UA134177U - MULTIPLE AND OUTPUT (MIMO) SYSTEM - Google Patents

Abstract

The multiple-input and multiple-output system (містить) comprises a transmission part, a receiving portion, the transmitting portion comprising a data source, an encoder, a low-frequency modulator, a buffer device, a first channel of the transmitting portion, a second channel of the transmitting portion, the first channel of the transmitting portion contains a high-frequency (HF) modulator of the first channel of the transmitting portion, a frequency synthesizer of the first channel of the transmitting portion, and a second channel of the transmitting portion contains a modulator of RF of the second channel of the transmitting part Copyrights parts, frequency synthesizer of the second channel of transmission.

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 block for adapting to a signal-disturbing situation, containing a control unit, an evaluation unit, an optimization unit and a main circuit regulator, and the evaluation unit is connected in series with the input of the optimization unit, the output of the optimization unit is connected in series with the input of the main circuit regulator, the output the regulator of the main circuit is connected in series with the input of the control unit (11.

Among the disadvantages of the block of adaptation to the signal-interference situation, which was chosen as an analogue, is the low speed of adaptation when working in a complex signal-interference situation.

The closest technical solution 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, a first channel of a transmitting part, a second channel of a transmitting 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 of the data source 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 transmitting part and the input of the second channel of the transmitting part, the outputs of which are connected to antenna devices , reception and the 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 a demodulator of the second channel of the receiving part, a 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

From which the quadrature of the receiving part is connected to the converter, 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, the output of which is connected to the input of the data recipient, and the second input of the channel status evaluation module of the receiving part (21.

Among the disadvantages of the known system with multiple inputs and multiple outputs (MIMO) is low fault tolerance.

The useful model is based on the task of increasing the energy efficiency, providing the possibility of adaptation to the signal-jamming situation and, as a result, increasing the stability of the operation of the military communication system "link"

The essence of the utility model in a system with multiple inputs and multiple outputs (MIMO) comprising a transmission part 1, a reception part 2, and the transmission part includes a data source 7, an encoder 8, a low frequency modulator 9, a buffer device 10, a first channel of the transmission part C, 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 RF 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 connected to the input of the first channel of the transmission part C and the input of the second channel of the transmission part 4, the outputs of which connected to the 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, the data receiver 26, the evaluation module of the state of the channel of the receiving part 27, thus, the first channel of the receiving part 5 contains the demodulator of the first channel of the receiving part 18, the frequency synthesizer of the first channel of the receiving part 19, and the second channel of the receiving part 6 contains the demodulator of the second channel of the receiving part 21, because the frequency synthesizer of the second channel of the receiving part 22, and the output of the first channel of the receiving part part 5 and the output of the second channel of the receiving part b 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 to the input of the decoder of the receiving part 25, and to the first input of the channel state evaluation module reception area 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 module for evaluating the state of the channel of the receiving part 26, differs in that the system additionally includes a unit for adapting to the signal-jamming situation of the first channel of the transmitting part 12, the adaptation block to the signal and jamming situation of the second channel of the transmitting part 15, the adaptation block to the signal and jamming situation of the first channel of the receiving part 17, the adaptation block to the signal and jamming situation of the second channel of the receiving part 20, and the adaptation block to the signal - the interference situation of the first channel of the transmission part 12 is located in the first channel of the transmission part C and is connected to the output of the frequency synthesizer of the first channel of the transmission part 13, the adaptation block to the signal-interference situation of the second channel of the transmission part 15 is located in the second channel of the transmission part 4 and with united with the output son of the frequency synthesizer of the second channel of the transmitting part 16, the adaptation block to the signal-interference situation of the first channel of the receiving 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 adaptation block to the signal-interference situation of the second channel of the receiving part 20 is placed in the second channel of the receiving part 6 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 a drawing, where the functional scheme of the proposed system is presented.

The system with multiple inputs and multiple outputs (MIMO) structurally contains (see drawing) the transmitting part 1, the receiving part 2, the first channel of the transmitting part 3, the second channel of the transmitting part 4, the first channel of the receiving part 5, the second channel of the receiving part b, the source data 7, encoder 8, low frequency modulator (LF) 9,

Zo buffer device 10, HF modulator of the first channel of the transmission part 11, adaptation unit to the signal-interference situation of the first channel of the transmission part 12, frequency synthesizer of the first channel of the transmission part 13, HF modulator of the second channel of the transmission part 14, adaptation block to the signal-interference situation of the second of the channel of the transmitting part 15, the frequency synthesizer of the second channel of the transmitting part 16, the adaptation unit to the signal-interference situation 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 adaptation unit to the signal-interference situation of the second channel of the receiving part 20, the demodulator of the second channel of the receiving part 21, the frequency synthesizer of the second channel of the receiving part 22, the buffer device of the receiving part 23, the quadrature converter of the receiving part 24, the decoder of the receiving part 25, the data receiver 26 and the module of evaluating the state of the receiving part of part 27.

A multiple input multiple output (MIMO) system works as follows.

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

The transmission part consists of: - the data source 7, which is located in the transmission 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 are 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 transmission part of the system with multiple inputs and multiple outputs (MIMO) is divided into two channels of the same type, which are identical in terms of functional purpose and structural execution.

The first channel of the transmission part consists 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 HF modulator of the first channel of the transmission part 11 are connected to the input of the adaptation block to the signal-jamming situation 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) is composed as follows: - the input of the HF modulator of the second channel of the transmission part 14, connected to the output 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 adaptation block to the signal-jamming situation of the second channel of the transmission part 15.

The receiving part of the system with multiple inputs and multiple outputs (MIMO) consists structurally of two channels.

