Radiotelephone station capable of transmitting data

FIELD: radio engineering, communication.

SUBSTANCE: radio station further includes a data transmission channel converter, a data reception channel converter, a data transmission channel information converter, wherein the data transmission channel converter has six channel data transmission packet generators. The data transmission channel information converter has six channel data transmission channel information generators. Use of the device allows operation of the radio station in duplex mode at one frequency on one antenna with ten telephone channels and switching six channels from the fifth to the tenth channel for operation in data transmission mode with speeds in channel of: 100, 300, 500 and 1200 Bd for operation with data terminal equipment and at 1200 Bd for operation with a personal computer.

EFFECT: high flexibility during communication by introducing data transmission channels, increasing throughput of the radio station.

12 cl, 15 dwg

 

The invention relates to the field of radio communications and can be used to create radio stations, meter, decimeter and centimeter ranges of the radio spectrum, providing two-way radio communication with one antenna at the same frequency in the mode of a pseudo-random adjustment of the operating frequency (frequency hopping). Mode hopping is also called mode software adjustment of the operating frequency.

The radio station, as well as other electronic means on one antenna possible if the separation time of the transfer, i.e. successive work stations for reception and transmission. So work radar station, and the time to transfer much less time taking and simplex radio with manual or automatic control modes of transmission and reception.

Duplex radio communication is a two-way radio communication in which transmission is carried out simultaneously with the radio (GOST 24375-80, Radio. Terms and definitions). Currently widely used work stations in the duplex mode spacing in frequency or antennas with different polarization (e.g., TV reception waves with vertical and horizontal polarization; means of communication through satellites reception waves levomenthol and provintsii polarizations).

Know the local antenna switches, that is, devices designed for automatic switching of the antenna input of the radio transmitter to the receiver input and back, apply in the case of using a common antenna for transmission and reception (bila Tserkva G.B. Antenna. M: Hesistates mod, 1956, and 1962).

Another type of antenna switch, having a frequency range of 50-860 MHz, the maximum switching capacity of 100 watts and crosstalk between the switching inputs are not less than 34 dB, presented in the book: "the Antenna switch type PA-2" Bulgaria, Industrial and maintenance of enterprise communication. Industrial directory PC-9645-88. The antenna switch with replaceable circuit boards. Sweden PC-9635-88 proposed device software management with replaceable circuit boards, which performs the switching of antennas for reception and transmission.

Methods of calculation of semiconductor switching devices, and a description of the power and the matrix switches of the microwave range, schema management as outlined in the book: BitBlt AV Switching devices microwave semiconductor diode, M., Chapman and hall, 1987

Patent of the Russian Federation 2118050 from 20.08.98 on the application 95116780/09 from 02.10.95 implements a duplex mode in ten channels to their temporary separation for raznosortnyh packets of information pulses in each to the patient from 1 MS to 10 MS.

Patent of the Russian Federation 2141723 from 20.11.99 on the application 95110203/09 from 16.06.95 implements a duplex mode in ten channels to their temporary separation for onemillionth information pulses in each channel.

Patent of the Russian Federation 2225674 from 10.03.2004 on the application 2000117626/09 from 04.07.2000 implements a duplex mode in ten channels to their temporary separation for two onemillionth information pulses in each channel time-correlated channels from 1 MS to 10 MS.

Patent of the Russian Federation 2225673 from 10.03.2004 on the application 2000117625/09 from 04.07.2000 implements a duplex mode in ten channels to their temporary separation for two onemillionth information pulses in each channel time-correlated channels from 1 MS to 10 MS, structurally introduced a system of maintaining a closed-door talks.

Known simplex radio station R-625, manufactured according to the specifications IZH 1.101.020. THE unit pseudo-random (software) adjustment of the operating frequency (block hopping and with his regular antenna To-698-1. General specifications UGT. Part of the radio station R-625 comes with a switch of acceptance (block 6, relay 3)carrying out the antenna connection to the radio (Radio R-625. Technical description and operating instructions. IGT). When pressed the PTT switch output radio programmes is adamcik is disconnected from the antenna, and the antenna is connected to the input of the radio.

Set of two radio stations R-625 with their regular antennas does not provide the organization duplex frequency division transmission and reception by the defeat of the input circuits in the radio mode pseudo-random adjustment of the operating frequency (frequency hopping), when the frequencies of transmission and reception accidentally coincide.

The base object can serve as the patent of the Russian Federation 2118050 from 20.08.98 on the application 95116780/09 from 02.10.95, which implements a duplex mode in ten telephone channels with their time division mode of reception and transmission in each channel and the separation channel on the basis of raznosortnyh packets of information pulses in each channel from 1 MS to 10 MS.

The basic object of the work station has the following disadvantages:

- you will not be able to provide data for standard transmission channels with speeds: 100, 300, 500, 1200;

- you will not be able to provide data for the standard bearer, with speeds of 1200 Baud/s to work with personal computers.

The aim of the present invention is to automate the control of the antenna switch, providing full-duplex mode when working on a single antenna mode, a pseudo-random realignment of operating frequencies (frequency hopping), increased maneuverability when exchanging information through the introduction channel is in data transfer; increasing the capacity of radio stations in the data transmission channels; reduction in material costs when creating a duplex mode for the radio channels of telephone and data transmission.

To achieve this goal in a radio station, consisting of a non-directional antenna 1 connected to a coaxial cable line 3 through the antenna diode capacitive switch 2 in parallel through the radio 4 and radio 5 (figure 1), which are connected in parallel with the unit of frequency tuning of a radio receiver and a radio transmitter unit poft 14, inputs of the amplifier 6, the clock 7, the Converter receiving channels 8, the Converter of the transmission channel 9, the block of ten analog-to-digital Converter 11, a block of ten digital-to-analogue converters 10, the filter unit 12, ten remote stations radio operator-operator 13, the Converter is receiving data channels 16, each output of the ten remote stations radio operator-operator 13 is connected through the filter cartridge 12 with ten inputs of the analog-to-digital converters 11 and through their ten outputs with ten inputs of the Converter of the transmission channel 9, the output of which is connected in parallel to the first input of the transmitter 5 and the amplifier 6 to the second input of the antenna diode capacitive repair the I 2, and each entry of the ten remote stations radio operator-operator 13 is connected with the ten inputs of the filter block 12 and through him with the ten outputs of the unit d / a converters 10 and through it connected with the ten outputs of the Converter receiving channels 8, the first input connected to the output of radio 4, the generator output clock pulses 7 connected in parallel to the second input of the Converter receiving channels 8, to the eleventh input of the Converter transfer channels 9 and to the input of the pseudo-random frequency hopping 14, eleventh inverter output channels 8 is connected through a switch 15 "VK" twelfth input channel converters transmission 9, six inputs 13, 14, 15, 16, 17 and 18 of the transducer transmission channels 9 form inputs to work with data transmission channels; the outputs of the twelfth, thirteenth, fourteenth, fifteenth, sixteenth and seventeenth Converter receiving channels 8 are connected in parallel to the first, second, third, fourth, fifth and sixth inputs of the Converter is receiving data channels 16, the Converter is receiving data channels 16 has six outputs for connection receiving part of the data transmission channels; the seventh input of the inverter 16 is connected to the generator output tact 7.

Converter channels of the front and 9 (figure 2) contains the pulse counter 17, ten delay lines smooth tuning 18, nine lines of discrete delay (VIP) with a delay of 100 MS to 900 MS (from 19 to 27); nine triggers 28, 29, 30, 31, 32, 33, 34, 35, 36, ten shapers of information pulses 37, item, OR 38, switches: 1, 2, 3, 4, 5, 6, 7 and 8, the transmitter of the data transmission channels 39 and item OR 40, with ten inputs of the Converter 9 form ten channels, in which each of the ten inputs from the first to the tenth connected with the second input of ten shapers of information pulses 37 and through them through the element 38 and the first input of the OR element 40 with the output of the Converter 9. The eleventh input of the inverter 9 is connected through the meter 17 to the first input of the shaper of information pulses 37 in each of the ten channels connected in series through the first channel - smooth line delay 18; the second channel is through the smooth line delay 18, through line discrete delay 19 and through the trigger 28, the third channel is through the smooth line delay 18, through line discrete delay 20 and through the trigger 29; in the fourth channel - through the smooth line delay 18, through line discrete delay 21 and through the trigger 30; in the fifth channel - through the line smooth delay 18, through line discrete delay 22 and through the trigger 31; in the sixth channel - through the smooth line delay 18, through line discrete delay 2 and through the trigger 32; in the seventh channel - through the smooth line delay 18, through line discrete delay 24 and through the trigger 33; in the eighth channel - through the smooth line delay 18, through line discrete delay 25 and through the trigger 34; in the ninth channel-through the smooth line delay 18, through line discrete delay 26 and through the trigger 35; in the tenth channel - through the smooth line delay 18, through line discrete delay 27 and through the trigger 36. The trigger output is 36 through the switch 1 may be connected to the first input transducer data channels 39 to use the tenth channel in the automatic transfer of data from data terminal equipment (DTE); trigger output 35 through the switch 2 may be connected to the second input of the Converter data channels 39; trigger output 34 through the switch 3 is connected to the third input of the Converter data channels 39; trigger output 33 through the switch 4 is connected to the fourth input of the Converter data channels 39; trigger output 32 through the switch 5 is connected to the fifth input of the Converter data channels 39; trigger output 31 through the switch 6 is connected to the sixth input of the Converter data channels 39; and the Converter output data channels 39 through the switch 8 is connected with the second input element ILI. The inputs of the thirteenth, fourteenth, fifteenth, sixteenth, seventeenth and eighteenth Converter transmission channels 9 are connected in parallel to the six inputs of the Converter data channels 39 starting from the seventh through the twelfth, respectively, of the twelfth input of the inverter 9 is connected to the second input of the counter 17.

Each driver information pulses 37 (figure 3) contains in each of the ten channels of the first and second memory cells 41 and 42, seven elements And(43, 44, 45, 46, 47, 48 and 49), two elements (50 and 51), the multivibrator 52, the trigger 53 and the element OR 55 and the offset pulse 54, which contains the trigger 57, differentiating the chain of the elements of the valve D1and resistor R1and the delay line 56. The first input of the driver 37 is connected to the output of the imaging unit 37 through two identical parallel circuits. The first circuit is a first output of the driver 37 is connected via the first input of the first element And 43, through the first input of the first memory cell 41, through the first input of the seventh element And 49, through the first input element OR 55 with the output of the imaging unit 37. The second circuit first input of the shaper 37 is connected via the first input of the third element And 45, through the first input of the second memory cell 42, through the first input of the second element And 44 and through a second input of the OR element 55 with the output of the imaging unit 37. All of Stalin the e elements, presented at figure 3, there are controls the recording and reading of information recorded in the memory cells 41 and 42 are synchronized with the pulses of the GTI 7 (Fig 1 and Fig 2)received on the second input of the shaper 37. The second input of the shaper 37 are connected in parallel to the input of the trigger 53 to the input of the offset pulse 54 and the input of the multivibrator 52. The output of the trigger 53 is connected through the first element is NOT 51 in parallel to the second input of the first element And 43 and to the second input of the second element And 44. The output of the trigger 53 is also connected through the second element 50, through the second input of the fifth element And 47 to the second input of the second memory cell 42. In addition, the output of the trigger 53 is connected through a second input of the fourth element And 46 to the second input of the first memory cell 41. Further, the output of the trigger 53 is connected in parallel to the second input of the third element And 45 and to the second input of the seventh element And 49. The output of multivibrator 52 through the second input of the sixth element And 48 are connected in parallel to the first input of the fifth element And 47 and to the first input of the fourth element And 46. The output of the offset pulse 54 is connected to the first input of the sixth element And 48. The sign of the offset pulse 54 (figure 4) is connected through smooth delay line 56, through the valve D1differentiating chain in parallel through resistor R1on the ground, and through input trigger 57 with the output is arrector pulse 54.

A Converter receiving channels 8 (figure 5) contains ten channels in each of the ten channels own channel driver information 58, nine items And 59 (the first element 59-1 And for the first channel, the second element And 59-2 in the second channel, the third And 59-3 in the third channel, the fourth And 59-4 - in the fourth channel, the fifth And 59-5 - in the fifth channel, the sixth And 59-6 - in the sixth channel, the seventh And 59-7 - in channel seven, eight And 59-8 - in the eighth channel, ninth And 59-9 - ninth channel), nine elements And 60 (the first element 60-1 And for the first channel, the second element And 60-2 in the second channel, the third And 60-3 - in the third channel, the fourth And 60-4 - in the fourth channel, the fifth And 60-5 - in the fifth channel, the sixth And 60-6 - in the sixth channel, the seventh And 60-7 - in channel seven, eight And 60-8 - in the eighth channel, ninth And 60-9 - ninth channel), nine triggers- 61, 62, 63, 64, 65, 66, 67, 68 and 69, nine items NOT 70 and nine lines smooth delay 71 1 MS, and in each of the ten channels formed breeding raznosortnyh packets of information pulses at the expense of the trigger, line 71, element 70 and two elements 59 and 60. So first channel formed by the serial connection of the inverter input reception 8 through the first line smooth delay 71, through the first input of the first element And 59-1 to the first input of the first driver information 58 is supplied to only the packet of the first channel long is inetu 1 MS, because the first input inverter receiving 8 all incoming packets of pulses in the first channel from them is only the first onemillisecond due to the work element 70. All packets received on the first input of the Converter 8 through the line smooth delay 71 to the first inputs of two elements And 59-1 60-1 and, by the second input of which receives the pulses of the trigger 61, whereby the element 60-1 And directly from the output of the trigger 61, and on the element And 59-1 through the element is NOT 70, the trigger 61 from onemillimeter pulse does not start, therefore, at the output from the first pulse have zero voltage, so through the element 60-1 And the first pulse onemillisecond not pass, but through the element And 59-1 pass, because the input element is NOT 70 zero, and the output of inverter 70 is the voltage that will skip the first pulse through the element 59-1 And to the first input of the shaper information 58. In the rest of the packets of pulses, except the first, the trigger 61 on their duration repeats and provides further pass through the element And 60-1, when this element 59-1 And for these packets of pulses will be closed by the inverter 70 to its second input. In this way provide a selection of the second package with duration of two milliseconds through the element And 59-2 in the second channel to the first input of the shaper 58, the trigger 62 is triggered only from rehmi losecontrol for the duration of the package i.e. the trigger 62 reproduces all packages starting with trehmilliardnoe and therefore miss all the packets of pulses through the second element And 60-2 on the second input, when receiving packets on its first input and the second element And 59-2 in the second channel will skip only dvukhelementnye due to the inversion of the second element 70, included on its second input. Thus, due to the work items and the set of relations is the selection of packets of pulses in each channel according to their duration.

In accordance with figure 5 of the first input inverter receiving channels 8 are connected in parallel through the delay line 71 to the first inputs of the first elements And 60-1 and the second And 59-1, and after the first trigger 61 to the second input of the first element And 60-1 and to the second input of the second element And 59-1 through the element is NOT 70; the output of the first element And 60-1 are connected in parallel through the delay line 71 to the first inputs of the elements of the third And 60-2 and the fourth And 59-2, and through the second trigger 62 to the second input of the third element And 60-2 and to the second input of the fourth element And 59-2 through the element is NOT 70; output the third element And 60-2 are connected in parallel through the delay line 71 to the first input element of the fifth And 60-3 and the sixth And 59-3, and after the third trigger 63 to the second input of the fifth element And 60-3 and to the second input of the sixth element And 59-3 through the element is NOT 70; vhodyathego element And 60-3 are connected in parallel through the delay line 71 to the first inputs of the elements of the seventh And 60-4 and the eighth And 59-4, and through the fourth trigger 64 to the second input of the seventh element And 60-4 and to the second input of the eighth element And 59-4 through the element is NOT 70; the output of the seventh element And 60-4 are connected in parallel through the delay line 71 to the first inputs of the elements of the ninth And 60-5 and the tenth And 59-5, and through the fifth trigger 65 to the second input of the ninth element And 60-5 and to the second input of the tenth element And 59-5 through the element is NOT 70; output ninth element And 60-5 connected in parallel through the delay line 71 to the first inputs of the elements of the eleventh And 60-6 and the twelfth And 59-6, and through the sixth trigger 66 to the second input of the eleventh element And 60-6 and to the second input of the twelfth element And 59-6 through the element is NOT 70; output eleventh element And 60-6 connected in parallel through the delay line 71 to the first inputs of the elements of the thirteenth And 60-7 and the fourteenth And 59-7, and through the seventh trigger 67 to the second input of the thirteenth element And 60-7 and to the second input element of the fourteenth And 59-7 after the item is NOT 70; output thirteenth element And 60-7 connected in parallel through the delay line 71 to the first inputs of the elements of the fifteenth And 60-8 and sixteenth And 59-8, and through the eighth trigger 68 to the second input the fifteenth item And 60-8 and to the second input of the sixteenth element And 59-8 through the element is NOT 70; output fifteenth element And 60-8 connected in parallel through the delay line 71 to the first of the passages of the elements of the seventeenth And 60-9 and eighteenth And 59-9, and through ninth trigger 69 to the second input of the seventeenth element And 60-9 and to the second input of the eighteenth item And 59-9 through the element is NOT 70; output seventeenth element And 60-9 connected through the switch 6 to the first input channel driver 58 in the tenth channel or through the switch 6 to the seventeenth inverter output channels 8; the output of the second element 59-1 And connected in parallel to the eleventh inverter output channels 8 and to the first output via the first input channel driver 58 in the first channel; the output of the fourth element And 59-2 connected to the second inverter output channels 8 through the first the entrance channel driver 58 in the second channel; the output of the sixth element And 59-3 connected to the third inverter output channels 8 through the first input channel driver 58 in the third channel; the output of the eighth element And 59-4 connected to the fourth inverter output channels 8 through the first input channel driver 58 in the fourth channel; the output of the tenth element And 59-5 connected in parallel through the first switch to the twelfth inverter output channels 8 or to his fifth output through the first input channel driver 58 in the fifth channel; the output of the twelfth element And 59-6 connected in parallel through a second switch to trinadtsat the mu the inverter output channels 8 or to his sixth output through the second switch and through the first input channel driver 58 in the sixth channel; the output of the fourteenth element And 59-7 connected in parallel through the third switch to the fourteenth inverter output channels 8 or in its seventh output through the third switch and through the first input channel driver 58 in the seventh channel; output sixteenth element And 59-8 connected in parallel via the fourth switch to the fifteenth inverter output channels 8 or its eighth output through the fourth switch and through the first input channel driver 58 in the eighth channel; output eighteenth element And 59-9 connected in parallel via a fifth switch to the sixteenth inverter output channels 8 or its ninth output through the fifth switch and through the first the entrance channel driver 58 in the ninth channel; switches the first, second, third, fourth, fifth and sixth have a two position switch; a second input transducer of the receiving channels 8 in parallel connected to the second input of each of the ten channel shaper 58.

