RU95440U1 - PORTABLE SUBSCRIBER MOBILE STATION OF RADIO ACCESS EQUIPMENT - Google Patents

Abstract

 1. A portable subscriber mobile station of radio access equipment, comprising a control unit, the control output of which is connected by a bi-directional control bus to the control input-output of a data reception and transmission channel, the input and output of the control unit being an interface of high-speed data transmission networks, a transmission and reception channel the data contains a series-connected encoder, modulator, transmitter and antenna switch, the output-input of which through the first antenna matching device is connected to the receiver transmitting antenna, as well as a series-connected receiver, demodulator and decoder, the output of which is the information output of the data reception and transmission channel and connected to the information input of the control unit, the information output of which is the information input of the data reception and transmission channel and the first input of the encoder, as well as the receiving an antenna that is connected to the third input of the receiver through the second ACS, a frame detection unit, a CINR (Carrier to interference plus noise ratio) estimator, an RSSI (Receive Strength Signal Indicator) and a block of the time-frequency estimation of the received signal, made by two-channel, the first inputs of which are combined and connected to the first output of the receiver, and the second inputs are combined and connected to its second output, in addition, the output of the frequency synthesizer is connected to the second inputs of the transmitter and the receiver, and its input with the control input-output of the data reception and transmission channel and with the control inputs of the encoder, modulator, transmitter, two-channel receiver, two-channel demodulator, decoder, antenna switch

Description

The utility model relates to radio engineering and can be used to organize high-speed radio networks for transmitting information and packet duplex radio communications, exchanging digital information in accordance with the IEEE 802.16e standard (http://standards.ieee.org/getieee802), where as a source of digital information One of the following high-speed data transfer interfaces can be used:

- PCMCIA - (Peripheral Component Microchannel Interconnect Architecture http://www.pcmcia.org/);

- PCIe - (PCI Express or PCI-E, also known as 3GIO for 3rd Generation I / O http): //www.pcisig.com/specifications/pciexpress/);

- USB - (Universal Serial Bus http://www.usb.org/developers/docs/);

- CF - (CompactFlash http://www.compactflash.org/);

- Ethernet - (IEEE 802.3 and IEEE 802.3u LAN standard http://standards.ieee.org/getieee802/download/802.3-2002.pdf).

A large number of wearable and transportable radio stations are known, for example, radio stations according to patents for utility models No. 72590, 87852, 87853, etc., performing similar functions.

The disadvantages of these radio stations are:

- the presence of a single source of digital information, which significantly limits the scope of the device;

- the absence of an energy-saving mode, depending on the operating mode of the subscriber mobile station of radio access equipment, which significantly reduces the continuous operation time and service life of autonomous power sources.

The closest in technical essence to the proposed portable subscriber mobile station of radio access equipment is a high-speed subscriber mobile radio station of radio access equipment according to the patent for utility model No. 87853, adopted as a prototype.

Figure 1 shows a diagram of a device of the prototype, figure 2 is a diagram of the encoder of a device of a prototype, figure 3 is a diagram of a decoder of a device of a prototype, figure 4 is a diagram of a modulator of a device of a prototype, figure 5 is a diagram of a demodulator prototype device, Fig.6 is a structural diagram of the proposed device, Fig.7 is a diagram of the encoder of the proposed device, Fig.8 is a diagram of the decoder of the proposed device; figure 9 is a diagram of a modulator of the proposed device; figure 10 - diagram of the demodulator of the proposed device; figure 11 is a transmitter diagram of the proposed device; on Fig - receiver circuit of the proposed device,

Figure 1 shows a generalized structural diagram of a prototype radio station, where it is indicated:

1 - control unit;

1 - channel for receiving and transmitting data;

2 - frequency synthesizer;

3 - encoder;

4 - transmitter;

5 - receiver;

6 - antenna switch;

7.1 - transceiver antenna;

7.2 - receiving antenna;

8.1, 8.2 - the first and second antenna matching devices (ACS);

9 - decoder;

10 - modulator;

11 - demodulator;

12 - block detecting frames;

13 - CINR estimation forming unit (Carrier to interference plus noise ratio);

14 - block forming the RSSI score (Receive Strength Signal Indicator - indicator of the level of the received signal);

15 is a block of the time-frequency evaluation of the received signal.

The prototype device comprises a control unit 1, the control output-input of which is connected by a bi-directional control bus to the control input-output of the data reception and transmission channel I, the input-output of the control unit 1 being the interface of high-speed Ethernet information networks.

