first channel of the receiving part 18 and the demodulator of the second channel of the receiving part 21 .

After accumulating a certain amount of information necessary for operation, the buffer device of the receiving part 23 transmits the accumulated information to the quadrature converter of the receiving part 24, which is a universal device used regardless of the type of modulation, but with additional conversion of the demodulating oscillation.

The quadrature converter of the receiving part is a balanced type device that does not require filtering to select the additive or subtractive component of the signal. From the output of the quadrature converter of the receiving part 24, the signal enters the input of the decoder of the receiving part 25, which performs the function of decoding the information sequence. The channel status evaluation module of the receiving part 27 is designed to analyze the channel status (the ratio of the number of FALSELY received bits/the number of correctly received bits). Information to the channel state evaluation module of the receiving part 27 comes from the quadrature converter of the receiving part 24 and the decoder of the receiving part 25. The channel state evaluation module of the receiving part 27 analyzes the information coming from the quadrature converter of the receiving part 24 and the decoder of the receiving part 25 and depending on which of the devices detected an excess of the ratio of the number of erroneously received bits/the number of correctly received bits and a request is made to retransmit the information sequence that was received with distortion. From the output of the decoder of the receiving part 25, information is sent to the data receiver 26.

Increasing the efficiency of using a system with multiple inputs and multiple outputs (MIMO) with the possibility of self-learning, which is claimed, compared to the prototype, is achieved due to the additional introduction of neural network filters, which will provide the possibility of self-learning, increase immunity and speed of information transmission, and as a result to increase the stability of the functioning of the military communication system.

Sources of information: 1. Russell, Stuart, Norvig, Peter. Artificial intelligence: a contemporary approach, 2nd ed.:

Trans. with English Moscow: "Williams" Publishing House, 2006. 1408 p.: ill. - analogue 2. MIMO - technologies: practical application. - |(electronic resource|.- Access mode: per//ps.Kiem.pa/apisivie.rpit!?1I0-22022 - prototype.

Claims (1)

10 UTILITY MODEL FORMULA A self-learning multiple-input-multiple-output (MIMO) system comprising a transmitting part, a receiving part, wherein the transmitting part includes a data source, an encoder, a low frequency modulator, a buffer device, a first channel 15 of the transmitting part, the second channel of the transmission part, while the first channel of the transmission part contains a high-frequency (HF) modulator of the first channel of the transmission part, a frequency synthesizer of the first channel of the transmission part, and the second channel of the transmission part contains a HF modulator of the second channel of the transmission part, a frequency synthesizer of the second channel of the transmission part, and the output of the data source 20 is connected to the input of the encoder, the output of which is connected to the input of the low-frequency modulator, the output of the low-frequency modulator is connected to the input of the buffer device, the output of which is connected to the input of the first channel of the transmission part and the input of the second channel of the transmission part, the outputs of which are connected to antenna devices, the receiving part contains the first channel of the receiving part, the second channel of the receiving part, the buffer device 25 of the receiving part, the quadrature converter of the receiving part, the decoder of the receiving part, the data receiver, the evaluation module of the state of the channel of the receiving part, while the first channel of the receiving part contains the demodulator of the first of the channel of the receiving part, the frequency synthesizer of the first channel of the receiving part, and the second channel of the receiving part contains a demodulator of the second channel of the receiving part, a frequency synthesizer of the second channel Zo of the receiving part, and the output of the first channel of the receiving part and the output of the second channel of the receiving part are connected to the input of the buffer device of the receiving part, the output of which is connected to the quadrature converter of the receiving part, the output of which is connected to the input of the decoder of the receiving part and to the first input of the channel state estimation module of the receiving part, the output of which is connected to the second input of the receiver decoder part, whose output 35 is connected to the input of the data receiver and the second input of the channel state evaluation module of the receiving part, which is characterized by the fact that the system additionally contains a neural network filter of the first channel of the transmitting part, a neural network filter of the second channel of the transmitting part, a neural network filter of the first channel of the receiving part parts, the neural network filter of the second channel of the receiving part, and the neural network filter 40 of the first channel of the transmitting part is located in the first channel of the transmitting part and is connected to the output of the frequency synthesizer of the first channel of the transmitting part, the neural network filter of the second channel of the transmitting part is located in the second channel of the transmitting part and with connected to the output of the frequency synthesizer of the second channel of the transmitting part, the neural network filter of the first channel of the receiving part 45 is located in the first channel of the receiving part and is connected to the output of the frequency synthesizer of the first channel of the receiving part, the neural the control filter of the second channel of the receiving part is placed in the second channel of the receiving part and is connected to the output of the frequency synthesizer of the second channel of the receiving part, while the inputs of the first channel of the receiving part and the second channel of the receiving part are connected to antenna devices.