Figure 6 presents channel driver information 58, where 119, 120, the first and second memory cells, 121, 133 and 134 of the pulse counter, 122, 132, 135 triggers, 123, 124, 125, 126, 127 and 128 - elements And, 129 - item NO, 130, and 131 - adenovirally, 136 - element OR, with the first input channel shaper connected in parallel to the first is th input of the first memory cell 119 through the first input of the fifth element And 127, and to the first input of the second memory cell 120 through the first input of the sixth element And 128; the output of the first memory cell 119 is connected to the input of the third trigger 135, and in parallel to the output channel driver information 58 through the third pulse counter 134 and through the first input element OR 136; the output of the second memory cell 120 is connected to the input of the second trigger 132 and parallel to the outlet channel driver information 58 through the second pulse counter 132 and through the second input element OR 136; the second input of the shaper of information pulses connected to the input of the first flip-flop 122 through the first pulse counter 121; output the first flip-flop 122 is connected in parallel to the second input of the first memory cell 119 through the first input of the first element And 123 and through the first input of the second element And 124 and to the second input of the second memory cell 120 through the first input of the third element And 125 and through the first input of the fourth element And 126; the output of the third trigger 135 connected in parallel to the second inputs of the first element And 123 and the sixth element And 128, and to the second input of the fifth element And 127 through 129 item is NOT; the output of the second trigger 132 is connected to the second input of the third element And 125; the second output of the third the counter 134 is connected in parallel to the third input of the first memory cell 119, and through the first one-shot 130 to the second input of the fourth is of lament And 126; the second output of the second counter 134 is connected in parallel to the third input of the second memory cell 120, and through a second one-shot 131 to the second input of the second element And 124.

Figure 7 presents the transducer data channels 39, containing six channel formers packet data(90, 91, 92, 93, 94 and 95) and the element OR 96, while the sixth and seventh inputs of the Converter data channels 39 is connected to the second and the first input of the first channel driver packet data 90; fifth and eighth inputs of the Converter data channels 39 is connected to the second and the first input of the second channel driver packet data 91; fourth and ninth device inputs data channels 39 is connected to the second and the first input of the third channel driver packet data 92; the third and tenth device inputs data channels 39 is connected to the second and the first input of the fourth channel driver packet data 93; the second and eleventh device inputs data channels 39 is connected to the second and the first input of the fifth channel driver packet data 94; first and twelfth device inputs data channels 39 is connected to the second and the first input of the sixth channel f is reroutes packet data 95; the six outputs of the channel forming packet data transmission is connected to the Converter output data channels 39 through the sixth, fifth, fourth, third, second and first inputs of the element OR 96.

On Fig presents channel driver packet data 90, where the multivibrator 108, two memory cells 109 and 110, elements, And- 97, 98, 99, 100, 101, 102 and 111, the items are NOT 103 and 104, the trigger 105, the element OR 112 and three switch at four positions (LCLUC, LCLUC, Wclac), with the first input channel driver packet data 90 is connected in parallel to the zero contact of the first switch via the first input of the second element And 98 and to the zero contact of the second switch via the first input of the first element And 97; the memory cells of the first 109 and second 110 on four inputs; the first input of each memory cell 1200 Bit memory, the second entrance is 500 Bits of memory, the third entrance is 300 Bits of memory, the fourth entrance on the 1200 Bit memory; the switches of the first and second alternately, sequentially, connect zero contact to the first, second, third or fourth contact, and through them to the first or second, or third, or fourth inputs of the memory cells of the first and second 109 and 110 based on the selected mode of transmission rate transmission channel data: 100 Bps, 300 Bps-500 Bps and 1200 Bps; the output of the first memory cell 109 is connected to the exit to the national driver packet data 90 sequentially through the first input of the fourth element And 100 and through the first input element OR 112; the output of the second memory cell 109 is connected to the output of the channel driver packet data 90 sequentially through the first input of the third element And 99 and through the second input element OR 112; a second input channel driver packet data 90 is connected in parallel to the first input of the sixth element 102 And through the delay line 107 and through the corrector pulse 106 to the input of the trigger 105 and to the zero contact of the third switch; a third switch serially, sequentially connects the zero contact to the first, second, third or fourth contact, and through them to the first or second, or third, or fourth the inputs of the multivibrator 108 based on the selected mode speed channel transmit data: 100 Bps, 300 Bps-500 Bps and 1200 Bps; the output of the multivibrator 108 is connected to the output of the sixth element 102 And via its second input; the output of the sixth element And 102 are connected in parallel to the fifth input of the first memory cell 109 through the first input of the seventh element And 111, and to the fifth input of the second memory cell 110 through the first input of the fifth element 101 And, when connecting the zero contact of the third switch to one of the inputs of the multivibrator 108 is alternately reading data from memory cells 109 and 110 on their fifth input pulses of the multivibrator 108; when connecting a zero account is that to the first input of the multivibrator 108 the latter operates at a frequency of 240 kHz and produces 1200 pulses to eject the information pulses of the memory cells for a period of five milliseconds; when connecting the zero contact to the second input of the multivibrator 108 the latter operates at a frequency of 100 kHz and generates 500 pulses to eject the information pulses of the memory cells for a period of five milliseconds; when connecting the zero contact to the third input of the multivibrator 108 the latter operates at a frequency of 60 kHz and produces 300 pulses to eject the information pulses of the memory cells for a period of five milliseconds; when connecting the zero contact to the fourth input of the multivibrator 108 the latter operates at a frequency of 20 kHz and generates 100 pulses to eject the information pulses of the memory cells for a period of five milliseconds; management of alternate one-second recording information from a channel data in the memory cell and the read channel to the output of the imaging unit 90 performs the trigger 105, synchronized peacemillion pulses on its input; the output of the trigger 105 is connected in parallel to the second inputs of the first element And 97, the fourth element 100 and the seventh element And 111; the output of the trigger 105 is also connected in parallel to the second inputs of the second element And 98 and the third element And 99 through the element is NOT 104 and to the second input of the fifth element And 101 through 103 item is NOT.

Channel driver packet data 91 (Fig.7 and Fig) such channel driver package p is passing data 90, the difference in the operation of the multivibrator 108 for shaper 91, which is synchronized shestielementnaya pulses, so when connecting the zero contact of the third switch to the first input of the multivibrator 108 the latter operates at a frequency of 200 kHz and produces 1200 pulses to eject the information pulses of the memory cells for a period of six milliseconds; when connecting the zero contact to the second input of the multivibrator 108 the latter operates at a frequency of 83 kHz and generates 500 pulses to eject the information pulses of the memory cells for a period of six milliseconds; when connecting the zero contact to the third input of the multivibrator 108 the latter operates at a frequency of 50 kHz and produces 300 pulses to eject the information pulses of the memory cells for a period of six milliseconds; when connecting the zero contact to the fourth input of the multivibrator 108 the latter operates at a frequency of 16 kHz and generates 100 pulses to eject the information pulses of the memory cells for a period of six milliseconds.

Channel driver packet data 92 (Fig.7 and Fig) such fundamentally and functionally channel driver packet data 90, the difference shaper 92 in the operation of the multivibrator 108, which is synchronized seminolecounty pulses, so when connected to the zero contact of the third switch to the first input of the multivibrator 108 the latter operates at a frequency of 170 kHz and produces 1200 pulses to eject the information pulses of the memory cells for a period of seven milliseconds; when connecting the zero contact to the second input of the multivibrator 108 the latter operates at a frequency of 71 kHz and generates 500 pulses to eject the information pulses of the memory cells for a period of seven milliseconds; when connecting the zero contact to the third input of the multivibrator 108 the latter operates at a frequency of 42 kHz and produces 300 pulses to eject the information pulses of the memory cells for a period of seven milliseconds; when connecting the zero contact to the fourth input of the multivibrator 108 the latter operates at a frequency of 14 kHz and generates 100 pulses to eject the information pulses of the memory cells for a period of seven milliseconds.

Channel driver packet data 93 (Fig.7 and Fig) such fundamentally and functionally channel driver packet data 90, the difference of the imaging unit 93 in the operation of the multivibrator 108, which is synchronized vosmerochnyj pulses, so when connecting the zero contact of the third switch to the first input of the multivibrator 108 the latter operates at a frequency of 150 kHz and produces 1200 pulses to eject the information pulses of the memory cells over a period of eight milliseconds; when connecting the zero contact to the second input of the multivibrator 108 the latter operates at a frequency of 62.5 kHz and generates 500 pulses for vital the air traffic management information pulses of the memory cells over a period of eight milliseconds; when connecting the zero contact to the third input of the multivibrator 108 the latter operates at a frequency of 37.5 kHz and produces 300 pulses to eject the information pulses of the memory cells over a period of eight milliseconds; when connecting the zero contact to the fourth input of the multivibrator 108 the latter operates at a frequency of 12 kHz and generates 100 pulses to eject the information pulses of the memory cells over a period of eight milliseconds.

Channel driver packet data transmission 94 (Fig.7 and Fig) such fundamentally and functionally channel driver packet data 90, the difference shaper 94 in the operation of the multivibrator 108, which is synchronized devyatimillimetrovy pulses, so when connecting the zero contact of the third switch to the first input of the multivibrator 108 the latter operates at a frequency of 133 kHz and produces 1200 pulses to eject the information pulses of the memory cells over a period of nine milliseconds; when connecting the zero contact to the second input of the multivibrator 108 the latter operates at a frequency of 55.5 kHz and generates 500 pulses to eject the information pulses of the memory cells over a period of nine milliseconds; when connecting the zero contact to the third input of the multivibrator 108 the latter operates at a frequency of 33.3 kHz and produces 300 pulses is La push information pulses of the memory cells over a period of nine milliseconds; when connecting the zero contact to the fourth input of the multivibrator 108 the latter operates at a frequency of 11 kHz and generates 100 pulses to eject the information pulses of the memory cells over a period of nine milliseconds.

Channel driver packet data 95 (Fig.7 and Fig) such fundamentally and functionally channel driver packet data 90, the difference shaper 95 in the operation of the multivibrator 108, which is synchronized desyatimillionnikov pulses, so when connecting the zero contact of the third switch to the first input of the multivibrator 108 the latter operates at a frequency of 120 kHz and produces 1200 pulses to eject the information pulses of the memory cells for a period of ten milliseconds; when connecting the zero contact to the second input of the multivibrator 108 the latter operates at a frequency of 50 kHz and generates 500 pulses to eject the information pulses of the memory cells for a period of ten milliseconds; when connecting the zero contact to the third input of the multivibrator 108 the latter operates at a frequency of 30 kHz and produces 300 pulses to eject the information pulses of the memory cells for a period of ten milliseconds; when connecting the zero contact to the fourth input of the multivibrator 108 the latter operates at a frequency of 10 kHz and generates 100 pulses d is I eject the information pulses of the memory cells for a period of ten milliseconds.

Concealer pulses 106 presented on figure 9, contains a line of discrete delay 165, the first differentiating chain in the form of a diode D1and resistor R1the second differentiating chain in the form of a diode D2and resistor R2and the trigger 166; at the entrance of the offset pulse 106 is connected in parallel directly to the second differentiating the chain through the diode D2and through resistor R2on the ground and through the line of discrete delay 165 to the second differentiating the chain through the diode D1and through resistor R1on the ground; the output of the diode D2connected in parallel to the first input of the trigger 166; output diode D1connected in parallel to the second input of the trigger 166; output trigger 166 is connected to the output of the offset pulse.

Converter information data channels 16, are presented on figure 10, where 113, 114, 115, 116, 117 and 118 of the channel forming information data, with six inputs from the first to the sixth inverter information data channels 16 are connected to the six outputs of the drive information of the data channels 16 in parallel through the first six inputs channel formers information data from 113 118; the seventh input of the Converter information data channels 16 are connected in parallel to each second input W the particular channel formers information data from 113 through 118.

Channel driver information data 113 figure 11 presents containing the first 137 and 138 second memory cell; 141, 142, 143, 144, 145, 146 - from first to sixth elements And, 147 - item NO, 140, 150 and 153 triggers, 139, 151 and 152 of the pulse counter, 148 and 149 adenovirally; 154 - element OR the first input channel of the driver information data 113 connected in parallel to the zero contact of the first switch via the first input of the fifth element And 145 and to the zero contact of the second switch through the first input of the sixth element And 146; the zero contact of the first switch serially connected to the first contact of the first switch and through him to the first input of the first memory cell 137, the second contact of the first switch and through him to the second input of the first memory cell 137, to the third contact of the first switch and through him to the third input of the first memory cell 137, the fourth contact of the first switch and through him to the fourth input of the first memory cell 137, zero contact of the second switch serially connected to the first contact of the second switch, and through him to the first input of the second memory cell 138 to the second contact of the second switch, and through him to the second input of the second memory cell 138, to the third contact of the second switch, and through him to the third input of the second memory cell 138 to the fourth contact of the second switch, and through him to the fourth input of the second memory cell 138; the output of the first memory cell 137 is connected to the input of the third trigger 153 and parallel to the zero contact of the third switch; zero contact of the third switch alternately connects the switch through the first contact to the first input of the third pulse counter 152; zero contact of the third switch connects the switch through the second contact to the second input of the third pulse counter 152; zero contact of the third switch connects the switch through the third contact to the third input of the third pulse counter 152; zero contact of the third switch connects the switch through the fourth contact to the fourth input of the third pulse counter 152; the first output of the third pulse counter 152 via the first the input element OR 154 is connected to the output of the shaper 113, and the second output of the third counter 152 is connected in parallel to the fifth input of the first memory cell 137 and to the second input of the fourth element And 144 through the first one-shot 148; the output of the second memory cell 138 is connected to the input of the second trigger 150 and parallel to the zero contact of the fourth switch; zero contact of the fourth switch alternately connects the switch through the first contact to the first input of the second pulse counter 151; zero contact of the fourth switch is connected vluchtelingen the second contact to the second input of the second pulse counter 151; the zero contact of the fourth switch connects the switch through the third contact to the third input of the second pulse counter 151; zero contact of the fourth switch connects the switch through the fourth contact to the fourth input of the second pulse counter 151; the first output of the second pulse counter 151 through the second input of the OR element 154 is connected to the output of the shaper 113, and the second output of the second counter 151 is connected in parallel to the fifth input of the second memory cell 138 and to the second input of the second element And 142 through the second one-shot 149; the output of the second trigger 150 is connected to the second input of the third element And 143; the output of the third trigger 153 is connected in parallel to the second input of the first element And 141, to the second input of the sixth element And 146 and through the element is NOT 147 to the second input of the fifth element And 145; the second input channel of the driver information data 113 is connected through a first pulse counter 139 to the zero contact of the fifth switch; zero contact of the fifth switch serially connected to the first or second or third or fourth contacts, the first contact of the first switch connected to the first input of the first flip-flop 140, the second contact of the first switch is connected to the second input of the first flip-flop 140, the third contact of the first switch under the offline to the third input of the first flip-flop 140, the fourth contact of the first switch is connected to the fourth input of the first flip-flop 140; when connected to the first input of the first flip-flop 140 of the output of the first pulse counter 139 at the output of the trigger 140 is created 1200 pulses per second, when the connection of the counter 139 to the second input of the trigger 140 at its output generates 500 pulses per second, when the connection of the counter 139 to the third input of the trigger 140 at its output is created 300 pulses per second, when the connection of the counter 139 to the fourth input of the trigger 140 at its output generates 100 pulses per second; the output of the first flip-flop 140 is connected in parallel to the sixth input of the first cell memory 137 through the first input of the first element And 141 and the first input of the second element And 142, and to the sixth input of the second memory cell 138 through the first input of the third element And 143 and the first input of the fourth element And 144.