The data transmission and reception channel I contains a series-connected encoder 3, a modulator 10, a transmitter 4, and an antenna switch 6, the output-input of which through the first ACS 8.1 is connected to a transceiver antenna 7.1, a two-channel receiver 5, a two-channel demodulator 11, and a decoder 9 are connected in series, the output which is the information output of the data reception and transmission channel I and connected to the information input of the control unit 1, the information output of which is the information input of the data reception and transmission channel I and the first input encoder house 3, as well as a receiving antenna 7.2, which is connected to the third input of the receiver 5 through the second ACS 8.2, a frame detection unit 12, a CINR 13 estimation generating unit, an RSSI estimation generating unit 14, and a time-frequency estimation unit of the received signal 15 made by two-channel the first inputs of which are combined and connected to the first output of the receiver 5, and the second inputs are combined and connected to its second output. In addition, the output of the frequency synthesizer 2 is connected to the second inputs of the transmitter 4 and receiver 5, and its input is connected to the control input-output of the data reception and transmission channel I and with the control inputs of the encoder 3, modulator 10, transmitter 4, receiver 5, demodulator 11 , a decoder 9, an antenna switch 6, a frame detection unit 12, a CINR rating generating unit 13, an RSSI rating generating unit 14 and a frequency-time evaluation unit for the received signal 15. The outputs of automatic gain control (AGC1 and AGC2) and automatic frequency adjustment s (AFC1 and AFC2) of the first and second channels of the demodulator 11 are connected to the corresponding inputs of the AGC and AFC of the first and second channels of the receiver 5, the output of the antenna switch 6 is connected to the first input of the receiver 5. In addition, the output of the frame detection unit 12 is the first output of the reception channel - data transmission I, the output of the CINR 13 estimation generating unit - its second output, the RSSI 14 evaluation generating unit output - the third, the output of the time-frequency estimation unit of the received signal 15 - the fourth, and the outputs from the first to the fourth receiving channel data transmissions I are connected to the corresponding inputs of control unit 1.

The structural diagram of the encoder of the device of the prototype 3 is shown in figure 2, where it is indicated:

3.1 - Reed / Solomon block encoder; 3.2 - convolutional encoder; 3.3 - interleaver; 3.4 - turbo encoder.

The encoder 3 contains series-connected block Reed / Solomon encoder 3.1, a convolutional encoder 3.2, an interleaver 3.3, the output of which is the output of encoder 3. The first input of the Reed / Solomon 3.1 encoder is the first input of encoder 3, the control input of which is connected to the control inputs of blocks 3.1, 3.2, 3.3, 3.4. The first input of the turbo encoder 3.4 is connected to the first input of the Reed / Solomon 3.1 block encoder, and the output is connected to the interleaver 3.3 input.

The structural diagram of the decoder of the device of the prototype 9 is shown in figure 3, where indicated:

9.1 - reverse interleaver; 9.2 - Viterbi decoder; 9.3 - Reed / Solomon block decoder; 9.4 - turbo decoder.

The decoder 9 contains a series-connected reverse interleaver 9.1, a Viterbi decoder 9.2 and a Reed / Solomon 9.3 block decoder, the output of which is the output of the decoder 9. The first input of the interleaver 9.1 is the first input of the decoder 9, and its control input is connected to the control inputs of blocks 9.1, 9.2, 9.3, 9.4. The first input of the turbo decoder 9.4

connected to the output of the reverse interleaver 9.1, and its output is connected to the output of the Reed / Solomon 9.3 block decoder.

The structural diagram of the modulator of the device of the prototype 10 is shown in figure 4, where indicated:

10.1 - block forming characters BPSK, QPSK, 16QAM, 64QAM from the input data stream; 10.2 - block substitution of the pilot signal and protective characters; 10.3 - block inverse fast complex Fourier transform; 10.4 - block interpolator and digital low-pass filter; 10.5 - digital-to-analog converter (DAC).

The modulator 10 contains a series-connected block of character formation BPSK, QPSK, 16QAM, 64QAM from the input data stream 10.1, a substitution block for the pilot signal and protective sub-characters 10.2, an inverse fast complex Fourier transform 10.3, an interpolator and a digital low-pass filter 10.4, and a DAC 10.5 whose output is the output of the modulator. The first input of the character generation unit BPSK, QPSK, 16QAM, 64QAM from the input data stream 10.1 is the first input of the modulator 10, the control input of the modulator 10 is connected to the control inputs of the blocks 10.1,10.2,10.3, 10.4, 10.5.

The structural diagram of the demodulator of the device of the prototype 11 is presented in figure 5, where it is indicated:

11.1 - analog-to-digital Converter (ADC); 11.2 - block digital low-pass filter and thinning device; 11.3 - block fast complex Fourier transform; 11.4 - block allocation of the pilot signal and protective sub-characters; 11.5 - block weighted summation and formation of a stream of data bits; 11.6 - controller for automatically adjusting the gain of the receiver; 11.7 - automatic frequency control controller; 11.8 - equalizer.