The first channel of the receiving part of the system with multiple inputs and multiple outputs (MIMO) is structurally designed as follows: - the output of the adaptation block to the signal-jamming situation 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 input of the demodulator of the first channel of the receiving part 18 is connected to the output of the frequency synthesizer of the first channel of the receiving part 19, and the second output of the frequency synthesizer of the first channel of the receiving part 19 is connected to the input of the adaptation block to the signal-jamming situation 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 adaptation unit to the signal-jamming situation 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 input of the demodulator of the second channel of the receiving part 21 is connected to the output of the frequency synthesizer of the second channel of the receiving part 22, and the second output of the frequency synthesizer of the second channel of the receiving part 22 is connected to the input of the adaptation block to the signal-jamming situation 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

From 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 multiple-input-multiple-output (MIMO) system works like this.

For the transmission of information from the transmission part 1, the data source 7 is sent to the encoder 8, where the sequence of output symbols of the message Ц(Y) is transformed into a sequence of symbols М (), 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, the transmission part is logically and constructively divided into the first channel of the transmission part C and the second channel of the transmission part 4. The first channel of the transmission part C and the second channel of the 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 adaptation block to the signal-interference situation of the first channel of the transmission part 12, which performs the function of selecting the algorithm for equalizing (correcting) the characteristics of the channel depending on the signal and interference conditions.

The information sequence formed in the RF 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 are received at the input of the adaptation block to the signal-jamming situation of the first channel of the transmission part 12.

The second channel of 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 adaptation block to the signal-interference situation of the second channel of the transmission part 15, which performs the function of selecting the algorithm for equalizing (correcting) the characteristics of the channel depending on the signal and interference situation.

The information sequence formed in the RF 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 are received at the input of the adaptation block to the signal-jamming situation of the second channel of the transmission part 15.

The information sequence from the output of the adaptation block to the signal-interference situation of the first channel of the transmission part 12 and the adaptation block to the signal-interference situation of the second channel of the transmission part 15 are received by 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 6 are designed in the same way and functionally have the same purpose.

The received information sequence from the outputs of the antenna devices is sent to the block

From the adaptation to the signal-jamming situation of the first channel of the receiving part 17 and the block of adaptation to the signal-jamming situation 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 an information and service sequence is received from the output of 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 selected by correlating the received signal with a signal sample, 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 an 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 an additional 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 state evaluation module of the receiving part 27 is designed to analyze the channel state (the ratio of the number of erroneously 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 in which of the devices, an excess of the ratio of the number of erroneously received bits/the number of correctly received bits is detected 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 effectiveness of the application of the system with multiple inputs and multiple outputs (MIMO), which is claimed, in comparison with the prototype, is achieved due to the additional introduction of blocks of adaptation to the signal-jamming situation, which provides increased energy efficiency, the ability to adapt to the signal-jamming situation and how the result provides an increase in the stability of the functioning of the military communication system.

SOURCES OF INFORMATION: 1. Ermolaeev V.T., Flaxman A.G. Adaptive spatial processing of signals in wireless communication systems / Educational and methodological material. - Nizhny Novgorod, 2006 - analogue. 2. MIMO - technologies: practical application.- (electronic resource|- Access mode: per//ps.Kiem.pa/apisive.rpit!?1I0-22022 - prototype.

Claims (1)

USEFUL MODEL FORMULA A 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 of the transmitting part, a second channel of the transmitting part, wherein the first channel the transmission part contains 25 high frequency (HF) modulator of the first channel of the transmission part, the frequency synthesizer of the first channel of the transmission part, and the second channel of the transmission part contains the HF modulator of the second channel of the transmission part, the frequency synthesizer of the second channel of the transmission part, and the output of the data source 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 with antenna devices, the receiving part contains the first the 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 state evaluation module 35 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 a demodulator of the second channel of the receiving part, a 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 40 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, the output of which is connected to the input of the receiver them and the second input of the channel state evaluation module of the receiving part, which is characterized by the fact that 45 the system additionally contains a block for adapting to the signal-jamming situation of the first channel of the transmitting part, a block for adapting to the signal-jamming situation of the second channel of the transmitting part, a block for adapting to the signal-jamming situation the situation of the first channel of the receiving part, the adaptation unit to the signal-jamming situation of the second channel of the receiving part, and the adaptation unit to the signal-jamming situation of the first 50 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 adaptation block to the signal-jamming situation of the second channel of the transmitting part is located in the second channel of the transmitting part and is connected to the output of the frequency synthesizer of the second channel of the transmitting part, the adaptation block to the signal-jamming situation of the first 55 channel of the receiving part located in the first channel of the receiving part and connected to the output of the frequency synthesizer of the first channel of the receiving part, the adaptation block to the signal-interference situation of the second channel of the receiving part is located in the second channel of the receiving part and connected to the output of the frequency synthesizer of the second channel of the receiving part, when thus, the inputs of the first channel of the receiving part and the second channel of the receiving part are connected to antenna devices. : и Zirohokktum yuki kiya putu y : Ko elyanyatikhnmtnyi, Kedatsyumya skh I vrodu veeero mut rmy fen | fzhnnnnnnnnnnnnnnnnnneyannnnineyu OO TE pt OO KO TI nn no MO a S nn V nn kn WRITE i VA za ny za: PI z SP o on Bon Kukhta Mnshnnya i nych -k I : ko y : TE a : kny : ry i she E ee we SHIN NYA still OVO Oz and Tori : : RO Ben ku in ; From two hundred kilometers: ; рн-еЯ НИ У : : Not YET : ! No : ; weight: N and Mn: ; I STILL eat her and : : ri her in ke : : E : . her: : х щ- I H 1 3 : : KOM oechdtnyanny Kei still t: NE E : nn yn A topa turu Yan y ! : volume of them M BE and "i 17 ШЭ жи : : E и ку Би : ; maybe OK : :