The pulse counter 17, presented at Fig contains two resistors (155 and 156), the trigger 157, differential chain 158, the valve element 159 and 160; the first input of the pulse counter 17 is connected in parallel to the first input element And 160 and to the grounded voltage divider consisting of series-connected resistors 155 and 156; the second input of the pulse counter 17 is connected in parallel to the midpoint of the voltage divider of resistors 155 and 156, and through the trigger 157 through on ferentinou chain 158, valve 159 to the second input element And 160, the output element And is connected to the output of the pulse counter 17.

The filter unit 12 provided on Fig, consists of ten channels, each of which contains at reception: filter rejectee 161, band-pass filter 162, the amplifier receiving 163; transmission: power transmission 164, with each of the ten inputs of the receiving channels of the filter unit 12 is connected to the output of the filter block 12 through the filter rejectee 161, band-pass filter 162 and amplifier reception 163; each of the ten inputs of the transmission channels of the filter unit 12 is connected to the ten outputs of the filter unit 12 via the amplifier transfer 164.

The set of essential features of the claimed device provides a station in FH mode full duplex on one antenna at a frequency of ten telephone channels, in addition, six channels: 5, 6, 7, 8, 9 and 10, can be used to transfer data at a rate of 100 Bps, 300 Bps-500 Bps and 1200 Bps to work with data terminal equipment (DTE)and with a speed of 1200 Baud to work in the channels of the PC.

Not known to the authors of the technical solution of radiocommunications, including signs, is equivalent to the distinguishing features of the claimed device. Authors unknown solutions from other fields of technology, with the properties of the proposed technical object izopet the deposits. Thus, the claimed technical solution according to the authors, has the criterion of essential features.

Figure 1 shows the radio station, where 1 is the non-directional antenna 2 - antenna diode capacitive switch, 3 - coaxial cable line, 4 - radio 5 - radio, 6 - power 7 - clock 8 - Converter receiving channels 9 - Converter transmission channels, 10 - block of ten digital to analog converters, 11 - block of ten analog-to-digital converters, 12 - unit filters, 13 - ten remote stations of a radio operator, a 14 - block pseudo-random adjustment of the operating frequency (block hopping, 15 switch, 16 - Converter information data channels.

Figure 2 presents the Converter of the transmission channel 9, where 17 - pulse counter; 18 - delay, continuous tuning from 0 to 100 MS; 19 - line discrete delay (VIPs) for 100 MS; 20 - VIP 200 MS; 21 - VIP 300 MS; 22 - VIP 400 MS; 23 - VIP 500 MS; 24 - VIPs 600 MS; 25 - VIP 700 MS; 26 - VIP 800 MS; 27 - VIP 900 MS; 28, 29, 30, 31, 32, 33, 34, 35, 36 - triggers; 37 - driver information pulse; 38 - item OR; 39 - Converter data channels; 1, 2, 3, 4, 5, 6 - switches; 40 - the element OR.

Figure 3 presents the shaper of information pulses 37, where 41 and 42 of the first and second memory cell; 43, 44, 45, 46, 47, 48, 4 - from the first to the seventh And gates 50 and 51 elements are NOT, 52 - multivibrator 53 - flop 54 - corrector pulse, 55 - item OR.

4 shows the pulse corrector 54, 56 where the line discrete delay for channel 1 MS, for the second channel VIPs at 2 MS, for the third channel VIPs at 3 MS, for the fourth channel VIPs at 4 MS, for the fifth channel VIPs at 5 MS, for a sixth channel VIPs at 6 MS, for the seventh channel VIPs at 7 MS, for the eighth channel VIPs at 8 MS, for the ninth channel VIPs 9 MS for the tenth channel VIPs at 10 MS, differentiating the chain of the elements of the valve - D1and resistor - R1and 57 trigger.

Figure 5 presents Converter receiving channels 8, where 58 - ten channel formers information; 59-1, 59-2, 59-3, 59-4, 59-5, 59-6, 59-7, 59-8, 59-9 - nine items; 60-1, 60-2, 60-3, 60-4, 60-5, 60-6, 60-7, 60-8, 60-9 - nine elements And; 70 - nine items are NOT, 71 - nine delay lines smooth tuning with a delay of one millisecond; 1, 2, 3, 4, 5 and 6 switches for switching operation modes of the phone - data transfer; 61, 62, 63, 64, 65, 66, 67, 68 and 69 triggers that trigger 61 generates as output 2, 3, 4, 5, 6, 7, 8, 9 and 10 MS pulses and does not work from arriving at the first input 1 MS pulse; a trigger 62 generates as output 3, 4, 5, 6, 7, 8, 9 and 10 MS pulses; a trigger 63 generates as output 4, 5, 6, 7, 8, 9 and 10 MS pulses; a trigger 64 generates at the output 5, 6, 7, 8, 9, and 10 MS pulses; Tr is gger 65 generates at the output 6, 7, 8, 9, and 10 MS pulses; a trigger 66 generates at the output 7, 8, 9, and 10 MS pulses; trigger 67 generates output 8, 9, and 10 MS pulses; a trigger 68 generates at the output 9 and 10 MS pulses; a trigger 69 generates output 10 MS pulses.

Figure 6 presents channel driver information 58, where 119, 120, the first and second memory cells; 121, 133 and 134 of the pulse counter; 122, 132, 135 triggers; 123, 124, 125, 126, 127 and 128 - elements; 129 - item NOT; 130 and 131 - adenoviridae; 136 - item OR.

Figure 7 presents the transducer data channels 39, where 90, 91, 92, 93, 94 and 95 - channel formers packet data transmission in the fifth, sixth, seventh, eighth, ninth and tenth channels, 96 - OR element.

On Fig presents channel driver packet data 90, where 109 and 110, the first and second memory cell; 97, 98, 99, 100, 101, 102, 111 - from the first to the seventh And gates 103 and 104 elements do NOT, 108 multivibrator 105 - flop 106 - corrector pulse 107 - smooth line delay; 112 - item OR.

Figure 9 presents the pulse corrector 106, where 165 - delay line, 166 - trigger, the first differentiating the chain of the elements of the valve - D1and resistor R1the second differentiating the chain of the elements of the valve - D2and resistor R2.

Figure 10 presents Converter information data channels 16, where 113, 114, 115, 116, 117 and 118 of the channel formation is eating information data.

Figure 11 presents channel driver information data 113, where 137 and 138, the first and second memory cell; 141, 142, 143, 144, 145, 146 - from first to sixth elements And; 147 - item NOT; 139, 151, 152 with the first through third counters; 140, 150, 153 - the first to the third trigger; 148 149 adenovirally; 154 - item OR.

On Fig presents the pulse counter 17, where 155 and 156 resistors, 157 - flop 158 - differentiating chain, 159 - gate, 160 - item I.

On Fig presents the filter unit 12, where 161 - filter rejectee at 1000 Hz, 162 - bandpass filter with bandwidth 300-2700 Hz, 163 amplifier receiving, 164 - power transmission.

On Fig the logic model of the distribution of the transmitting pulse: newstAndNFNfor N=10 channels, withtAndNF1=1MS for the first channel duration 100 MS,tAndNF2=2MS for the second channel duration 100 MS, etc.

On Fig example temporal distribution of transmission pulses in the firsttthe NF1=1MS and the secondtAndNF2=2MS channels.

The radio station operates as follows.

Before considering the operation of the device, it is expedient to justify the logic model multi-channel radio system with time division mode transfer and channels. To develop a model of such a system introduces the following assumptions:

- each channel of multi-channel stream contains the transmission of one pulse and one pulse at the reception, the pulses are separated by time;

- to improve the noise immunity of the system synchronization when the radio pulse with a duration equal to one millisecond (τThe BEAT=1 MS), the first channel provides synchronization;

- the temporal distance between pulses corresponds to the channel number, in milliseconds, for example, for channel fivetAndNF5=5MS;

pulses for transmission in each channel are information and to enhance their selectivity for each channel, the pulses are correlated across the width, so their duration according to the respectively equal to the channel number in milliseconds, for example, for channel fivetAndNF5=5milliseconds.

Assumptions allow us to build a logic model of the transmission system. In this system the flow of different duration information pulsestAndNFtransmitted time division channels. Each channel is allocated 100 MS (Fig). In each channel, the channel coding is performed on the provisional size of the information pulsetAndNFN. On Fig and Fig the above described model. The information pulses are of different length in each channel so marked as:tAndNF1,tAndNF2,tAndNF3,tAndN F4,tAndNF5,tAndNF6,tAndNF7,tAndNF8,tAndNF9,andtAndNF10.While the duration of each information pulse is determined by the formulatAndNFN=Nt1,where N is the channel number, and τ1- the duration of the information pulse, sound for the first channel or system of communication. The information pulses of the first, second, third, and fourth channels of small duration which, ietAndNF1=1MS,tAndNF2=2MS,tAndNF3=3MS,tAndNF4=4MS will only be used for telephone communication. At the same time taking into account the duration of more than five milliseconds, the information pulses of the fifth, sixth, seventh, eighth, ninth and tenth channels durationtAndNF5=5MS,tAndNF6=6MS,tAndNF7=7MS,tAndNF8=8MS, tAndNF9=9MS andtAndNF10=10MS can be filled with data channels data systems data terminal equipment (DTE) and personal computers (PC). The data rate of the selected six channels substantiated for CCCS: 100 Bps, 300 Bps-500 Bps and 1200 Bps and for PC: 1200 Baud.

Thus, the developed model system logic, able to work ten duplex channels on one frequency on one antenna, and in software mode adjustment of the operating frequency of the radio station at teamwork telephone channels and data channels.

Antenna 1 (Fig 1) using a diode-capacitive switch 2 (for example, a Diode switch, application No. 58-21843, Japan, NR/15) in turn connects to the transmitter 5 and the receiver 4 through the coaxial cable 3. The operation of the antenna diode capacitive switch 2 via the amplifier 6 pulses, synchronized clock 7 through the transducer transmission channels 9. The latter generates transmission pulses with built in information on the channel number and information coming through the analog-to-digital Converter 11, the filter unit 12 with a remote post of operator-operator 13, where the acoustic signal of speech of the operator using the microphone is converted into electrical signals and fed to the amplifier transfer 164 (Fig) of the filter unit 12 (figure 1). Restructuring operating frequency for a given program in the radio transmitter and the radio is via the control unit pseudorandom (software) adjustment of the operating frequency (block poft) 14. Block hopping provides restructuring simultaneously operating frequency of the radio receiver and radio transmitter, and limit the ability of the unit to 100 jumps in frequency per second. The output of block hopping is connected in parallel with the second inputs of the transmitter 5 and the receiver 4, and the wave number that is set in the block 14, is automatically the frequency of the radio wave is set by the block adjustment of the number of waves, and the production numbers of the next wave is a block software management select the number of the working wave for transmission and reception in mode hopping, in block 14 on the touch device is installed, the program sequence change working waves. Modern conditions of technical support allow speed adjustment frequencies up to 100 switches per second. The block is of introw 12 connected ten remote stations radio operator-operator 13, that is, in the filter unit 12 is set ten amplifiers transmission 164. Thus, all ten channels receive gain. The amplified signal of each channel separately and in parallel converted in the analog-to-digital converters 11 (figure 1) into a sequence of pulses, which for each channel is fed into a transmitter of the transmission channel 9, on its inputs, from the first to the tenth. In the Converter of the transmission channels 9 are compressed in time information for transmission in each of the ten channels so that the one-second speech information is transmitted within time set for each channel equal totAndNFN=Nt1,where N is the channel number, and τ1- the duration of the information pulse, sound for the first channel, in milliseconds. And to separate them, at the reception Converter in each channel generates raznoskorostnye information pulses. So for the first channel is formed in one information pulse duration oftAndNF1=1.Temporary layout package size transmitting the pulses of the first channel is represented as: 1 MS. This scheme temporary information of the size of the first channeltPEP1shown in Fig and Fig. At the same time on Fig and Fig shows a diagram of the temporary information amount with respect to the second channeltPEP2as 2 MS. For the third channel will betPEP3- 3 MS, for the fourth channeltPEP4- 4 MS, for the fifth channeltPEP5- 5 MS, for a sixth channeltPEP6- 6 MS for the seventh channeltPEP7- 7 MS, for the eighth channeltPEP8 - 8 MS,tPEP9- 9 MS for the ninth channel for the tenth channeltPEP1010 MS. Each channel is given every second 100 MS (Fig), in which the time to transfer the information packet giventPEPNand the rest of the time on the radiotPPNfor N channel, i.e. the100mwith a=tPEPN+tPPN.

For example, for the fifth channel transmission time is 5 MS and the receiving allocated 95 MS. For the tenth channel time allocated transmission 10 MS, and at the reception - 90 MS. This is not a complication, since the practice allows you to have a separation distance of 2 bits between channels in satellite, radio relay, and cellular communication systems.

Formed and correlated in time packages information pulse is s arrives at the output transducer 9, providing modulation of the transmitter 5 and its connection to the antenna on the package of the pulse amplifier circuit 6 and the antenna diode capacitive switch 2. During the absence on the inverter output transmission channels 9 package information pulses) antenna 1 antenna diode capacitance switch 2 is connected to the input of radio 4, this is the radio pulses corresponding radio station. The output of the receiver 4 receives the packets in a sequence of pulses, which through the first input transducer of the receiving channels 8 are received by the ten channels on the unit d / a converters 10. A Converter receiving channels 8 performs two functions. The first is the selection of the received pulses on channels is a channel selector that selects pulses, using the correlation between the pulses in each channel. The second transformation of the information pulse in a continuous sequence of pulses within each of the ten channels, which is channel driver information. For the first channel and the third is the function - selection of the sync pulse. The duration information of the pulse in each channel is different and is determined by the expressiontAndNF N=Nt1.So in the first channel, the duration of a packet of information pulses is equal totAndNF1=1MS, in the secondtAndNF2=2MS, in the third -tAndNF3=3MS, in the fourthtAndNF4=4MS, in the fifthtAndNF5=5MS, in the sixth -tAndNF6=6MS, in the seventh -tAndNF7=7MS, in the eighth -tAndNF8=8 MS, in the ninth -tAndNF9=9MS, in the tenthtAndNF10=10MS. A continuous sequence of pulses on the ten outputs of the Converter receiving channels 8, digital to analog block is converted to analog information to electrical signals, the last act in his ten channels in the filter unit 12. For each of the ten channels in the filter unit 12 (Fig) created a chain of filter frequency quantization and nonlinear distortion in the frequency band. For rejectio frequency quantization included in each channel filter rejectee 161 at a frequency of 1000 Hz, and for filtering frequencies of 50 Hz is entered bandpass filter 162 and the bandwidth is 300-2700 Hz. The output of the filter 162 is connected amplifier receiving 163, the output of which electrical signals are sent to a remote post of operator-operator 13 in each information channel and further to the speaker (or headphones).

The formation of channels in time is carried out by the Converter transfer channels 9 (2), where each one-second pulse sequence of telephone channels fed to the inputs of C 1 is about 10, converted to a sequence consisting of raznosortnyh packets of information pulses correlated to the duration for a packet of information pulse in each channel. The conversion is as follows. The pulse generator of the quantum 7 (figure 1) with a duration of 1 MS is transmitted through 11 the input of the Converter 9 (2) the pulse counter 17, the last output selects only one pulse per second. This dedicated pulse arrives simultaneously on ten channels through the delay line. In the first channel set the delay line continuous tuning 18, which allows you to delay the pulse at any time in the range from 0 to 100 MS. If this station is older, then the synchronization of the first channel for many radio stations, working together. Synchronization is performed off switch 7 switch ("On") in the first channel delay lines smooth tuning 18, in this case, the pulse from the counter 17 is directly fed to the output driver 9 through 1 input schema OR 49. And on the secondary stations of this momentum, highlighted in the Converter receiving channels 8 (figure 1) and is fed through the switch 15 (BK.) through the twelfth sign of the transducer transmission channels 9 (2), to synchronize the counter 17 to its second input.

Rebuilding the line the delay 18 is smooth (as a delay line, you can use the schema listed in the magazine "Radio" No. 1, 1980, p.60). In the second channel, 1 MS pulse pulse counter 17 is delayed by time in the range from 100 to 200 MS, which provides the shift pulses in the second channel in time, different from the first channel. The delay is discretely 100 MS line discrete delay 19 and smoothly in the range from 100 to 200 MS delay line continuous tuning 18, are connected in series to a discrete delay line 19. The pulse from the counter in the third channel line discrete delay 20 and delay line continuous tuning 18 will be delayed in the range from 200 to 300 MS. The same pulse from the counter 17 in the fourth channel will be delayed in the range from 300 to 400 MS delay lines 18 and 21, and a fifth channel delay lines 18 and 22, the pulse will be in the range from 400 to 500 MS, in the sixth channel delay lines 18 and 23, the pulse will be in the range from 500 to 600 MS, in the seventh channel impulse will be in the range from 600 to 700 MS at the expense of delay lines 18 and 24, in the eighth channel impulse will be in the range from 700 to 800 MS at the expense of delay lines 18 and 25 in the ninth channel impulse will be in the range from 800 to 900 MS at the expense of delay lines 18 and 26, in the tenth channel impulse will be in the range from 900 to 1000 MS at the expense of delay lines 18 and 27. Thus, the delay lines 18, 19, 20, 21, 22, 23, 24. 25, 26 and 27 is provided by the arrangement MS pulse, coming from the output of the pulse counter 17, in each second time in ten channels with a time interval between pulses is about 100 MS.

However, logic models communication system radio station (Fig and Fig) forms in each channel one packet of information pulses, raznochintsy or correlated to the duration in time of service, defined astAndNFN=Nt1.