The demodulator 11 is made two-channel, and the second channel is identical to the first, while all the functional nodes of the demodulator 11 and their connections are two-channel. The demodulator 11 contains a series-connected ADC 11.1, a digital low-pass filter unit and a decimation device 11.2, a fast complex Fourier transform unit 11.3, a pilot signal and protective sub-symbols 11.4, and a weighted summing and generating block of data bits 11.5, the output of which is the output of the demodulator 11 The first and second inputs of the ADC 11.1 are the corresponding inputs of the demodulator 11 and, respectively, the inputs of the first and second channels. The control input of the demodulator 11 is connected to the control inputs of blocks 11.1, 11.2, 11.3, 11.4, 11.5, 11.6, 11.7, 11.8. In addition, the output of the ADC 11.1 is connected to the first input of the controller for automatically adjusting the gain of the receiver 11.6, the first output of which is the AGC output of the first channel, and the second output is the AGC output of the second channel. The output of the digital low-pass filter block and decimation device 11.2 is connected to the first input of the AFC controller 11.7, the first output of which is the AFC output of the first channel, and the second output is the AFC output of the second channel. The output of the fast complex Fourier transform block 11.3 is connected to the first input of the equalizer 11.8 and the second inputs of the blocks 11.5 and 11.7. In this case, the output of the equalizer 11.8 is connected to the third input of the weighted summation block and the formation of the data bit stream 11.5.

The disadvantages of the prototype device are:

- the ability to work with only one type of high-speed data interface, which significantly limits the scope of the device;

- the absence of an energy-saving mode, depending on the operating mode of a high-speed subscriber mobile station of radio access equipment, which significantly reduces the continuous operation time and service life of autonomous power sources.

The objective of the proposed device is to expand the functionality of a portable subscriber mobile station by implementing energy saving procedures depending on the operating mode of the subscriber mobile station radio access equipment, as well as realizing the station's ability to work with one of the following high-speed data transfer interfaces:

- PCMCIA - {Peripheral Component Microchannel Interconnect Architecture http://www.pcmcia. ors /};

- PCIe - (PCI Express or PCI-E, also known as 3GIO for 3rd Generation I / O http://www.pcisig.com/specifications/pciexpress/);

- USB - (Universal Serial Bus http://www.usb.org/developers/docs/) '

- CF - (CompactFlash http://www.compactflash.org/);

- Ethernet - (IEEE 802.3 and IEEE 802.3u LAN standard http://standards.ieee.org/getieee802/download/802.3-2002.pdf).

To solve the problem in a portable subscriber mobile station of radio access equipment, containing a control unit, the control output of which is connected by a bi-directional control bus to the control input-output of the data reception and transmission channel, the input and output of the control unit being the interface of high-speed data transmission networks, channel The data transmit-receive contains a serial encoder, modulator, transmitter and antenna switch, the output-input of which is through the first antenna matching The device is connected to a transceiver antenna, as well as a receiver, demodulator and decoder connected in series, the output of which is the information output of the data reception and transmission channel and connected to the information input of the control unit, the information output of which is the information input of the data reception and transmission channel and the first input of the encoder as well as a receiving antenna, which is connected through the second ACS to the third input of the receiver, a frame detection unit, a CINR (Carrier to interference plus noise ratio) evaluation unit, RSSI (Receive Strength Signal Indicator) estimation block and the time-frequency block of the received signal made by two channels, the first inputs of which are combined and connected to the first output of the receiver, and the second inputs are combined and connected to its second output, in addition, the output of the frequency synthesizer connected to the second inputs of the transmitter and receiver, and its input - with the control input-output of the data reception and transmission channel and with the control inputs of the encoder, modulator, transmitter, two-channel receiver, two-channel demodulator , a decoder, an antenna switch, a frame detection unit, a CINR rating generating unit, an RSSI rating generating unit and a time-frequency estimation unit of the received signal, while the outputs of automatic gain control (AGC1 and AGC2) and automatic frequency control (AFC1 and AFC2) of the first and the second channels of the demodulator are connected to the corresponding inputs of the AGC and AFC of the first and second channels of the receiver, the first input of which is connected to the output of the antenna switch; in addition, the output of the frame detection unit is the first m is the output of the data reception and transmission channel, the output of the CINR estimation generating unit is its second output, the output of the RSSI estimation generating unit is the third, the output of the time-frequency estimation unit of the received signal is fourth, and the outputs from the first to fourth data receiving and transmitting channels are connected to according to the utility model, an energy-control signal generating unit has been introduced into the data reception and transmission channel, the first input of which is connected to the output of the decoder, and the second input is connected to the output m of a frame detection unit, the output of the power control signal generating unit being connected to the control bus, while the corresponding blocks for partially or completely turning off the power and changing the clock frequency of the functional units, the input of each of which are introduced into the encoder, decoder, modulator, demodulator, receiver and transmitter connected to the control input of the corresponding unit.

The structural diagram of the proposed portable subscriber mobile station radio access equipment is shown in Fig.6, where it is indicated:

1 - control unit;

I - channel data reception;

2 - frequency synthesizer;

3 - encoder;

4 - transmitter;

5 - receiver;

6 - antenna switch;

7.1 - transceiver antenna;

7.2 - receiving antenna;

8.1, 8.2 - the first and second antenna matching devices (ACS);

9 - decoder;

10 - modulator;

11 - demodulator;

12 - block detecting frames;

13 - CINR estimation forming unit (Carrier to interference plus noise ratio);

14 - block forming the RSSI score (Receive Strength Signal Indicator-indicator of the level of the received signal);

15 is a block of the time-frequency evaluation of the received signal;

16 is a block generating energy control signals. The proposed device contains a control unit 1, the control output-input of which is connected by a bi-directional control bus to the control input-output of the data reception and transmission channel I, and the input-output of the control unit 1 is one of the following interfaces for high-speed data transmission:

- PCMCIA - (Peripheral Component Microchannel Interconnect Architecture http://www.pcmcia.org/);

- PCIe - (PCI Express or PCI-E, also known as 3GIO for 3rd Generation I / O http://www.pcisig.com/specifications/pciexpress/);

- USB - (Universal Serial Bus http.:/vww.usb.org/developers/docs/);

- CF - (CompactFlash http://www.compactflash.org/);

- Ethernet - (IEEE 802.3 and IEEE 802.3u LAN standard http://standards.ieee.org/getieee802/download/802.3-2002.pdf).

The data transmission and reception channel I contains a series-connected encoder 3, a modulator 10, a transmitter 4, and an antenna switch 6, the output-input of which through the first ACS 8.1 is connected to a transceiver antenna 7.1, a two-channel receiver 5, a two-channel demodulator 11, and a decoder 9 are connected in series, the output which is the information output of the data reception and transmission channel I and connected to the information input of the control unit 1, the information output of which is the information input of the data reception and transmission channel I and the first input encoder house 3, as well as a receiving antenna 7.2, which is connected to the third input of the receiver 5 through the second ACS 8.2, a frame detection unit 12, a CINR 13 estimation generating unit, an RSSI estimation generating unit 14, and a time-frequency estimation unit of the received signal 15 made by two-channel the first inputs of which are combined and connected to the first output of the receiver 5, and the second inputs are combined and connected to its second output. In addition, the output of the frequency synthesizer 2 is connected to the second inputs of the transmitter 4 and receiver 5, and its input is connected to the control input-output of the data reception and transmission channel I and with the control inputs of the encoder 3, modulator 10, transmitter 4, receiver 5, demodulator 11 , a decoder 9, an antenna switch 6, a frame detection unit 12, a CINR rating generating unit 13, an RSSI rating generating unit 14 and a frequency-time evaluation unit for the received signal 15. The outputs of automatic gain control (AGC1 and AGC2) and automatic frequency adjustment (AFC1 and AFC2) of the first and second channels of the demodulator 11 are connected to the corresponding inputs of the AGC and the AFC of the first and second channels of the receiver 5, the output of the antenna switch 6 is connected to the first input of the receiver 5. In addition, the output of the frame detection unit 12 is the first output of the reception channel of data transmission I, the output of the CINR 13 estimator — the second output, the output of the RSSI estimator 14 — the third, the output of the time-frequency estimator of the received signal 15 — fourth, the outputs from the first to the fourth receive-ne channel the data input I is connected to the corresponding inputs of the control unit 1. In addition, the data reception and transmission channel I contains a power control signal generation unit 16, the first input of which is connected to the output of the decoder 9, and the second input is connected to the output of the frame detection unit 12, and the output the power control signal generating unit 16 is connected to the control bus.

The block diagram of the encoder of the proposed portable subscriber mobile station is shown in Fig.7, where it is indicated:

3.1 - Reed / Solomon block encoder; 3.2 - convolutional encoder; 3.3 - interleaver; 3.4 - turbo encoder; 3.5 - block partial or complete power outage and change the clock frequency of the functional units.

The encoder 3 contains series-connected block Reed / Solomon encoder 3.1, a convolutional encoder 3.2, an interleaver 3.3, the output of which is the output of encoder 3. The first input of the Reed / Solomon 3.1 encoder is the first input of encoder 3, the control input of which is connected to the control inputs of blocks 3.1, 3.2, 3.3, 3.4, 3.5. The first input of the turbo encoder 3.4 is connected to the first input of the Reed / Solomon 3.1 block encoder, and the output is connected to the interleaver 3.3 input.

The structural diagram of the decoder of the proposed portable subscriber mobile station 9 is shown in Fig.8, where indicated:

9.1 - reverse interleaver; 9.2 - Viterbi decoder; 9.3 - Reed / Solomon block decoder; 9.4 - turbo decoder; 9.5 - block partial or complete power failure and change the clock frequency of the functional units.

The decoder 9 contains a series-connected reverse interleaver 9.1, a Viterbi decoder 9.2 and a Reed / Solomon 9.3 block decoder, the output of which is the output of the decoder 9. The first input of the interleaver 9.1 is the first input of the decoder 9, and its control input is connected to the control inputs of blocks 9.1, 9.2, 9.3, 9.4, 9.5. The first input of the turbo decoder 9.4 is connected to the output of the deinterleaver 9.1, and its output is connected to the output of the Reed / Solomon 9.3 block decoder.