So in the first channel of the first pulse generator 7 with a duration of 1 MS is supplied to the inverter output 9 output of the first delay line continuous tuning 18 via the first input of the shaper information packages pulses 37, through the first input circuit OR 38, through the first input element OR 40. The imaging unit 37 in the first channel creates one information packet of pulses with a duration of 1 MS and the packet received at the output of the Converter 9, is the first information packet in a given second. Driver information package 37, without changing the duration of 1 MS pulse received on its first input, generates or contributes by compression in the momentum one-second information on the second input of the shaper 37 through the first input transducer is of analy transmission 9.

In the second channel simultaneously and in parallel for all channels, 1 MS clock pulse from the output of the counter 17, the last in the second channel through the line 18 passes through the second line of discrete delay 19 on the trigger 28. This 1 MS pulse starts the trigger 28 and the output trigger appears dvukhelementnye pulse, which is supplied to the first input of the shaper information package pulse 37. Driver information package 37, without changing the duration of 2 MS pulse received on its first input, generates information dvukhelementnye package by introducing subsequent compression of one-second information received by the second input of the shaper 37 through the second input to the Converter of the transmission channel 9. The output of the imaging unit 37 via the second input of the OR element 38 and the first input of the OR element 40 is connected to the Converter output channel 9. Therefore, at the output of the Converter 9, a second information packet with duration of two milliseconds, formed in the second channel.

In the third channel, simultaneously and in parallel for all channels, 1 MS clock pulse from the output of the counter 17, the last in the third channel through the line 18 passes through the second line of discrete delay 20 on the trigger 29. This 1 MS pulse starts the trigger 29 and the output of the trigger occurred which raised the pulse of three milliseconds, which is supplied to the first input of the shaper information package pulse 37. Driver information package 37, without changing the duration of 3 MS pulse received on its first input, generates an information package with duration of three milliseconds by introducing subsequent compression of one-second information received by the second input of the shaper 37 through the third input of the Converter of the transmission channel 9. The output of the imaging unit 37 via the third input of the OR element 38 and the first input of the OR element 40 is connected to the Converter output channel 9. Therefore, at the output of the Converter 9 receive third information packet with duration of three milliseconds, formed in the third channel.

In the fourth channel, simultaneously and in parallel for all channels, 1 MS clock pulse from the output of the counter 17, the last in the fourth channel through the line 18 passes through the second line of discrete delay 21 on the trigger 30. This 1 MS pulse starts the trigger 30 and the output trigger pulse appears with a duration of four milliseconds, which is supplied to the first input of the shaper information package pulse 37. Driver information package 37, without changing the duration of 4 MS pulse received on its first input, generates an information packet duration, look no further than the millisecond by introducing subsequent compression of one-second information, received on the second input of the shaper 37 via the fourth input of the Converter of the transmission channel 9. The output of the imaging unit 37 via the fourth input of the OR element 38 and the first input of the OR element 40 is connected to the Converter output channel 9. Therefore, at the output of the Converter 9, a fourth information package with duration of four milliseconds, formed in the fourth channel.

In the fifth channel, simultaneously and in parallel for all channels, 1 MS clock pulse from the output of the counter 17, the last in the fifth channel through the line 18 passes through the second line of discrete delay 22 to the trigger 31. This 1 MS pulse starts the trigger 31 and the output trigger pulse appears with a duration of five milliseconds, which enters through the sixth switch is in its first terminal to the sixth input of the Converter data channels 39, and the second terminal is at the first input of the shaper information package pulse 37. The sixth mode of the switch is determined by the appropriateness of the selection operation of the channel as the call channel by the imaging unit 37 or as a data bearer connection to the inverter data channels 39. Driver information package 37, without changing the duration of 5 MS pulse received on its first input, generates information paketdienst five milliseconds by introducing subsequent compression of one-second information, received on the second input of the shaper 37 through the fifth input of the Converter of the transmission channel 9. The output of the imaging unit 37 through the fifth input of the OR element 38 and the first input of the OR element 40 is connected to the Converter output channel 9. Therefore, at the output of the Converter 9 appears fifth information package with duration of five milliseconds, formed in the fifth telephone channel. In the case of the fifth channel is a data channel, the pulse duration of five milliseconds, coming on the sixth input of the Converter data channels 39, forms a fifth information package one second information according to the seventh input of the Converter 39 through the eighteenth Converter input transmission channels 9. Patibility information packet data arrives at the inverter output data channels 39 and through the eighth switch via the second input of the OR element 40 is supplied to the inverter output of the transmission channel 9.

In the sixth channel, simultaneously and in parallel for all channels, 1 MS clock pulse from the output of the counter 17, the last in the sixth channel through the line 18 passes through the second line of discrete delay 23 on the trigger 32. This 1 MS pulse starts the trigger 32 and the output of the trigger 32 receive a pulse duration of five milliseconds, to whom that flows through the fifth switch is in its first terminal to the fifth input of the Converter data channels 39, and the second terminal is at the first input of the shaper information package pulse 37. The fifth mode of the switch is determined by the appropriateness of the selection operation of the channel as the call channel by the imaging unit 37 or as a data bearer connection to the inverter data channels 39. Driver information package 37, without changing the duration of 6 MS pulse received on its first input, generates an information package with duration of six milliseconds by introducing subsequent compression of one-second information received by the second input of the shaper 37 through the sixth input of the Converter of the transmission channel 9. The output of the imaging unit 37 via the sixth input of the OR element 38 and the first input of the OR element 40 is connected to the Converter output channel 9. Therefore, at the output of the Converter 9 appears sixth information package with duration of six milliseconds, formed in the sixth telephone channel. In the case of the sixth channel as a data channel, the pulse duration of six milliseconds, coming on the fifth input of the Converter data channels 39, forms a sixth information package one second information according to the eighth input of the Converter 39 through the seventeenth Converter input transmission channels 9. The pole is millisecond information packet data arrives at the inverter output data channels 39 and through the eighth switch via the second input of the OR element 40 is supplied to the inverter output channels transmission 9.

In the seventh channel, simultaneously and in parallel for all channels, 1 MS clock pulse from the output of the counter 17, the last in the seventh channel through the line 18 passes through the second line of discrete delay 24 to the trigger 33. This 1 MS pulse starts the trigger 33 and the output of the trigger 33 receive a pulse of seven milliseconds, which enters through the fourth switch is in its first terminal to the fourth input of the Converter data channels 39, and the second terminal is at the first input of the shaper information package pulse 37. The fourth mode of the switch is determined by the appropriateness of the selection operation of the channel as the call channel by the imaging unit 37 or as a data bearer connection to the inverter data channels 39. Driver information package 37, without changing the duration of 7 MS pulse received on its first input, generates an information package with duration of seven milliseconds by introducing subsequent compression of one-second information received by the second input of the shaper 37 through seventh input of the Converter of the transmission channel 9. The output of the imaging unit 37 through the seventh input of the OR element 38 and the first input of the OR element 40 is connected to the Converter output channel 9. Therefore, at the output of the conversion is the user 9 appears seventh information package lasting seven milliseconds, formed in the seventh telephone channel. In the case of the seventh channel as a data channel, the pulse duration of seven milliseconds, received on the fourth input of the Converter data channels 39, forms the seventh information package one-second information received by the ninth input of the Converter 39 through the sixteenth to the input of the Converter of the transmission channel 9. Seminolecounty information packet data arrives at the inverter output data channels 39 and through the eighth switch via the second input of the OR element 40 is supplied to the inverter output of the transmission channel 9.

In the eighth channel, simultaneously and in parallel for all channels, 1 MS clock pulse from the output of the counter 17, the last in the eighth channel through the line 18 passes through the second line of discrete delay 25 on the trigger 34. This 1 MS pulse starts the trigger 34 and the output of the trigger 34 receive the pulse eight milliseconds, which flows through the third switch is in its first terminal to the third input of the Converter data channels 39, and the second terminal is at the first input of the shaper information package pulse 37. The third mode of the switch is determined by the appropriateness of the selection operation of the channel as the call channel is formed through which the user 37 or as a data bearer connection to the inverter data channels 39. Driver information package 37, without changing the duration of 8 MS pulse received on its first input, generates an information package with duration of eight milliseconds by introducing subsequent compression of one-second information received by the second input of the shaper 37 through eighth input of the Converter of the transmission channel 9. The output of the imaging unit 37 through eighth input of the OR element 38 and the first input of the OR element 40 is connected to the Converter output channel 9. Therefore, at the output of the Converter 9 appears eighth information package with duration of eight milliseconds, formed in the eighth telephone channel. In the case of the eighth channel as a data channel, the pulse-eight milliseconds, received by the third input of the Converter data channels 39, forms the eighth information package one-second information received by the tenth input of the Converter 39 through the fifteenth to the input of the Converter of the transmission channel 9. Vosmitysyachny information packet data arrives at the inverter output data channels 39 and through the eighth switch via the second input of the OR element 40 is supplied to the inverter output of the transmission channel 9.

In the ninth channel, simultaneously and in parallel, as in all Cana who am, 1 MS clock pulse from the output of the counter 17, the last in the ninth channel through the line 18 passes through the second line of discrete delay 26 on the trigger 35. This 1 MS pulse starts the trigger 35 and the output of the trigger 35, you receive the pulse at nine milliseconds, which enters through the second switch is in its first terminal to the second input transducer data channels 39, and the second terminal is at the first input of the shaper information package pulse 37. The mode of the second switch is determined by the appropriateness of the selection operation of the channel as the call channel by the imaging unit 37 or as a data bearer connection to the inverter data channels 39. Driver information package 37, without changing the duration of 9 MS pulse received on its first input, generates an information package with duration of nine milliseconds by introducing subsequent compression of one-second information received by the second input of the shaper 37 through ninth input of the Converter of the transmission channel 9. The output of the imaging unit 37 through ninth input of the OR element 38 and the first input of the OR element 40 is connected to the Converter output channel 9. Therefore, at the output of the Converter 9 appears ninth information package with duration of nine milliseconds,formed in the ninth telephone channel. In the case of the ninth channel as a data channel, the pulse of nine milliseconds, input by the second input transducer data channels 39, forms a ninth information package one-second information received by the eleventh input of the Converter 39 through the fourteenth input to the Converter of the transmission channel 9. Devyatimillimetrovy information packet data arrives at the inverter output data channels 39 and through the eighth switch via the second input of the OR element 40 is supplied to the inverter output of the transmission channel 9.

In the tenth channel, simultaneously and in parallel for all channels, 1 MS clock pulse from the output of the counter 17, passed in the tenth channel through the line 18 passes through the second line of discrete delay 27 on the trigger 36. This 1 MS pulse starts the trigger 36 and the output of the trigger 36 receive a pulse duration of ten milliseconds, which is supplied via the first switch is in its first terminal to the first input transducer data channels 39, and the second terminal is at the first input of the shaper information package pulse 37. The mode of the first switch is determined by the appropriateness of the selection operation of the channel as the call channel by the imaging unit 37 or as bearer Yes the data connection to the inverter data channels 39. Driver information package 37, without changing the duration in 10 MS pulse received on its first input, generates an information package with duration of ten milliseconds by introducing subsequent compression of one-second information received by the second input of the shaper 37 through tenth the input of the Converter of the transmission channel 9. The output of the imaging unit 37 through the tenth input element OR 38 and the first input of the OR element 40 is connected to the Converter output channel 9. Therefore, at the output of the Converter 9 appears tenth information package with duration of ten milliseconds, formed in the tenth telephone channel. In the case of the tenth channel as a data channel, the pulse duration of ten milliseconds, received by the first input transducer data channels 39, forms a tenth of the information package one-second information received by the twelfth to the input of the Converter 39 through the thirteenth input of the Converter of the transmission channel 9. Desyatitysyachnyj information packet data arrives at the inverter output data channels 39 and through the eighth switch via the second input of the OR element 40 is supplied to the inverter output of the transmission channel 9.

The formation of information pulses is carried out in which romeroville information pulse 37 (figure 3). To the second input of the shaper information pulse 37 receives a pulse duration of 1 MS, and each channel its own. This momentum provides synchronization trigger multivibrator 53 and 52. Simultaneously, the pulse duration of 1 MS arrives at the first input of the sixth element And 48 through the pulse corrector 54, which ensures the passage through it of fifty 20 µs pulse from multivibrator 52 only during his action, i.e. 1 MS and only for the first channel. Synchronized 1 MS pulse GTI trigger 53 operates in standby mode and generates a one-second pulses, alternately connecting the first and second cells 41 and 42 through the first and third elements 43 and 45 to the information channel according to the first input of the shaper information pulse 37, which provides alternating one-second recording of information in each memory cell. To provide a consistent user experience and continuous receipt of information in the memory cell between the trigger 53 and the first element And 43 included the first element is NOT 51. Recorded in the memory information is read in the first channel to the modulator of the transmitter for 1 MS, the second channel is 2 MS, the third is 3 MS, the fourth is 4 MS, the fifth is 5 MS, in the sixth for 6 MS, in the seventh - 7 MS, in the eighth - 8 MS, in the ninth for 9 MS, the tenth is 10 MS. Reading occurs following the m way. Synchronization of the offset pulse is a pulse received on the second input of the shaper 37. In the first channel multivibrator 52 creates fifty pulses with a duration of 20 μs each, supplied to the second input of the sixth element And 48, and their synchronization occurs through the pulse corrector 54 on the first input of the sixth element And 48 pulse duration of 1 MS. In the second channel multivibrator 52 creates fifty pulses with a duration of 40 μs each, supplied to the second input of the sixth element And 48, and their synchronization occurs through the pulse corrector 54 on the first input of the sixth element And 48 pulse duration of 2 msec. In the third channel multivibrator 52 creates fifty pulses with a duration of 60 μs each, supplied to the second input of the sixth element And 48, and their synchronization occurs through the pulse corrector 54 on the first input of the sixth element And 48 pulse duration of 3 MS. In the fourth channel multivibrator 52 creates fifty pulses with a duration of 80 μs each, supplied to the second input of the sixth element And 48, and their synchronization occurs through the pulse corrector 54 on the first input of the sixth element And 48 pulse duration of 4 MS. In the fifth channel multivibrator 52 creates fifty pulses of duration 100 μs each, supplied to the second input of the first cell battery (included) the TA And 48, and their synchronization occurs through the pulse corrector 54 on the first input of the sixth element And 48 pulse duration of 5 MS. In the sixth channel multivibrator 52 creates fifty pulses of 120 μs each, supplied to the second input of the sixth element And 48, and their synchronization occurs through the pulse corrector 54 on the first input of the sixth element And 48 pulse duration of 6 milliseconds. In the seventh channel multivibrator 52 creates fifty pulses of 140 μs each, supplied to the second input of the sixth element And 48, and their synchronization occurs through the pulse corrector 54 on the first input of the sixth element And 48 pulse duration of 7 msec. In the eighth channel multivibrator 52 creates fifty pulses of 160 μs each, supplied to the second input of the first of the sixth element And 48, and their synchronization occurs through the pulse corrector 54 on the first input of the sixth element And 48 pulse duration of 8 MS. In the ninth channel multivibrator 52 creates fifty pulses with a duration of 180 μs each, supplied to the second input of the sixth element And 48, and their synchronization occurs through the pulse corrector 54 on the first input restowage element And 48 pulse duration of 9 msec. In the tenth channel multivibrator 52 creates fifty pulses of 200 μs each, do them to the second input of the sixth element And 48, and their synchronization occurs through the pulse corrector 54 on the first input of the sixth element And 48 pulse duration of 10 MS.

The correction pulse 54 (figure 4) produces a correction of a batch of 50 pulses of 20 msec of multivibrator 52, passed through the sixth element And 48 in the first channel, providing in duration at the output of the shaper 37 package information impulse transmission to the first channel in one millisecond. The incoming pulse in each channel raznochintsy to the input of the corrector 54 is delayed by the delay line 56 in time by an amount agreed for simultaneous operation or running multivibrator 52. Next pulse arrives at the input of the differentiating network consisting of a valve D1and resistor R1that highlights the positive momentum generated by the front edge of the pulse received on the second input of the shaper 37, and a negative pulse generated by the rear edge of the pulse at the input of the driver 37. In this case, the resistor R1stands a positive pulse front time pulse, which triggers the trigger 57. Stop trigger 57 is a negative pulse which appears across the resistor R1when the trailing edge of the pulse. Thus, the trigger 57 output recreates the pulse duration grounded for Yes the aqueous channel tAndNFN=Nt1,where N is the channel number, and τ1- the duration of the information pulse, sound for the first channel, in milliseconds.

At the same time, analog-to-digital Converter unit 11 performs the quantization of the speech signal with a frequency of 50 Hz. Because the capacitance of the memory cells 41 and 42 is designed to record 50 pulses of verbal information. To read data stored in the first memory cell 41, fifty pulses of the multivibrator 52 is received on the second input of the memory cell 41 via the second input of the sixth element And 48 and through the first input of the fourth element And 46. And for reading data stored in the second memory cell 42, fifty pulses of the multivibrator 52 is received on the second input of the memory cell 42 through the second input of the sixth element And 48 and through the first input of the fifth element And 47. Reading of information is the output of the imaging unit 37 through the output of the first memory cell 41, through the first input of the seventh element And 49 and through the first input element OR 55. Reading of information is the output of the imaging unit 37 from the output of the second memory cell 42, through the first input of the second element And 44 and through a second input of the OR element 55. This fifty pulses m is levibreton 52 are one of the elements And 46 or 47 to the memory cell, which is filled with information, and the trigger 53 is disconnected from her information input channel, i.e. the first input of the shaper 38, and an entry is made in the opposite memory. Moreover, the elements 46 and 47 are opened by the trigger 53 alternately, since the element 46 is connected directly to the output of the trigger 53 and the element And 47 through the second element 50.