The structural diagram of the modulator of the proposed portable subscriber mobile station 10 is shown in Fig.9, where it is indicated:

10.1 - block forming characters BPSK, QPSK, 16QAM, 64QAM from the input data stream; 10.2 - block substitution of the pilot signal and protective characters; 10.3 - block inverse fast complex Fourier transform; 10.4 - block interpolator and digital low-pass filter; 10.5 - digital-to-analog converter (DAC); 10.6 - block partial or complete power failure and change the clock frequency of the functional units.

The modulator 10 contains a series-connected block of character formation BPSK, QPSK, 16QAM, 64QAM from the input data stream 10.1, a substitution block for the pilot signal and protective sub-characters 10.2, an inverse fast complex Fourier transform block 10.3, an interpolator and a digital low-pass filter 10.4 and DAC 10.5, the output of which is the output of the modulator. The first input of the character generation unit BPSK, QPSK, 16QAM, 64QAM from the input data stream 10.1 is the first input of the modulator 10, the control input of the modulator 10 is connected to the control inputs of the blocks 10.1,10.2, 10.3, 10.4, 10.5,10.6.

The structural diagram of the demodulator of the proposed portable subscriber mobile station 11 is presented in figure 10, where it is indicated:

11.1 - analog-to-digital Converter (ADC); 11.2 - block digital low-pass filter and thinning device; 11.3 - block fast complex Fourier transform; 11.4 - block allocation of the pilot signal and protective sub-characters; 11.5 - block weighted summation and formation of a stream of data bits; 11.6 - controller for automatically adjusting the gain of the receiver; 11.7 - automatic frequency control controller; 11.8 - equalizer; 11.9 - block partial or complete power failure and change the clock frequency of the functional units.

The demodulator 11 is made two-channel, and the second channel is identical to the first, while all the functional nodes of the demodulator 11 and their connections are two-channel. The demodulator 11 contains a series-connected ADC 11.1, a digital low-pass filter unit and a decimation device 11.2, a fast complex Fourier transform unit 11.3, a pilot signal and protective sub-symbols 11.4, and a weighted summing and generating block of data bits 11.5, the output of which is the output of the demodulator 11 The first and second inputs of the ADC 11.1 are the corresponding inputs of the demodulator 11 and, respectively, the inputs of the first and second channels. The control input of the demodulator 11 is connected to the control inputs of the blocks 11.1, 11.2, 11.3, 11.4, 11.5, 11.6, 11.7, 11.8, 11.9. In addition, the output of the ADC 11.1 is connected to the first input of the controller for automatically adjusting the gain of the receiver 11.6, the first output of which is the AGC output of the first channel, and the second output is the AGC output of the second channel. The output of the digital low-pass filter block and decimation device 11.2 is connected to the first input of the AFC controller 11.7, the first output of which is the AFC output of the first channel, and the second output is the AFC output of the second channel. The output of the fast complex Fourier transform block 11.3 is connected to the first input of the equalizer 11.8 and the second inputs of the blocks 11.5 and 11.7. In this case, the output of the equalizer 11.8 is connected to the third input of the weighted summation block and the formation of the data bit stream 11.5.

The structural diagram of the transmitter of the proposed portable subscriber mobile station 4 is shown in Fig. 11 and differs from the prototype transmitter circuit by the additionally introduced block 4.1 of a partial or complete power outage and a change in the clock frequency of the functional units, the input of which is connected to the control input of the transmitter 4.

The block diagram of the receiver of the proposed portable subscriber mobile station 5 is shown in Fig. 12 and differs from the receiver-prototype scheme by the additionally introduced block 5.1 of a partial or complete power outage and a change in the clock frequency of the functional nodes, the input of which is connected to the control input of the receiver 5.

The proposed device operates as follows.

When the power is turned on, the portable subscriber mobile station of the radio access equipment automatically switches to the mode of receiving service synchronization packets from base stations according to the IEEE 802.16e standard.

Any station located in the radio access network goes into the transmission mode by the signal “Transfer Request” from a digital information source, in this case, from one of the interfaces of the high-speed data transmission infrastructure: PCMCIA, PCIe, USB, CF or Ethernet.

The network data goes to the input-output of the control unit 1, where the methods of medium access, frame format, addressing, support for access to the communication channel are implemented, information and control frames are received and transmitted, transmission and reception errors are detected, and the handover procedure is implemented, allowing a portable subscriber mobile station to switch between base stations due to a change in its location and interference conditions, without interrupting communication and without stopping the reception and transmission of digital information and.

The transmitted information packets, which are a continuous stream of bytes, from the information output of the control unit 1 through the information input of the transmit-receive channel I go to the first input of the encoder 3 (Fig. 7), where the byte stream is encoded under the control of block 1, which is provided by the Reed block encoder / Solomon 3.1. After processing in the Reed / Solomon 3.1 block encoder, the byte stream is supplied as a serial bit stream to the convolutional encoder 3.2, which introduces redundancy in the bit stream. After the convolutional encoder 3.2, the bit stream is fed to the input of the interleaver 3.3, where the bits coming from the convolutional encoder 3.2 are interleaved with the specified interval and depth values. Depending on the parameters set at the base station, the input stream under control of block 1 can be encoded by a turbo encoder 3.4 instead of being encoded by a Reed / Solomon 3.1 block encoder and a convolutional encoder 3.2. Next, from the output of the encoder 3, the bit stream is fed to the first input of the modulator 10 (Fig. 9), where under the control of block 1 in block 10.1 it is converted to BPSK, QPSK, 16QAM or 64QAM, preferably with orthogonal frequency division, and goes to block 10.2, where is the substitution of the pilot symbols. Next, the new generated sequence arrives in block 10.3 inverse fast Fourier transform. Upon completion of the modulation, the digital sequence is supplied to block 10.4 and, if necessary, is interpolated to a higher frequency before output to the DAC 10.5, the output signal of which is the output signal of the modulator 10. Next, the signal from the modulator 10 is fed to the first input of the transmitter 4 (Fig.6 ) Block 1 controls the transmitter 4 and its required level of output power. Then the signal enters the antenna switch 6, where, under the control of unit 1, it is transmitted to the transceiver antenna 7.1 through the antenna matching device 8.1 and is transmitted to the air at a channel speed of up to 37.2 Mbit / s.

The portable subscriber mobile station of the radio access equipment can receive the reception mode both on one antenna 7.1, and on two antennas 7.1 and 7.2, for the subsequent optimal reception of signals and interference suppression, implemented in block 11.5 in the form of a weight adder with complex weighting factors, and as a result , increasing the noise immunity and the bandwidth of the data receiving-transmitting channel I. For this, a two-channel receiver 5 and a two-channel demodulator 11 are provided in the mobile station.

Functional nodes of the demodulator 11.1-11.8 (figure 10) and all their connections are implemented dual-channel. The inclusion of the second receiving channel of the receiver 5, the demodulator 11, and the weighted summation unit and the formation of the data bit stream 11.5 takes place depending on the operating mode of the station and is controlled directly by the control unit 1.

In the reception mode for one antenna, the portable subscriber station of the radio access equipment located in the network performs the procedure of the inverse transformation of the signal received by the antenna 7.1. In this case, the signal through the ACS 8.1 and under the control of unit 1 from the antenna switch 6 is fed to the first input of the receiver 5, and then to the demodulator 11 (figure 10), where the analog signal is fed to the input of the ADC 11.1. The output signal of the ADC 11.1 is sampled and fed as a feedback signal to the automatic gain control (AGC) loop implemented by block 11.6, so that the ADC 11.1 operation mode is supported in a linear operating range. The output signal of the ADC 11.1 is also supplied to the first input of block 11.2, as a result of which the digital signal is digitally processed and filtered. After these transformations, the signal is an orthogonal frequency division symbol, which is fed into the feedback loop of the automatic frequency adjustment implemented by the AFC controller 11.7 so that the frequency of reception coincides with the frequency of the received signal. Further, the symbols with orthogonal frequency division are fed to the fast complex Fourier transform block 11.3, the output of which is fed to the input of block 11.4 to extract the sub-symbols and pilot synchronization signals, to the feedback loop of the automatic frequency adjustment implemented by block 11.7, to the first input of the equalizer 11.8 and to the second input of block 11.5. In the equalizer 11.8 under the control of block 1, the data is digitally filtered to compensate for the nonlinearity of the distribution channel and then fed to block 11.5. The sub-symbols and pilot synchronization signals allocated by block 11.4 are also received in block 11.5. At the next stage of demodulation in block 11.5, under the control of block 1, the received BPSK, QPSK, 16QAM, 64QAM characters are converted to a bit stream received at the output of demodulator 11.

Next, the bit stream is subjected to deinterleaving in block 9.1 of decoder 9 (Fig. 8). Reverse interleaver 9.1 places the bits in the same order as they were in the original transmitted signal. Next, the serial data stream enters the Viterbi decoder 9.2, where the bit rate decreases to correct errors and enters the Reed / Solomon decoder 9.3 to correct the remaining errors. Depending on the parameters set at the base station, the serial data stream from block 9.1 under the control of block 1 can be decoded by turbo decoder 9.4 instead of decoding in Viterbi decoder 9.2 and Reed / Solomon decoder 9.3. The generated information stream enters the control unit 1 for converting it into the required format of the received data corresponding to the standard of one of the PCMCIA, PCIe, USB, CF or Ethernet interfaces, where the methods of medium access, frame format, addressing, support for access to the communication channel are implemented, receiving and transmitting information and control frames, detecting transmission errors are detected and fed to the input-output of control unit 1 for further connection of the subscriber mobile station to one of the interfaces highly high-speed information transfer: PCMCIA, PCIe, USB, CF or Ethernet.