The connection of the outputs of the memory cells 41 and 42 is alternately, if the cell is being recorded, then the output should not be information, because at this time is read from the other memory cell. Therefore, the second and seventh elements 44 and 49 are connected to the opposite signals trigger 53, item And 49 directly to the output of the trigger 53 and the element 44 through the element is NOT 51. Elements 44 and 49 missing information packets of pulses to the second and first inputs OR 55 and further to the output driver 38, and the duration information of the pulses in each of the ten channels different from 1 MS to 10 MS (i.e. in accordance with the formulatAndNFN=Nt1,wheretAndNFN- duration information to them is the pulse for the N channel, N is the channel number from the first to the tenth, τ1- pulse width clock or the first channel, 1 MS). Thus, the entry in the cell is on the second information in the form of 50 pulses from the analog-to-digital Converter 11, and the reading of these pulses in each channel different pulses from 20 μs to 200 μs, i.e. in accordance with the expressiontAndNFN/50=tMYLBTAndBPAndTAboutPAnd.

Data reception is carried out as follows. The output signal of the radio 4 (figure 1) are fed to the first input of the Converter receiving channels 8, in which the analysis of pulse packets with their distribution according to the ten channels independently of each channel in time and the transformation of the information pulse in a continuous sequence at the output of each channel (figure 5). A Converter receiving channels 8 has ten phone output channels (outputs 1 through 10), each of which is connected to a digital to analog Converter block 10 (Fig 1). In addition, the Converter receiving channels 8 has six outputs (from the twelfth through the seventeenth), which are the channels of transmission of the data is, which are connected to six inputs of the Converter information data channels 16 (figure 1). According to the first input of the Converter 8 receives every second ten packets of pulses correlated to the duration in each of the 10 channels), which are in parallel Converter receives ten channels through breeding packages. Let the first input receives the first of the ten packet duration in millisecond. Package onemillisecond is supplied simultaneously to the input of the first flip-flop 61 and to the input of the delay line 71, and a line parallel to the first input of the first element And the 60-1 and the first input of the second element And 59-1. If the first trigger 61 from onemillimeter pulse at its input does not start, then the output of the trigger 61 no voltage. No voltage at the output of the first flip-flop 61 detects no voltage on the second input of the first element And 60-1, which does not allow the first onemillisecond package to pass through this element 60-1 and then in the subsequent channels. This means that in the subsequent channels first onemillisecond package to do will never be. In addition, the trigger output is 61 connected in parallel to the input of the inverter element 70, therefore, no voltage at the input of inverter 70 will allow you to create the inverter output voltage, which will create once esaudi signal at the second input of the second element 59-1 And for the first onemillimeter package through the element 59-1 And to the first input of the shaper information 58 of the first telephone channel. After conversion onemillimeter packet shaper 58 in a continuous sequence on the first output transducer 8 will see the information of the first telephone channel. For synchronization arrangement of transmitting packets in Converter of the transmission channel 9, the output of the second element 59-1 And connected in parallel to the eleventh inverter output channels 8. The trigger 61 is started from the second and subsequent batches, i.e. other than the first, so the pulses of the first flip-flop 61 is received by the second input element And 60-1, pass from the second to the tenth of information packets through the first input element 60-1 And the second channel. At the same time the voltage of the trigger 61 is supplied through the inverter element is NOT 70 according to the second input of the second element And 59-1, is a ban on a pass from the second to the tenth of information packages.

Thus, at the output of the second element 60-1 And receive all the information packets from the second to tenth. The second channel is similar to the first channel. The second packet at the output of the element 60-1 And passes through the delay line 71 in parallel to the first inputs of the third and fourth elements And 60-2 and 59-2, and also to the input of the trigger 62. From the second package, the second trigger 62 is not triggered, the output of the trigger 62 voltage n is t, because there is no enabling pulse at the second input element And 60-2 on the second passage of the package through the element And 60-2, at the same time inversion element 70 through the second input of the fourth element And 59-2 are skipping the second packet to the output element And 59-2 to the first input of the second driver information pulses 58 and via its output to the second inverter output channels 8. The second trigger 62 is triggered from the third to the tenth packet of pulses and its output voltage shall pass from the third to the tenth of information packets through the third element And 60-2 in the third channel with simultaneous ban passes from the third to the tenth packages inversion voltage of the second trigger 62 element 70 according to the second input of the fourth element And 59-2. Thus, in the third channel output element And 60-2 receives information packets from the third to the tenth.

The third channel is similar to the first and second channels. The third package on the output element And 60-2 is supplied through the delay line 71 in parallel to the first inputs of the fifth and sixth elements And 60-3 and 59-3, and also to the input of the trigger 63. From the third packet is the third trigger 63 is not triggered, the output of the trigger 63 there is no voltage because there is no enabling pulse at the second input element And 60-3 at the third passage of the package through the element is 60-3, at the same time inversion element 70 through the second input of the sixth element And 59-3 is skipping the third packet to the output element And 59-3 at the first input of the third driver information pulses 58 and via its output to the third inverter output channels 8. The third trigger 63 is triggered from the fourth to the tenth packet of pulses and its output voltage shall pass from the fourth to the tenth of information packets through the fifth element And 60-3 in the fourth channel with simultaneous ban passes from the fourth to the tenth packages inversion voltage of the third trigger 63 element 70 according to the second input of the sixth element And 59-3. Thus, in the fourth channel output element And 60-3 receives information packets from the fourth to the tenth.

The fourth channel is similar to the first, second and third channels. The fourth information packet on the output element And 60-3 passes through the delay line 71 in parallel to the first inputs of the seventh and eighth elements And 60-4 and 59-4, and also to the input of the fourth flip-flop 64. From the fourth package, trigger 63 is not triggered, the output of the trigger 64 there is no voltage because there is no enabling pulse at the second input element And 60-4 on the fourth passage of the package through the element And 60-4, at the same time inversion element 70 through Vtorovo eighth element And 59-4 is skipping the fourth packet to the output element And 59-4 at the first input of the fourth driver information pulses 58 and via its output to the fourth inverter output channels admission 8. The trigger 64 is triggered from the fifth to the tenth packet of pulses and its output voltage shall pass from the fifth to the tenth of information packets through the seventh element And 60-4 in the fifth channel with simultaneous ban passes from the fifth to the tenth packages inversion voltage of the fourth flip-flop 64 element 70 according to the second input of the eighth element And 59-4. Thus, in the fifth channel on the output element And 60-4 receives information packets from the fifth to the tenth.

The fifth channel is similar to the previous channel. The fifth information packet on the output element And 60-4 passes through the delay line 71 in parallel to the first inputs of the ninth and tenth elements And 60-5 and 59-5, and also to the input of the fifth trigger 65. From the fifth packet, the trigger 65 is not triggered, the output of the trigger 65 there is no voltage because there is no enabling pulse at the second input element And 60-5 on the fifth passage of the package through the element And 60-5, at the same time inversion element 70 through the second input of the tenth element And 59-5 is skipping the fifth packet to the output element And 59-5 at the first input of the fifth driver information pulses 58 and via its output to the fifth inverter output channels 8. The trigger 65 is triggered from the sixth to the tenth packet of pulses and its output voltage shall skip the SC from the sixth to the tenth of information packets through the ninth element And 60-5 in the sixth channel with simultaneous ban passes from the sixth to the tenth packages inversion voltage of the fifth trigger 65 element 70 according to the second the entrance of the tenth element And 59-5. Simultaneously, the output of the tenth element And 59-5 connected to the first switch at two positions, with the switch through a first position connects the output element And 59-5 for the twelfth output Converter receiving 8, and through the second position of the switch to the first input of the fifth imaging unit 58. Thus, in the sixth channel at the output of the ninth element And 60-5 receives information packets from sixth to tenth.

The sixth channel is similar to the previous channel. The sixth information packet on the output element And 60-5 passes through the delay line 71 in parallel to the first inputs of the eleventh and twelfth items And 60-6 and 59-6, and also to the input of the sixth trigger 66. From the sixth package, the trigger 66 is not triggered, the output of trigger 66 there is no voltage because there is no enabling pulse at the second input element And 60-6 on the sixth passage of the package through the eleventh element, And 60-6, at the same time inversion element 70 through the second input of the twelfth element I-6 is the sixth pass the packet to the output element And 59-6 at the first input of the sixth driver information pulses 58 and via its output to the sixth inverter output channels 8. The trigger 66 is triggered from the seventh to the tenth packet of pulses and its output voltage provides the PCC is to from the seventh to the tenth of information packets through the eleventh element, And 60-6, in the seventh channel with simultaneous ban passes from the seventh to the tenth packages inversion voltage of the sixth trigger 66 item NO 70 the second input of the twelfth element And 59-6. Simultaneously, the output of the twelfth element And 59-6 connected to the second switch at two positions, with the switch through a first position connects the output element And 59-6 to the thirteenth output Converter receiving 8, and through the second position of the switch to the first input of the sixth shaper 58. Thus, in the seventh channel at the output of the eleventh element And 60-6 receives information packets from the seventh through the tenth.

The seventh channel is similar to the previous channel. The seventh information packet on the output element And 60-6 passes through the delay line 71 in parallel to the first inputs of the thirteenth and fourteenth elements And 60-7 and 59-7, and also to the input of the seventh trigger 67. From the seventh package trigger 67 is not triggered, the output of the trigger 67 there is no voltage because there is no enabling pulse at the second input element And 60-7 on the seventh passage of the package through the thirteenth element And 60-7, at the same time inversion element 70 through the second input of the fourteenth element And 59-7 is the seventh pass the packet to the output element And 59-7 to the first input of the seventh driver information pulses 58 and via its output to the seventh inverter output channels 8. The trigger 67 is triggered from the eighth to the tenth packet of pulses and its output is dnim voltage shall pass from the eighth to the tenth of information packets through the thirteenth element And a 60-7 in the eighth channel with simultaneous ban passes from the eighth to the tenth packages inversion voltage the seventh trigger 67 element 70 according to the second input of the fourteenth element And 59-7. Simultaneously, the output of the fourteenth element And 59-7 connected to the third switch at two positions, with the switch through a first position connects the output element And 59-7 to the fourteenth to the output of the inverter receiving 8, and through the second position of the switch to the first input of the seventh shaper 58. Thus, in the eighth channel at the output of the thirteenth element And 60-7 receives information packets from the eighth through the tenth.

The eighth channel is similar to the previous channel. The eighth information packet on the output element And 60-7 passes through the delay line 71 in parallel to the first inputs of the fifteenth and sixteenth elements And 60-8 and 59-8, and also to the input of the eighth trigger 68. From the eighth package of the trigger 68 is not triggered, the output of trigger 68 there is no voltage because there is no enabling pulse at the second input element And 60-8 at the eighth passage of the package through the fifteenth element And 60-8, at the same time inversion element 70 through the second input of the sixteenth element And 59-8 is the eighth pass the packet to the output element And 59-8 to the first input of the eighth driver information pulses 58 and via its output to the eighth inverter output channels 8. The trigger 68 is triggered from deviator is up to ten packets of pulses and its output voltage shall pass from the ninth to the tenth of information packets through the fifteenth element And 60-8 in the ninth channel with simultaneous ban passes from the ninth until the tenth packages inversion voltage of the eighth trigger 68 element 70 according to the second input of the sixteenth element And 59-8. Simultaneously, the output of the sixteenth element And 59-8 connected to the fourth switch at two positions, with the switch through a first position connects the output element And 59-8 to the fifteenth output Converter receiving 8, and through the second position of the switch to the first input of the eighth shaper 58. Thus, in the ninth channel at the output of the fifteenth element And 60-8 receives information packets from the ninth to tenth.

The ninth channel is similar to the previous channel. The ninth information packet at the output of the eighth element And 60-8 passes through the delay line 71 in parallel to the first inputs of the seventeenth and eighteenth elements And 60-9 and 59-9, and also to the input of the ninth trigger 68. From the ninth package trigger 69 is not triggered, the output of trigger 68 there is no voltage because there is no enabling pulse at the second input element And 60-9 on the ninth passage of the package through the seventeenth element And 60-9, at the same time inversion element 70 through the second input of the eighteenth item And 59-9 is the ninth pass the packet to the output element And 59-9 at the first input of the ninth driver information pulses 58 and via its output to the ninth output of Preobrazovatel the receiving channels 8. The trigger 69 is triggered from the tenth pulse and its output voltage shall pass the tenth information package through the seventeenth element And 60-9 in the tenth channel with simultaneous ban passes tenth inversion voltage of the ninth trigger 69 element 70 according to the second input of the eighteenth item And 59-9. Simultaneously, the output of the eighteenth item And 59-9 connected to the fifth switch at two positions, with the switch through a first position connects the output element And 59-9 to the sixteenth to the output of the inverter receiving 8, and through the second position of the switch to the first input of the ninth shaper 58. Thus, in the tenth channel at the output of the seventeenth element And 60-9 enters the tenth information package.

The tenth information packet from the output of the seventeenth element And 60-9 arrives at the sixth switch two position, with the switch through a first position connects the output element And 60-9 to the seventeenth to the output of the inverter receiving 8, and through the second position of the switch to the first input of the tenth shaper 58 and via its output to the tenth inverter output channels 8. The delay line 71 in each channel allows for coordinated operation of the trigger element 60.

Thus, the correlated information pulses in time according to the current 1 MS, 2 MS, 3 MS, 4 MS, 5 MS, 6 MS 7 MS 8 MS 9 MS 10 MS through channel selector (each channel) and will be available separately and in parallel on the input channel formers information 58 (every channel) and through the formers will be available on the outputs 1, 2, 3, 4, 5, 6, 7, 8, 8, 9, 10 Converter 8 (figure 5). To synchronize the work of ten channel formers information 58 of the transducer receiving channels 8 second input of the inverter 8 is connected in parallel to the second inputs of each of the ten shaper 58.

Channel driver information 58 figure 6 and consists of first and second memory cells 119 and 120, in which, by means of the elements And 127 and 128, and 129 item is NOT managed by the second and third flip-flops 132 and 135, alternately recording information packets of pulses in each of the ten channels. Triggers 135 and 132 provide signal when filling memory cells 119 and 120, and the recording in the memory cell is performed with the speed of delivery of information for 1 MS in the first channel (the second channel for 2 MS, the third is 3 MS, the fourth is 4 MS, the fifth is 5 MS, in the sixth for 6 MS, in the seventh - 7 MS, in the eighth - 8 MS, in the ninth for 9 MS, the tenth - 10 MS), and the reading is the same for all channels per second. The operation of each channel of the driver information 58 is the same in each channel. From gene the operator 7 (1) clock pulses of 1 MS is received on each of the second input channel driver information 58. These pulses pass through the first pulse counter 121 (6), which allocates sync under 1:10 so that each tenth pulse enables the launch of the first flip-flop 122, which gives the scheme of the readout pulses with a frequency of 50 Hz. Pyatidesyatimetrovy pulses are received at the second inputs of the memory cells 119 and 120 through the control system, which for each of the memory cells consists of two schemes I. for Example, the first memory cell 119 this will be the second 123 and 124 fourth elements And. the Pulses of the read pass the first element And 123, if the third trigger 135 provided the alarm about the completion of the first memory cell 119, but since reading and writing are separated by time, then read from the memory 119 is performed after a read from the second memory cell 120. The end of reading of the memory cell 120 is indicated by a pulse of the second pulse counter 133 after passing through a 50 pulse data stored in the memory 120. When this pulse of one-shot 131 provides the passage of the pulses of the first flip-flop 122 through the element And 124 and start reading from the memory 119, and the end of reading, is signaled by the pulse counter 134, the pulse which through the third input of the memory cell 119 produces its zeroing and further through the one-shot 130 (Ovechkin M.A. Love the Yelsk TV games, 2 edition, M.: Radio and communication, 1989) and the element And 126 gives permission to read from the second memory cell 120. At the same time, the third trigger 135 after zeroing cell 119 permits through the elements NOT 129 and 127 passing the next information pulse in the cell 119 through the first input channel shaper 58. Scheme OR 135 coordinate data output of the sequential cells 119 and 120, and also ensures continuity in the delivery of this information to the output channel driver information 58 to enter it in the unit d / a converters 10 in each channel (figure 1). The ten outputs of the channel formers 58 in the transducer receiving 8 form the ten outputs of the Converter 8, respectively, with the number of the first through the tenth number. These outputs are connected in parallel with the ten inputs of the digital to analogue Converter 10 from 1 to 10 and through the transducer 10 with ten inputs of the filter block 12 from 1 to 10 inputs (figure 1). These ten inputs 1 through 10 in the filter unit 12 in parallel have their own circuit, is the same for each channel. On Fig shows an example circuit to the first input of the filter block 12. This voltage is in the process of transfer subject to quantization, therefore, is the elimination of frequency quantization and harmonics and subharmonics, work-related nonlinear elements in the transmission. To highlight the spectrum of the speech (Fig) in the first channel of the first entry in the filter unit 12 is connected with the first output through the filter rejectee 161 per 1000 Hz, through the band-pass filter 162 and the bandwidth is 300-2700 Hz and amplifier reception 163. The first output unit 12 is connected to the input of the remote post of operator-operator 13, where the voltage is supplied to the loudspeaker for speech corresponding radio station. Similarly formed filtering for other circuits through the filter cartridge 12, which connects the second input of the filter 12 with 2 output 3 input filter 12 with 3 output 4 input filter 12 with 4 output 5 input filter 12 5 output 6 input filter 12 with 6 output 7 input filter 12 with 7 output 8 input filter 12 with 8 output 9 input filter 12 from 9 output 10 input filter 12 with 10 outputs. Ten outputs 1, 2, 3, 4, 5, 6, 7, 8, 9 and 10 of the filter unit 12 (Fig) connected in parallel with the inputs of ten remote stations radio operator-operator 13.