Each station analyzes the signal-to-noise ratio and, as a result, the quality of information exchange at the operating frequency. If the signal-to-noise ratio is poor, the portable subscriber station of the radio access equipment can adaptively change the type of coding and the type of modulation to ensure the necessary quality of information exchange at the operating frequency. In addition to receiving a signal at the operating frequency, the subscriber mobile station searches for neighboring base stations at other frequencies and simultaneously generates estimates obtained as a result of the operation of the frame detection unit 12 (Fig. 6), the CINR 13 evaluation generating unit, the RSSI 14 evaluation generating unit, and the frequency -time assessment of the received signal 15. Based on the assessment of the interference environment and the assessment of the time-frequency and physical parameters of the received information packets from neighboring base stations, can be carried out edura handover, during which the frequency tuning of the subscriber station to a frequency of another base station, as well as other parameters of the subscriber mobile station according to the standard IEEE 802.16e.

Each of the functional blocks of the portable subscriber mobile station of the radio access equipment is controlled from block 1 through the control bus of the data receiving and transmitting channel I by a signal supplied to the control input of the corresponding block.

In the reception mode for two antennas, a subscriber mobile station located in the network performs the procedure of the inverse transformation of the signal received by antennas 7.1 and 7.2. In this case, according to the signal from the control unit 1, the second channels of the receiver 5, demodulator 11, similar to the first, and the block of weighted summation and formation of the data bit stream 11.5 enter into operation. At the same time, both channels of the receiver and demodulator operate independently of each other, performing the same functions. The feedback loops of the AGC and AFC of both channels of the receiver 5 also work independently of each other. Thus, two independent data streams formed by identical receive paths enter block 11.5 of the demodulator 11, which allows the algorithm for optimal weighted summation of independent data streams to be implemented at the final stage of demodulation in order to suppress interference and, as a result, increase the bandwidth of the data reception and transmission channel I. At the same time, the complex weighting coefficients of the summation of the input stream in can be both permanent and formed by a certain algorithm.

Given that the receiver 5 is made two-channel, the functional nodes of the blocks 12, 13, 14 and 15 are also two-channel, which makes it possible, in addition to implementing the handover procedure, to additionally carry out the auto-selection procedure, which consists in connecting the signal to that antenna, the physical characteristics of the signal and the interference environment at the receiving point which is most favorable.

In addition, working in accordance with the IEEE 802.16e standard (http://standards.ieee.org/getieee802) portable subscriber mobile station

radio access equipment, based on the operation of the power control signal generation block 16, determines the time points at which the station should transmit and receive. Knowing the moment the radio station enters the transmission mode, the power consumption control signal generation block 16 through the control bus of the data reception-transmission channel I, depending on the operation mode of the mobile station, partially or completely shuts off the reception path by controlling the partial or complete power outage blocks 5.1, 9.5, 11.9, and also reduces the clock frequencies of individual energy-intensive functional units of the respective blocks, which significantly reduces the power consumption of the mobile station as a whole. Similarly, knowing the time of the radio station’s operation in receive mode, the power consumption control signal generation block 16, through the control bus of the data reception and transmission channel I, partially or completely shuts off the transmission path by controlling the partial or complete power outage blocks 3.5, 10.6, 4.1, and also lowers the clock frequencies of individual energy-intensive functional units of the respective blocks, which, in turn, significantly reduces the power consumption of the subscriber mobile station as a whole. Thus, due to the joint work of the power consumption control signal generation block 16 and the blocks 5.1, 9.5, 11.9, 3.5, 10.6, 4.1 of a partial or complete power outage and a change in the clock frequency of the functional units of the blocks, a significant increase in the continuous operation time and the service life of autonomous power sources and reduce energy consumption of the subscriber mobile station radio access equipment in general. It is also possible to programmatically disable the operation algorithms of the corresponding blocks 3, 4, 5, 9, 10, 11.

Blocks of the proposed portable subscriber mobile station of radio access equipment such as control unit 1, encoder 3, Reed / Solomon block encoder 3.1, convolutional encoder block 3.2, interleaver 3.3, turbo encoder 3.4, decoder 9, reverse interleaver 9.1, Viterbi decoder 9.2, reed block decoder / Solomon 9.3, turbo decoder 9.4, modulator 10, symbol generation unit BPSK, QPSK, 16QAM, 64QAM 10.1, substitution block for the pilot signal and protective sub-characters 10.2, inverse fast complex Fourier transform 10.3, interpolator and digital low-pass filter unit frequencies 10.4, demodulator 11, digital low-pass filter unit and decimation device 11.2, fast complex Fourier transform block 11.3, pilot signal and protective sub-symbol extraction unit 11.4, weighted summing and generating data bit stream 11.5 block, automatic gain control controller for receiver gain 11.6 , automatic frequency adjustment controller 11.7, equalizer 11.8, frame detection unit 12, evaluation unit CINR 13, evaluation unit RSSI 14, time-frequency estimation unit of the 15th signal, the power control signal generation block 16 can be performed using user-programmed gate arrays, which are matrix FPGAs or technologies based on special integrated circuits (ASIC, VLSI), as well as on the basis of digital signal processor technology and RISK processors . Blocks for partial or complete power outages and changes in the clock frequency of functional units 3.5, 4.1, 5.1, 9.5, 10.6, 11.9 can be performed on microcircuits of analog equipment, as well as microcircuits designed to control the power supply of individual functional units. It is also possible to programmatically disable the operation algorithms of the corresponding blocks 3, 4, 5, 9, 10, 11.