When the simultaneous operation of multiple radio stations it is advisable to exclude the imposition of information pulses and, consequently, possible failures, requires synchronization of all stations on the work of the older radios. For this purpose, the eldest station is shunted by the switch "off" delay line continuous tuning 18 of the Converter 9, when it radiates the first packet of pulses correlated in time to the first channel. This impulse at a reception at the subordinate station goes on the eleventh inverter output 8 (figure 1, figure 5, and IG) and then goes on 12 the input of the Converter 9, providing a temporal offset of the counter 17 to its second input (Fig).

Converter data channels 39, presented in figure 7, contains six channel formers packet data 90, 91, 92, 93, 94, 95 and the item OR 96. The device inputs data channels 39 from first to sixth input receives pulses of different duration. On the first input receives a pulse duration of 5 MS, the second input is 6 MS, the third input - 7 MS, the fourth input is 8 MS, the fifth input is 9 MS and the tenth input 10 MS. At the same time to the inputs of the seventh, eighth, ninth, tenth, eleventh and twelfth receives continuous information data transfer speeds: 100 Bps, 300 Bps-500 Bps and 1200 Bps. Channel formers are forming data packets with fixed length packets of equal duration pulses on inputs from the first to the sixth. Therefore, the seventh and sixth inputs of the inverter 39 is connected to the first and second inputs of the driver 90, the output of which is connected to the output of the Converter 39 via the sixth input element OR 96. The eighth and fifth inputs of the inverter 39 is connected to the first and second inputs of the driver 91, the output of which is connected to the output of the Converter 39 via the fifth input element OR 96. The ninth and the fourth input is s of the inverter 39 is connected to the first and second inputs of the former (92, the output of which is connected to the output of the Converter 39 via the fourth input element OR 96. The tenth and third inputs of the inverter 39 is connected to the first and second inputs of the driver 93, the output of which is connected to the output of the Converter 39 through the third input element OR 96. The eleventh and second inputs of the inverter 39 is connected to the first and second inputs of the driver 94, the output of which is connected to the output of the Converter 39 via the second input of the OR element 96. The twelfth and the first input of the inverter 39 is connected to the first and second inputs of the former (95, the output of which is connected to the output of the Converter 39 through the first input element OR 96. Work shapers 90, 91, 92, 93, 94 and 95 are the same, and therefore the block diagram is the same and is represented by the work of the channel driver packet data 90.

Channel driver packet data 90 presented on Fig, contains the first and second memory cells 109 and 110, seven elements And- 97, 98, 99, 100, 101, 102 and 111, two NOT gates 103 and 104, the multivibrator - 108, the trigger 105, the pulse corrector - 106, a delay line 107 and the element OR 112.

Forming data packets of pulses, the data transmission in the driver packet data 90 (Fig). To the second input of the shaper information pulse 90 receives a pulse duration of 5 MS, p is item in each channel its own. This momentum provides synchronization trigger multivibrator 105 and 108. Simultaneously, the pulse duration of 5 MS arrives at the first input of the sixth element 102 And through the offset pulse 106 and the delay line 107, which provides the passage through it of the pulses of the multivibrator 108 for reading from memory cells 109 and 110 only during his action, i.e. 5 MS. In this mode of operation of the multivibrator 108 is dependent on the preset transfer rate in the data channel. The mode of operation of the multivibrator is set by the switch, at the same time indicating the transmission speed for the operation of the driver 90. The switch is associated with three switches: wclac, LCLUC, LCLUC. The switches have four positions: 1, 2, 3 and 4. In the first position, when the zero contact of each switch is connected to the first terminal, this provision defines work with a data rate of 1200 Baud. The second position when the zero contact of each switch is connected to the second terminal, this provision defines work with a data transfer rate of 500 Bps. The third position when the zero contact of each switch is connected to the third terminal, this provision defines work with a data transfer rate of 300 Baud. The fourth position of the switches when the zero contact of each switch is connected to the fourth terminal, this position is determined by the t to work with a data rate of 100 Bps. When writing in the memory cell 109 and 110 on the first input memory cells possess the capacity write to 1200 pulses; on the second input memory cells possess the capacity record in the 500 pulses; on the third log memory cells possess the capacity write to 300 pulses; on the fourth log memory cells possess the capacity record in the 100 pulses of information.

For the multivibrator 108, forming pulses, providing popping written from memory cells 109 and 110 of the information channel data, the number of generated pulses is determined by the duration of the packet transmission rate. The shaper 90 multivibrator 108 is synchronized 5 MS pulses for reading of the memory cells has a 5 MS on the first input of the multivibrator 108 to produce 1200 pulses or to operate at a frequency of 240 kHz. When applying the clock pulse 5 MS from the second input of the shaper 90 through the switch 3 to the second terminal of the multivibrator 108 the latter generates a 5 MS 500 pulses or operates at a frequency of 100 kHz. When applying the clock pulse 5 MS from the second input of the shaper 90 through the switch 3 to the third terminal of the multivibrator 108 the latter generates a 5 MS 300 pulses or operates at a frequency of 60 kHz. When applying the clock pulse 5 MS from the second input FD is MyRoutes 90 through the switch 3 to the fourth terminal of the multivibrator 108 the latter generates a 5 MS 100 pulses or operates at a frequency of 20 kHz.

The difference channel driver data 90 from the shaper 91 (7, 8) consists only in changing the operation of the multivibrator 108, for in the sixth channel information packet has a duration of 6 MS. Therefore, changing the generation of pulses of the multivibrator 108. When applying the clock pulse of 6 MS from the second input of the shaper 91 through the switch 3 to the first terminal of the multivibrator 108 must generate for 6 MS 1200 pulses or to operate at a frequency of 200 kHz. When applying the clock pulse of 6 MS from the second input of the shaper 91 through the switch 3 to the second terminal of the multivibrator 108 must generate for 6 MS, 500 pulses or operates at a frequency of 83 kHz. When applying the clock pulse of 6 MS from the second input of the shaper 91 through the switch 3 to the third terminal of the multivibrator 108 must generate 6 300 MS pulses or to work at a frequency of 50 kHz. When applying the clock pulse of 6 MS from the second input of the shaper 91 through the switch 3 to the fourth terminal of the multivibrator 108 must generate for 6 MS 100 pulses or to operate at a frequency of 16 kHz.

The difference channel driver data 90 from the shaper 92 (7, 8) consists only in changing the operation of the multivibrator 108, for in the seventh channel information packet has a duration of 7ms. Therefore, changing the generation of pulses of the multivibrator 108. When applying the clock pulse 7 MS from the second input of the shaper 92 through the switch 3 to the first terminal of the multivibrator 108 must generate 7 MS 1200 pulses or to operate at a frequency of 170 kHz. When applying the clock pulse 7 MS from the second input of the shaper 92 through the switch 3 to the second terminal of the multivibrator 108 must generate 7 MS 500 pulses or operates at a frequency of 71 kHz. When applying the clock pulse 7 MS from the second input of the shaper 92 through the switch 3 to the third terminal of the multivibrator 108 must generate 7 300 MS pulses or to operate at a frequency of 42 kHz. When applying the clock pulse 7 MS from the second input of the shaper 92 through the switch 3 to the fourth terminal of the multivibrator 108 must generate 7 100 MS pulses or to operate at a frequency of 14 kHz.

The difference channel driver data 90 from the shaper 93 (7, 8) consists only in changing the operation of the multivibrator 108, for in the eighth channel package information has duration of 8 MS. Therefore, changing the generation of pulses of the multivibrator 108. When applying the clock pulse 8 MS from the second input of the shaper 93 through the switch 3 to the first terminal of the multivibrator 108 lastly the th must generate for 8 MS 1200 pulses or to operate at a frequency of 150 kHz. When applying the clock pulse 8 MS from the second input of the shaper 93 through the switch 3 to the second terminal of the multivibrator 108 must generate for 8 MS 500 pulses or operates at a frequency of 62.5 kHz. When applying the clock pulse 8 MS from the second input of the shaper 93 through the switch 3 to the third terminal of the multivibrator 108 must generate 8 300 MS pulses or to work at a frequency of 37.5 kHz. When applying the clock pulse 8 MS from the second input of the shaper 93 through the switch 3 to the fourth terminal of the multivibrator 108 must generate 8 100 MS pulses or to operate at a frequency of 12 kHz.

The difference channel driver data 90 from the shaper 94 (7, 8) consists only in changing the operation of the multivibrator 108, for in the ninth channel package information has a duration of 9 msec. Therefore, changing the generation of pulses of the multivibrator 108. When applying the clock pulse 9 MS from the second input of the shaper 94 through the switch 3 to the first terminal of the multivibrator 108 must generate for 9 MS 1200 pulses or to operate at a frequency of 133 kHz. When applying the clock pulse 9 MS from the second input of the shaper 94 through the switch 3 to the second terminal of the multivibrator 108 must generate over 9 500 MS pulses or works n is the frequency of 55.5 kHz. When applying the clock pulse 9 MS from the second input of the shaper 94 through the switch 3 to the third terminal of the multivibrator 108 must generate at 9 300 MS pulses or to work at a frequency of 33.3 kHz. When applying the clock pulse 9 MS from the second input of the shaper 94 through the switch 3 to the fourth terminal of the multivibrator 108 must generate for 9 MS 100 pulses or to operate at a frequency of 11 kHz.

The difference channel driver data 90 from the shaper 95 (7, 8) consists only in changing the operation of the multivibrator 108, for in the tenth channel package information has duration of 10 MS. Therefore, changing the generation of pulses of the multivibrator 108. When applying the clock pulse 10 MS from the second input of the shaper 95 through the switch 3 to the first terminal of the multivibrator 108 must generate 10 MS 1200 pulses or to operate at a frequency of 120 kHz. When applying the clock pulse 10 MS from the second input of the shaper 95 through the switch 3 to the second terminal of the multivibrator 108 must generate 10 MS 500 pulses or operates at a frequency of 50 kHz. When applying the clock pulse 10 MS from the second input of the shaper 95 through the switch 3 to the third terminal of the multivibrator 108 must generate 10 MS 300 pulses or the work is at a frequency of 30 kHz. When applying the clock pulse 10 MS from the second input of the shaper 95 through the switch 3 to the fourth terminal of the multivibrator 108 must generate 10 MS 100 pulses or to operate at a frequency of 10 kHz.

Thus, should continue to review the operation of the imaging unit 90 on Fig. Synchronized 5 MS pulse trigger 105 operates in standby mode and generates a one-second pulses, alternately connecting the first and second memory cells 109 and 110 through the first and second elements And 98 and 97 to the information channel data to the first input of the shaper packet data 90, which provides alternating one-second recording of information in each memory cell depending on the data rate, when selected by the first switch and the second input number of memory cells. The first log provides a record of 1200 pulses; a second entrance is 500 pulses; and the third 300 pulses; fourth -100 pulses.

To provide a consistent user experience and continuous receipt of information in the memory cell between the trigger 105 and the first element And 98 included the first element is NOT 104. Recorded in the memory information is read in the fifth channel on the modulator of the transmitter for 5 MS, in the sixth channel for 6 MS, in the seventh - 7 MS, in the eighth - 8 MS, in the ninth for 9 MS, the tenth is 10 MS. Reading happens is as follows. Synchronization of the offset pulse is a pulse received on the second input of the shaper 90. In the fifth channel multivibrator 108, is connected by its first input supply sync, creates 1200 pulses with a duration of 4 μs each, supplied to the second input of the sixth element And 102, and their synchronization occurs through the pulse corrector 106 according to the first input of the sixth element 102 And a pulse duration of 5 MS. In the fifth channel multivibrator 108, is connected by its second input the filing of the sync pulse, generates 500 pulses with a duration of 10 μs each, supplied to the second input of the sixth element And 102, and their synchronization occurs through the pulse corrector 106 according to the first input of the sixth element 102 And a pulse duration of 5 MS. In the fifth channel multivibrator 108, connected on his third input supply sync, creates 300 pulses with a duration of 16 MS each, supplied to the second input of the sixth element And 102, and their synchronization occurs through the pulse corrector 106 according to the first input of the sixth element 102 And a pulse duration of 5 MS. In the fifth channel multivibrator 108, connected on his fourth input supply of the sync pulse, generates 100 pulses with a duration of 50 μs each, supplied to the second input of the sixth element And 102, and their synchronization occurs through the corrector of the pulse is sa 106 according to the first input of the sixth element 102 And a pulse duration of 5 MS. The correction pulse 106 (Fig.9) corrects 5 MS packet of pulses of the multivibrator 102, passed through the sixth element And 102, providing for the duration of the output driver 90 package information pulse data for the sixth channel in five milliseconds. The incoming pulse is 5 MS per input corrector 106 is supplied to the first input of the trigger 166 through the second differentiating chain, consisting of a valve D2and resistor R2. This differentiating chain positive pulse front time 5 MS pulse triggers 166. The first differentiating chain, consisting of a valve D1and resistor R1and connected to the input of the corrector 106 through the delay line 165 in time by the value of 5 MS, and performs the stop operation of the trigger 166 on the second positive input pulse leading edge of the delayed pulse is 5 MS. Thus, the trigger 166 output recreates the pulse duration of 5 MS to control the operation of the multivibrator 108.

To read data stored in the first memory cell 109 pulses, their number depends on the transmission rate of the multivibrator 108, which is coming to the fifth input of the memory 109 via the second input of the sixth element And 102 and through the first input of the seventh element And 111. A for reading information recorded in the second ball is s memory 110 pulses of the multivibrator 108, coming to the fifth input of the memory cell 110 through the second input of the sixth element And 102 and through the first input of the fifth element And 101. Reading of information is the output of the shaper 90 from the output of the first memory cell 109 through the first input of the fourth element And 100 and through the first input element OR 112. Reading of information is the output of the shaper 90 from the output of the second memory cell 110 through the first input of the third element And 99 and through a second input of the OR element 112. While the pulses of the multivibrator 108 are one of the elements And 111 or 101 to the memory cell, which is filled with information, and the trigger 105 is disconnected from her information input channel, i.e. the first input of the shaper 90, and an entry is made in the opposite memory. Moreover, the elements And 111 and 101 are opened by the trigger 105 alternately, since the element 111 And is connected directly to the output of the trigger 105 and the element 101 And the second element is NOT 103.

The connection of the outputs of the memory cells 41 and 42 is also alternately, if the cell is being recorded, then the output should not be information, because at this time is read from the other memory cell. Therefore, the third and fourth elements 99 and 100 are connected to the opposite signals trigger 105, the element 100 directly to the output of the trigger 105 and the element And 99 through the element 10. Elements 99 and 100 transmit the information packets of pulses to the second and first inputs OR 112 and further to the output driver 90, and duration information of the packets of pulses in each of the six channels (channels 6, 7, 8, 9, 10) data different from 5 MS to 10 MS (i.e. in accordance with the formulatAndNFN=Nt1,wheretAndNFN- duration information package pulse for N channel, N is the channel number from the first to the tenth, τ1- pulse width clock or the first channel is equal to 1 MS). Thus, the entry in the cell is on the second information in the form of 100, 300, 500 and 1200 pulses on the data channels from the thirteenth to the eighteenth (figure 1), and the reading of these pulses is different and depends on the selected mode of data transfer (100 Bps, 300 Bps-500 Bps and 1200 Bps) and pulse duration for a given channel from 5 MS to 10 MS.

Converter information data channels 16, shown in figure 10 and figure 1, contains six channel formers information data 113, 114, 115, 116, 117 and 118, which are connected in parallel to the first inputs of the six inputs from the first and sixth, respectively, the second inputs of the six channel formers in parallel connected to the seventh input of the Converter 16 and through it to the generator of the quantum to synchronize the operation of the channel formers; six outputs of six formers form a six outputs of the Converter 16.

Channel driver information data 113, presented by figure 11, contains the first and second memory cell - 137, and 138; the elements And from the first to the sixth- 141, 142, 143, 144, 145, 146; item NO - 147; counts pulses from the first to the third - 139, 151, 152; triggers from the first to the third - 140, 150, 153; adenovirally - 148, 149; item OR 154. The principle of operation of the six channel formers information data 114, 115, 116, 117 and 118 is similar to the work channel of the imaging unit 113, so you should consider only the difference in their work. But the construction and operation of the driver information data 113 is similar to the driver information telephone channel 58 presented on Fig.6. Indeed, arriving at the output of the receiving device 4 (figure 1) packets of pulses are separated by channels Converter receiving channels 8. In the transducer of the receiving channels 8 (figure 5) is allocating channels to work them in the phone mode or in transmission mode data using switches from the first to the sixth, the built-in Converter 8. With dedicated channels for lane is giving data with a significant time duration of the packet. These are the packages starting with the fifth channel with a duration of 5 MS, the sixth channel is 6 MS, the seventh - 7 MS, the eighth - 8 MS, the ninth - 9 MS, the tenth is 10 MS. These channels are connected to the inverter information data 16 (figure 10), which houses six shapers information for data channels. These conditioners provide second-by-second account of the packets in the two memory sections 137 and 138, and then the read cell information with speed, providing continuous information of the data transmission channel. To control alternate entry packages to the input of memory cells received on the first input of the shaper 113, and reads information embedded in the packets from the memory cells to the output of the shaper are the other elements of the imaging unit 113. Moreover, for each driver selects the mode of data transmission speed and the switch is set to five switches. The first and second switches installed capacity of memory cells 137 and 138 on the basis of the transfer rate. So when connecting the zero terminals of the switches 1 and 2 through the first terminal to the first input of memory cells 137 and 138 is connected to the memory capacity of the adoption of the package of 1200 pulses. Thus the position of the zero terminal connected to the first terminal of the switches 3 and 4 on especially the counters 152 and 151 1200 pulses passing through them a second output of the memory cells 137 and 138 with the subsequent alarm about the end on the fifth inputs for Boliviana few cells and run odnovorov 148 and 149 for issuing a read command to on sixth inputs of the opposite memory cell through the second inputs of the second and fourth elements 142 and 144. At the same time connecting the zero terminal of the switch 5 to the first terminal is the receipt of the sync pulse generator quantum 7 through the first counter 139 at the first input of the first flip-flop 140, which is output to the first position creates a 1200 pulses per second than feeds these pulses to read at the sixth input of the first memory cell 137 through the first input of the first element And 141 through the first input of the second element And 142 and parallel feeds these pulses to read at the sixth input of the second memory cell 138 through the first input of the third element And 143 through the first input of the fourth element And 144. Permission for admission of 1200 pulses trigger 140 to the sixth input of the cell 137 through the element And 141 is obtained, if the cell output 137 of the received signal on completing his service, and if the opposite cell 138 from the counter 151 received signal via the one-shot 149 to the second input element And 142 on the end of reading from the opposite cell 138. This is the second part of the shaper 113 memory 138.

When connecting the zero terminals of the switches 1 and 2 through the second terminal to the second input of memory cells 137 and 138 performs the I connect the memory capacity of the packet 500 pulses. Zero terminal connected to the second terminal of the switches 3 and 4, which ensures the counters 152 and 151 to 500 pulses passing through them a second output of the memory cells 137 and 138 with the subsequent alarm about the end on the fifth inputs for Boliviana few cells and run odnovorov 148 and 149 for issuing a read command to on sixth inputs of the opposite memory cell through the second inputs of the second and fourth elements 142 and 144. At the same time connecting the zero terminal of the switch 5 to the second terminal is the receipt of the sync pulse generator quantum 7 through the first counter 139 to the second input of the first flip-flop 140, which is output to the second position generates 500 pulses per second, which ensures the supply of these pulses to read at the sixth input of the first memory cell 137 through the first input of the first element And 141 through the first input of the second element And 142 and parallel feeds these pulses to read at the sixth input of the second memory cell 138 through the first input of the third element And 143 through the first input of the fourth element And 144. Permission to pass 500 pulses trigger 140 to the sixth input of the cell 137 through the element And 141 is obtained, if the cell output 137 of the received signal on completing his service, and if the opposite cell 138 from the counter 151 received ignal through the one-shot 149 to the second input element And 142 on the end of reading from the opposite cell 138. This is the second part of the shaper 113 memory 138.

When connecting the zero terminals of the switches 1 and 2 through the third terminal to the third inputs of the memory cells 137 and 138 is connected to the memory capacity of the adoption of the package of 300 pulses. Zero terminal connected to the third terminals of the switches 3 and 4, which ensures the counters 152 and 151 to 300 pulses passing through them a second output of the memory cells 137 and 138 with the subsequent alarm about the end on the fifth inputs for Boliviana few cells and run odnovorov 148 and 149 for issuing a read command to on sixth inputs of the opposite memory cell through the second inputs of the second and fourth elements 142 and 144. At the same time connecting the zero terminal of the switch 5 to its third terminal is the receipt of the sync pulse generator quantum 7 through the first counter 139 to the third input of the first flip-flop 140, which is output to the third position creates 300 pulses per second than feeds these pulses to read at the sixth input of the first memory cell 137 through the first input of the first element And 141 through the first input of the second element And 142 and parallel feeds these pulses to read at the sixth input of the second memory cell 138 through the first input of the third element And 143, cher is C the first input of the fourth element And 144. Permission to pass 300 pulses trigger 140 to the sixth input of the cell 137 through the element And 141 is obtained, if the cell output 137 of the received signal on completing his service, and if the opposite cell 138 from the counter 151 received signal via the one-shot 149 to the second input element And 142 on the end of reading from the opposite cell 138. This is the second part of the shaper 113 memory 138.

When connecting the zero terminals of the switches 1 and 2 through the fourth terminal to the fourth inputs of the memory cells 137 and 138 is connected to the memory capacity of the adoption of the package of 100 pulses. Zero terminal connected to the fourth terminals of the switches 3 and 4, which ensures the counters 152 and 151 100 pulses passing through them a second output of the memory cells 137 and 138 with the subsequent alarm about the end on the fifth inputs for Boliviana few cells and run odnovorov 148 and 149 for issuing a read command to on sixth inputs of the opposite memory cell through the second inputs of the second and fourth elements 142 and 144. At the same time connecting the zero terminal of the switch 5 to the fourth terminal is the receipt of the sync pulse generator quantum 7 through the first counter 139 to the fourth input of the first flip-flop 140, which is output to the fourth state which generates 100 pulses per second, what feeds these pulses to read at the sixth input of the first memory cell 137 through the first input of the first element And 141 through the first input of the second element And 142 and parallel feeds these pulses to read at the sixth input of the second memory cell 138 through the first input of the third element And 143 through the first input of the fourth element And 144. Permission for admission of 100 pulses trigger 140 to the sixth input of the cell 137 through the element And 141 is obtained, if the cell output 137 of the received signal on completing his service, and if the opposite cell 138 from the counter 151 received signal via the one-shot 149 to the second input element And 142 on the end of reading from the opposite cell 138. This is the second part of the shaper 113 memory 138.

Working channel formers information data 113, 114, 115, 116, 117 and 118 are the same, so the shaper 113 allows us not to consider the work of the other five shapers.

The use of the proposed device will provide a station in FH mode dialog scheme (duplex mode) on a single antenna, to increase the number of communication channels to one station, to increase the capacity of the exchange of information between the correspondents with the organization instead of one channel to de ate, to provide an independent connection to the radio channel of any of the ten correspondents as ten telephone channels, and six data channels with transfer rates of 100 Bps, 300 Bps-500 Bps and 1200 Bps channels of the terminal equipment and in the channels of the PC, to ensure the reduction of the number of antennas and the gain on the use of the bands, hard synchronization channels and immunity.

1. Phone radio with data that contains a radio transmitter and receiver connected by a coaxial cable line through the antenna diode capacitive switch with an omnidirectional antenna and unit frequency hopping, the frequency tuning of a radio receiver and a radio transmitter and change the number of wave-driven device software select the number of the working wave, characterized in that additionally introduced amplifier, clock, Converter transmission channels, the Converter receiving channels, the transmitter information of the data channels, the unit digital to analog converters, analog-to-digital converters, filters block of ten channels and receive ten channels, containing in each channel transmission power of the transmission, and each receive channel filter rejectee, bandpass filter and amplifier reception, des is th remote posts of operator-operator, their outputs separately and in parallel through the amplifiers in the transmission channels of the filter unit are connected with ten inputs of the analog-to-digital converters, and ten outputs of the unit d / a converters through the filter rejectee, bandpass filter and amplifier reception in its receive channel block filters connected to inputs of ten remote stations radio operator-operator, the ten inputs of the unit d / a converters are connected with the ten outputs of Converter channels, which first input connected to the output of the radio, and the second input to the output of the clock generator pulses, the eleventh inverter output channels is connected through a switch with the twelfth sign of the transducer transmission channels the ten outputs of the analog-to-digital converters connected with ten inputs of the Converter of the transmission channels, the eleventh input connected to the output of the clock generator pulses, the inverter output transmission channels coupled in parallel with the input of the transmitter and through the amplifier to the antenna diode capacitance switch block hopping is connected by its output to the second input of the radio receiver and radio transmitter, and to an input of the block poft change the number of waves is connected to the generator output clock pulses; and six outputs on radzay, the thirteenth, fourteenth, fifteenth, sixteenth and seventeenth Converter receiving channels respectively connected to first, second, third, fourth, fifth and sixth inputs of the Converter information of the data channels, the six outputs of the drive information of the data channels into six receiver channels to connect the receiving side data terminal equipment (DTE); six channels of the transmitting side Ltd. consists of six inputs of the Converter transmission channels: the thirteenth, fourteenth, fifteenth, sixteenth, seventeenth, and eighteenth.

2. Phone radio with data transmission according to claim 1, characterized in that the Converter of the transmission channel includes a pulse counter, ten delay lines smooth tuning for 100 MS each, nine discrete delay lines from 100 MS to 900 MS to ensure placement of pulses output from the pulse counter in ten channels, nine triggers, ten shapers of information pulses, the transmitter of the data transmission channels, two elements OR, in this case, each entry of the ten channels of the Converter of the transmission channels from the first to the tenth, is connected with the second input for each channel driver of the information pulse, the eleventh input to the Converter channel re the ACI through the pulse counter is connected in each channel in parallel to one of the ten inputs of the first element OR through the delay line and the driver information pulse, own for each channel, the first channel output of the counter is connected through a first delay line continuous tuning of 100 MS to the first input of the first element OR after the first input of the shaper information pulse of the first channel to synchronize the corresponding stations of the seventh switch must be bypassed with a smooth line delay in the first channel; the second channel output of the counter is connected through a first delay line smooth tuning on 100 MS, through a second line of discrete delay 100 MS after the trigger, creating a pulse duration of 2 msec at its output, and via the first input of the shaper information pulse of the second channel to the second input of the first element OR; for the third channel output of the counter is connected through a first delay line smooth tuning on 100 MS, through a second line of discrete delay 200 MS after the trigger, creating a pulse duration of 3 MS at its output, and via the first input of the shaper information pulse to the third input of the first element, OR; for the fourth channel output of the counter is connected through a first delay line smooth tuning on 100 MS, through a second line of discrete delay to 300 MS after the trigger, creating a pulse duration of 4 MS, at its output, and via the first input of the shaper information pulse Thu the REGO channel to the fourth input of the first element, OR; for the fifth channel output of the counter is connected through a first delay line smooth tuning on 100 MS, through a second line of discrete delay 400 MS after the trigger, creating a pulse duration of 5 MS at its output, via the sixth switch and through the first input of the shaper information pulse of the fifth channel to the fifth input of the first element, OR; for the sixth channel output of the counter is connected through a first delay line smooth tuning on 100 MS, through a second line of discrete delay for 500 MS, through a trigger that creates a pulse duration of 6 MS at its output, via the fifth switch and through the first input driver information pulse sixth channel to the sixth input of the first element, OR; for the seventh channel output of the counter is connected through a first delay line smooth tuning on 100 MS, through a second line of discrete delay of 600 MS, through a trigger that creates a pulse duration of 7 msec at its output, via the fourth switch, and through the first input of the shaper information pulse of the seventh channel to the seventh input of the first element, OR; for the eighth channel output of the counter is connected through a first delay line smooth tuning on 100 MS, through a second line of discrete delay of 700 MS after the trigger, creating a pulse duration of 8 MS at its output, through the third switch, and h is the cut the first input of the shaper information pulse of the eighth channel to the eighth input of the first element, OR; for the ninth channel output of the counter is connected through a first delay line smooth tuning on 100 MS, through a second line of discrete delay 800 MS after the trigger, creating a pulse duration of 9 MS at its output, via the second switch and the first input shaper information pulse ninth channel for the ninth input of the first element, OR; for the tenth channel output of the counter is connected through a first delay line smooth tuning on 100 MS, through a second line of discrete delay 900 MS after the trigger, creating a pulse duration of 10 MS at its output, through the first switch and through the first input driver information pulse of the tenth channel to the tenth input of the first element OR the first element OR connected to the first input of the second element, OR; six switches allow you to disable the trigger output six channels from the fifth to the tenth and to connect the outputs of flip-flops through the second terminal to the six inputs of the Converter of the data channels; so the trigger output of the tenth channel via a first switch connected to the first input of the Converter of the data transmission channels; the trigger output of the ninth channel via a second switch connected to the second input of the Converter of the data transmission channels; the trigger output of the eighth channel via a third switch connected to the third input of the Converter data channels; the trigger output of the seventh channel through the fourth switch is connected to the fourth input of the Converter of the data transmission channels; the trigger output of the sixth channel through the fifth switch is connected to the fifth input of the Converter of the data transmission channels; the trigger output of the fifth channel through the sixth switch is connected to the sixth input of the Converter of the data transmission channels; the twelfth sign of the transducer transmission channels connected to the second input of the pulse counter; six inputs of the Converter of the transmission channels from the thirteenth to the eighteenth connected in parallel to the six inputs of the Converter of the data channels from the twelfth to seventh, respectively; a Converter output data channels connected via the eighth switch to the second input of the second element OR the output of which forms the drive output of the transmission channels.

3. Phone radio with data transmission according to claim 2, wherein the driver information pulse contains two memory cells, seven elements And two elements are NOT, the multivibrator trigger offset pulse, the element OR the second input of the shaper information pulse in parallel connected to the input of the trigger with the second input of the sixth element And through the multivibrator, and through the corrector per pulse with the second input of the sixth element, And the output of the sixth element And connected in parallel through the first input of the fourth element And with the second input of the first memory cell, and through the first input of the fifth element And with the second input of the second memory cell, the trigger output is connected in parallel with the second input of the third element And with the second input of the fourth element And with the second input of the seventh element, And through the first element is NOT parallel with the second inputs of the first and second elements And, at the same time, the trigger output is connected through the second item, NOT with the second input of the fifth element And the first input of the shaper information pulse in parallel connected to the output of shaper through the first input of the first element And through the first input of the first memory cell through the first input of the seventh element And through the first input of the OR element and through the first input of the third element And through the first input of the second memory cell via the first input of the second element And through the second input of the OR element.

4. Phone radio with data transmission according to claim 3, characterized in that the corrector pulse shaper information pulse contains a line of discrete delay, trigger and differentiating chain elements and the input of the offset pulse is connected through the line discrete delay through the valve in parallel via the input trigger is the output of the offset pulse, and through a resistor to the ground.

5. Phone radio with data transmission according to claim 4, characterized in that the pulse counter Converter transmission channels contains a resistor voltage divider of two resistors, trigger, differentiating chain, the valve element And the first input of the pulse counter connected in parallel with the first input element And with the second input element And through the valve, differentiating chain, the trigger and the resistor voltage divider, a second input of the pulse counter connected to the resistor voltage divider, the output element And is connected to the output of the counter.

6. Phone radio with data transmission according to claim 5, characterized in that the Converter receiving channels includes ten channels in each of the ten channels own channel driver information, eighteen members, nine of triggers, nine and nine lines delay of 1 MS, and in each of the ten channels formed breeding raznosortnyh packets of information pulses at the expense of the trigger, the delay line element and two elements, the first input of the Converter receiving channels connected in parallel through the first delay line to the first inputs of the first elements And the second And, through the first trigger to the second input of the first is lament And to the second input of the second element And through the element; the output of the first element And connected in parallel through a second delay line to the first inputs of the elements of the third And fourth And, via a second trigger to the second input of the third element And to the second input of the fourth element And through the element; the output of the third element And connected in parallel through a third delay line to the first input element of the fifth And sixth, And through the third trigger to the second input of the fifth element And to the second input of the sixth element And through the element; the output of the fifth element And connected in parallel through a fourth delay line to the first inputs of the elements of the seventh And eighth And, through the fourth trigger to the second input of the seventh element And to the second input of the eighth element And through the element; the output of the seventh element And connected in parallel through the fifth delay line to the first inputs of the elements of the ninth And tenth, And through the fifth trigger to the second input of the ninth element And to the second input of the tenth element And through the element; the output of the ninth element And connected in parallel through sixth delay line to the first inputs of the elements of the eleventh And twelfth, And through the sixth trigger to the second input of the eleventh element And to the second input of the twelfth element And through the element; the output of the eleventh element And connected in parallel through the seventh whether the Oia delay to the first inputs of the elements of the thirteenth And fourteenth And and after the seventh trigger to the second input of the thirteenth element And to the second input element of the fourteenth And through the element; the output of the thirteenth element And connected in parallel through eighth delay line to the first inputs of the elements of the fifteenth And sixteenth, And through the eighth trigger to the second input of the fifteenth element And to the second input of the sixteenth element And through the element; the output of the fifteenth element And connected in parallel through ninth delay line to the first inputs of the elements of the seventeenth And eighteenth, And through ninth trigger to the second input of the seventeenth element And to the second input of the eighteenth element And through item NO; output seventeenth element And is connected through a sixth switch to the first input channel driver in the tenth channel or through a sixth switch to the seventeenth inverter output channels; the output of the second element And connected in parallel to the eleventh inverter output channels, and to the first output via the first input channel of the imaging unit into the first channel; a fourth output element And is connected to the second inverter output channels received through the first input channel driver information in the second channel; the output of the sixth element And connected to the third inverter output channels etc the EMA through the first input channel of the driver in the third channel; the output of the eighth element And connected to the fourth inverter output channels received through the first input channel shaper in the fourth channel; the output of the tenth element And connected in parallel through the first switch on the choice of its location to the twelfth inverter output channels or to his fifth output via the first switch via the first input channel shaper in the fifth channel; the output of the twelfth element And connected in parallel through a second switch on the choice of its provisions to the thirteenth inverter output channels or to his sixth output through the second switch and through the first input channel driver in the sixth channel; output fourteenth element And connected in parallel through the third switch to the fourteenth inverter output channels or to his seventh output through the third switch and through the first input channel driver in the seventh channel; output sixteenth element And connected in parallel via the fourth switch to the fifteenth inverter output channels or to his eighth output through the fourth switch and through the first input channel driver in the eighth channel; output eighteenth element And connected in parallel via a fifth switch to the sixteenth inverter output to the channels receive either his ninth output through the fifth switch and through the first input channel driver in the ninth channel; the switches of the first, second, third, fourth, fifth and sixth have a two position switch; a second input of the Converter channels in parallel connected to the second input of each of the ten channel formers, providing synchronization of shapers generator tact.