Thus, the proposed portable subscriber mobile station of radio access equipment allows you to organize a high-speed radio network for the transmission of information and packet duplex radio communications, the exchange of digital information in accordance with the IEEE 802.16e standard, where one of the following interfaces of the high-speed data transmission infrastructure can be used as a source of digital information:

- PCMCIA - (Peripheral Component MicroChannel Interconnect Architecture http://www.pcmcia.org/);

- PCIe - (PCI Express or PCI-E, also known as 3GIO for 3rd Generation I / O http://www.pcisig.com/specifications/pciexpress/);

- USB - (Universal Serial Bus http://www.usb.org/developers/docs/);

- CF - (CompactFlash http://www.compactflash.org/);

- Ethernet - (IEEE 802.3 and IEEE 802.3u LAN standard http://standards.ieee.org/getieee802/download/802.3-2002.pdf),

as well as implement a power saving mode depending on the operating mode of a portable subscriber mobile station of radio access equipment, which significantly increases the continuous operation time and service life of autonomous power sources.

Claims (6)

1. A portable subscriber mobile station of radio access equipment, comprising a control unit, the control output of which is connected by a bi-directional control bus to the control input-output of a data reception and transmission channel, the input and output of the control unit being an interface of high-speed data transmission networks, a transmission and reception channel the data contains a series-connected encoder, modulator, transmitter and antenna switch, the output-input of which through the first antenna matching device is connected to the receiver transmitting antenna, as well as a series-connected receiver, demodulator and decoder, the output of which is the information output of the data reception and transmission channel and connected to the information input of the control unit, the information output of which is the information input of the data reception and transmission channel and the first input of the encoder, as well as the receiving an antenna that is connected to the third input of the receiver through the second ACS, a frame detection unit, a CINR (Carrier to interference plus noise ratio) estimator, an RSSI (Receive Strength Signal Indicator) and the block of the time-frequency estimation of the received signal, made by two-channel, the first inputs of which are combined and connected to the first output of the receiver, and the second inputs are combined and connected to its second output, in addition, the output of the frequency synthesizer is connected to the second inputs of the transmitter and the receiver, and its input - with the control input-output of the data reception and transmission channel and with the control inputs of the encoder, modulator, transmitter, two-channel receiver, two-channel demodulator, decoder, antenna switch a, a frame detection unit, a CINR rating generating unit, an RSSI rating generating unit and a time-frequency estimation unit for a received signal, while the outputs of automatic gain control (AGC1 and AGC2) and automatic frequency adjustment (AFC1 and AFC2) of the first and second channels of the demodulator are connected with the corresponding inputs of the AGC and AFC of the first and second channels of the receiver, the first input of which is connected to the output of the antenna switch, in addition, the output of the frame detection unit is the first output of the transmit-receive channel data, the output of the CINR estimation generating unit is its second output, the RSSI evaluation generating unit output is the third, the output of the time-frequency estimation unit of the received signal is fourth, and the outputs from the first to fourth data reception and transmission channels are connected to the corresponding inputs of the control unit, characterized by the fact that a power consumption control signal generation unit is introduced into the data transmission and reception channel, the first input of which is connected to the output of the decoder, and the second input is connected to the output of the frame detection unit, m the output of the power control signal generation block is connected to the control bus, while the corresponding blocks of partial or complete power outage and change of the clock frequency of the functional units are introduced into the encoder, decoder, modulator, demodulator, receiver and transmitter, the input of each of which is connected to the control input of the corresponding block. 2. The portable subscriber mobile station according to claim 1, characterized in that the input-output of the control unit 1 is a PCMCIA high-speed information transmission interface. 3. The portable subscriber mobile station according to claim 1, characterized in that the input-output of the control unit 1 is an interface for the high-speed transmission of PCIe information. 4. The portable subscriber mobile station according to claim 1, characterized in that the input-output of the control unit 1 is an interface for high-speed USB data transmission. 5. The portable subscriber mobile station according to claim 1, characterized in that the input-output of the control unit 1 is an interface for high-speed transmission of information CF. 6. The portable subscriber mobile station according to claim 1, characterized in that the input-output of the control unit 1 is an Ethernet high-speed information transmission interface.