7. Phone radio with data transmission according to claim 6, characterized in that each of the ten channels of the Converter channels, each channel driver information contains two memory cells, three counters, three trigger, the six elements And the element is NOT, two one-shot, OR element; the first input channel shaper connected in parallel to the first input of the first memory cell through the first input of the fifth element And to the first input of the second memory cell through the first input of the sixth element And the output of the first memory cell is connected to the input of the third trigger, and in parallel to the output channel driver information through the third pulse counter and through the first input of the OR element; the output of the second memory cell is connected to the input of the second trigger, and in parallel to the output channel driver information via a second pulse counter and through a second input of the OR element; a second input of the shaper of information pulses connected to the input of the first flip-flop through the PE the first pulse counter; the output of the first flip-flop connected in parallel to the second input of the first memory cell through the first input of the first element And through the first input of the second element And to the second input of the second memory cell through the first input of the third element And through the first input of the fourth element; the output of the third trigger is connected in parallel to the second inputs of the first element And the sixth element, And the second input of the fifth element And through the element; the output of the second trigger is connected to the second input of the third element And the second output of the third counter connected in parallel to the third input of the first memory cell, and through the first one-shot to the second input of the fourth element And the second output of the second counter is connected in parallel to the third input of the second memory cell, and through a second one-shot to the second input of the second element I.

8. Phone radio with data transmission according to claim 7, characterized in that the Converter data channels contains six channel formers packet data and the member OR, with the sixth and seventh inputs of the Converter data channels connected to the second and the first input of the first channel driver packet data transmission; the fifth and eighth inputs of the Converter data channels connected to the second and PE is the first input of the second channel driver packet data transmission; the fourth and ninth device inputs data channels connected to the second and the first input of the third channel driver packet data transmission; the third and tenth device inputs data channels connected to the second and the first input of the fourth channel driver packet data; the second and eleventh device inputs data channels connected to the second and the first input of the fifth channel driver packet data transmission; first and twelfth device inputs data channels connected to the second and the first input of the sixth channel driver packet data; the six outputs of the channel forming packet data transmission is connected to the Converter output data channels through sixth fifth, fourth, third, second and first inputs of the OR element.

9. Phone radio with data of claim 8, characterized in that each of the six shapers packet data contains the multivibrator, the two memory cells, seven elements And two elements are NOT, trigger, element, OR three switch at four positions (LCLUC, LCLUC, Wclac), the first input of the first channel driver packet data transmission are connected in parallel to the zero contact on the body first through the first input of the second element And to the zero contact of the second switch via the first input of the first element And; the memory cells of the first and second on four inputs; the first input in both the memory cells 1200 Bit memory, the second entrance is 500 Bits of memory, the third entrance is 300 Bits of memory, the fourth entrance on the 100 Bits of memory; the switches of the first and second alternately, sequentially, connect zero contact to the first, second, third or fourth contact, and through them to the first or second, or third, or fourth inputs of the memory cells of the first and second and based on the selected mode speed channel transmit data: 100 Baud, 300 Bps-500 Bps and 1200 Bps; the output of the first memory cell is connected to the output of the first channel driver packet data sequentially through the first input of the fourth element And through the first input of the OR element; the output of the second memory cell is connected to the output channel of the first driver packet data sequentially through the first input of the third element And through the second input of the OR element; a second input of the first channel driver packet data transmission are connected in parallel to the first input of the sixth element And through the delay line and through the corrector pulse to the input of the trigger and to the zero contact of the third switch; a third switch alternately consistently, connects the zero contact to the first, second, third or fourth contact, and across them to the first, or second, or third, or fourth inputs of the multivibrator based on the selected mode speed channel transmit data: 100 Bps, 300 Bps-500 Bps and 1200 Bps; the output of the multivibrator connected to the output of the sixth element And via its second input; the output of the sixth element And connected in parallel to the fifth input of the first memory cell through the first input of the seventh element, And to the fifth input of the second memory cell via the first input of the fifth element And, when connecting the zero contact of the third switch to one of the inputs of the multivibrator is alternately reading data from two memory cells according to their the fifth input pulses of the multivibrator; when connecting the zero contact to the first input of the multivibrator latter operates at a frequency of 240 kHz and produces 1200 pulses to eject the information pulses of the memory cells for a period of five milliseconds; when connecting the zero contact to the second input of the multivibrator latter operates at a frequency of 100 kHz and generates 500 pulses to eject the information pulses of the memory cells for a period of five milliseconds; when connecting the zero contact to the third input of the multivibrator latter operates at a frequency of 60 kHz and produces 300 pulses to eject the information pulses of the memory cells for a period of five milliseconds; when connected to the zero drop contact to the fourth input of the multivibrator latter operates at a frequency of 20 kHz and generates 100 pulses to eject the information pulses of the memory cells for a period of five milliseconds; managing alternate entry one-second information from the channel data in the memory cell and reading out in the channel on the output of the first driver performs a trigger synchronized peacemillion pulses on its input, the trigger output is connected in parallel to the second inputs of the first element And the fourth element And the seventh element And the trigger output is also connected in parallel to the second inputs of the second element And the third element And through the element and to the second input of the fifth element And through the element is NOT; the second channel driver packet data are similar to the first channel driver packet data transmission, the difference in the operation of the multivibrator to the second shaper, which is synchronized shestielementnaya pulses, so when connecting the zero contact of the third switch to the first input of the multivibrator latter operates at a frequency of 200 kHz and produces 1200 pulses to eject the information pulses of the memory cells for a period of six milliseconds, when connecting the zero contact to the second input of the multivibrator latter operates at a frequency of 83 kHz and generates 500 pulses to eject the information pulses of the memory cells for a period of six milliseconds, when connecting the zero contact to the third input of the multivibrator pic is one operates at a frequency of 50 kHz and produces 300 pulses to eject the information pulses of the memory cells for a period of six milliseconds, when connecting the zero contact to the fourth input of the multivibrator latter operates at a frequency of 16 kHz and generates 100 pulses to eject the information pulses of the memory cells for a period of six milliseconds; the third channel driver packet data such fundamentally and functionally to the first channel driver packet data, the difference of the third driver in the operation of the multivibrator, which is synchronized seminolecounty pulses, so when connecting the zero contact of the third switch to the first input of the multivibrator latter operates at a frequency of 170 kHz and produces 1200 pulses to eject the information pulses of the memory cells for a period of seven milliseconds, when connecting the zero contact to the second input of the multivibrator 108 the latter operates at a frequency of 71 kHz and generates 500 pulses to eject the information pulses of the memory cells for a period of seven milliseconds, when connecting the zero contact to the third input of the multivibrator latter operates at a frequency of 42 kHz and produces 300 pulses to eject the information pulses of the memory cells for a period of seven milliseconds, when connecting the zero contact to the fourth input of the multivibrator latter operates at a frequency of 14 kHz and generates 100 pulses to eject in ormation pulses of the memory cells for a period of seven milliseconds; the fourth channel driver packet data such fundamentally and functionally to the first channel driver packet data, the difference of the fourth driver in the operation of the multivibrator, which is synchronized vosmerochnyj pulses, so when connecting the zero contact of the third switch to the first input of the multivibrator latter operates at a frequency of 150 kHz and produces 1200 pulses to eject the information pulses of the memory cells over a period of eight milliseconds, when connecting the zero contact to the second input of the multivibrator latter operates at a frequency of 62.5 kHz and generates 500 pulses to eject the information pulses of the memory cells over a period of eight milliseconds, when connecting the zero contact to the third input of the multivibrator the latter operates at a frequency of 37.5 kHz and produces 300 pulses to eject the information pulses of the memory cells over a period of eight milliseconds, when connecting the zero contact to the fourth input of the multivibrator latter operates at a frequency of 12 kHz and generates 100 pulses to eject the information pulses of the memory cells over a period of eight milliseconds; the fifth channel driver packet data such fundamentally and functionally to the first channel driver Pak is tov data the difference of the fifth driver in the operation of the multivibrator, which is synchronized devyatimillimetrovy pulses, so when connecting the zero contact of the third switch to the first input of the multivibrator latter operates at a frequency of 133 kHz and produces 1200 pulses to eject the information pulses of the memory cells over a period of nine milliseconds, when connecting the zero contact to the second input of the multivibrator latter operates at a frequency of 55.5 kHz and generates 500 pulses to eject the information pulses of the memory cells over a period of nine milliseconds, when connecting the zero contact to the third input of the multivibrator latter operates at a frequency of 33.3 kHz and produces 300 pulses to eject the information pulses of the memory cells for the period of nine milliseconds, when connecting the zero contact to the fourth input of the multivibrator latter operates at a frequency of 11 kHz and generates 100 pulses to eject the information pulses of the memory cells over a period of nine milliseconds; the sixth channel driver packet data such fundamentally and functionally to the first channel driver packet data, the difference of the sixth driver in the operation of the multivibrator, which is synchronized desyatimillionnikov pulses, so when connected to the zero contact of the third switch to the first input of the multivibrator latter operates at a frequency of 120 kHz and produces 1200 pulses to eject the information pulses of the memory cells for a period of ten milliseconds, when connecting the zero contact to the second input of the multivibrator latter operates at a frequency of 50 kHz and generates 500 pulses to eject the information pulses of the memory cells for a period of ten milliseconds when connecting the zero contact to the third input of the multivibrator, the latter operates at a frequency of 30 kHz and produces 300 pulses to eject the information pulses of the memory cells for a period of ten milliseconds, when connecting the zero contact to the fourth input of the multivibrator latter operates at a frequency of 10 kHz and generates 100 pulses to eject the information pulses of the memory cells for a period of ten milliseconds.

10. Phone radio with data transmission according to claim 9, characterized in that the corrector pulse data channels contains a line of discrete delays, the first differentiating chain of elements of D1and R1the second differentiating chain of elements of D2and R2and the trigger, and the entrance of the offset pulse is connected in parallel to the second differentiating the chain through the diode D2and through resistor R2on the ground and through the line of discrete delay to the second differentiating the chain through the diode D1and through resistor R1on the ground, the output of the diode D2connected to the first input of the trigger; output diode D1 connected to the second input of the trigger, the trigger output is connected to the output of the offset pulse.

11. Phone radio with data of claim 10, wherein the Converter information data channels contains six channel formers information data, with six inputs from the first to the sixth inverter information data channels connected to the six outputs of the drive information of the data channels in parallel through the first six inputs channel formers information data, the seventh input of the Converter information of the data channels are connected in parallel to each channel six channel formers information data.

12. Phone radio with data claim 11, wherein each channel of the driver information data contains two memory cells, the six elements And the element is NOT three trigger, three counters, two one-shot, the element OR the first input of the first channel of the driver information data in parallel is connected to the zero contact of the first switch via the first input of the fifth element And to the zero contact of the second switch via the first input of the sixth element, And zero account the t of the first switch serially connected to the first contact of the first switch and through him to the first input of the first memory cell, the second contact of the first switch and through him to the second input of the first memory cell to the third contact of the first switch and through him to the third input of the first memory cell to the fourth contact of the first switch and through him to the fourth input of the first memory cell, the zero contact of the second switch serially connected to the first contact of the second switch, and through him to the first input of the second memory cell to the second contact of the second switch, and through him to the second input of the second memory cell to the third contact of the second switch, and through him to the third input of the second memory cell to the fourth contact of the second switch and through him to the fourth input of the second memory cell, the output of the first memory cell connected to the third input of the trigger and parallel to the zero contact of the third switch, the zero contact of the third switch alternately connects the switch through the first contact to the first input of the third pulse counter, the zero contact of the third switch connects the switch through the second contact to the second input of the third pulse counter, the zero contact of the third switch connects the switch through the third contact to the third input of the third pulse counter, the zero contact of the third switch connects the switch through h twenty his contact to the fourth input of the third pulse counter; the first output of the third counter pulses through the first input element OR is connected to the output of the first driver and the second output of the third counter connected in parallel to the fifth input of the first memory cell and to the second input of the fourth element And through the first one-shot; the output of the second memory cell is connected to the input of the second trigger and parallel to the zero contact of the fourth switch; zero contact of the fourth switch alternately connects the switch through the first contact to the first input of the second pulse counter, the zero contact of the fourth switch connects the switch through the second contact to the second input of the second pulse counter, the zero contact of the fourth switch is connected through the third switch his contact to the third input of the second pulse counter, the zero contact of the fourth switch connects the switch through the fourth contact to the fourth input of the second counter pulses; the first output of the second counter pulses through the second input element OR is connected to the output of the shaper and the second output of the second counter is connected in parallel to the fifth input of the second memory cell and to the second input of the second element And through the second one-shot; the output of the second trigger is connected to the second input of the third element; the output of the third three is Hera are connected in parallel to the second input of the first element And to the second input of the sixth element And through the element NOT to the second input of the fifth element And the second input channel of the driver information data is connected through a first pulse counter to the zero contact of the fifth switch; zero contact of the fifth switch serially connected to the first, or second, or third or fourth contacts, the first contact of the first switch connected to the first input of the first trigger, a second contact of the first switch is connected to the second input of the first trigger, the third contact of the first switch is connected to the third input of the first trigger, the fourth contact of the first switch is connected to the fourth input of the first trigger; when connected to the first input of the first trigger output of the first counter pulse output trigger is generated 1200 pulses per second, when you connect the meter to the second input of the trigger at its output generates 500 pulses per second, when you connect the meter to the third input of the trigger at the output is created 300 pulses per second, when you connect the meter to the fourth input of the trigger at its output generates 100 pulses per second; the output of the first flip-flop connected in parallel to the sixth input of the first memory cell through the first input of the first element And the first input of the second element And to the sixth input is at the second the memory cell through the first input of the third element And the first input of the fourth element.



 

Same patents:

FIELD: information technologies.

SUBSTANCE: accuracy of assessments of disturbance of a phase balance between inphase (I) and quadrature (Q) components may be increased by means of their completion on a transmitter and a receiver, which are connected via a local feedback connection, and removal of radio noise of mutual spectrum in transmitted packets. As soon as these accurate disturbances of the I/Q phase balance have been determined, they may be used to correct a signal processed by a transmitter or a receiver, in order to increase efficiency and throughput capacity of communication means using this signal.

EFFECT: accurate measurement and assessment of balance disturbances between inphase and quadrature components of a complex group signal.

39 cl, 5 dwg

FIELD: information technology.

SUBSTANCE: reception device has apparatus for determining the first, second and third position of the initial position of the fast Fourier transform (FFT) interval, apparatus for selecting one of the determined initial positions of the FFT interval, FFT apparatus for performing fast Fourier transformation of an orthogonal frequency division multiplexing (OFDM) signal in the time domain by using the initial position selected by the selection apparatus in order to generate a first OFDM signal in the frequency domain. The apparatus for determining the first position calculates the value of correlation between the OFDM signal in the time domain and the signal obtained by delaying said time-domain OFDM signal by the length of the effective symbol. Apparatus for determining the second position estimates the channel characteristic for transmitting the OFDM signal and the delay profile before estimating the value of interference between symbols with respect to each of the FFT intervals. The apparatus for determining the third position establishes the FFT interval with offset from the FFT interval used for generating the first OFDM signal, for generating the second OFDM signal before eliminating distortions from the first and second OFDM signals in order to generate an adjusted signal.

EFFECT: reducing multiple-beam interference by adjusting the symbol synchronisation signal.

8 cl, 26 dwg

FIELD: information technology.

SUBSTANCE: hard-decision bit from bits indicating the P-axial coordinate of a reception signal point is input into an area detection circuit, and based on the hard-decision bit input, the area detection circuit detects and outputs an area on the phase plane where the coordinate of the reception signal point is present. A soft-decision bit from bits indicating the coordinate of the reception signal point is input into a log-likelihood ratio (LLR) circuit, and based on the soft-decision bit input, the LLR circuit calculates a primary LLR. A LLR converter calculates the final LLR based on an output signal (area detection result) from the area detection circuit. In such a configuration, a log-likelihood ratio is calculated while limiting the scope within which the value of the log-likelihood ratio varies according to the position of the reception signal point, the interval between adjacent signal points including the hard-decision threshold of the bit.

EFFECT: log-likelihood ratio calculation at a higher rate while reducing the size of the circuit and consumed power, independent of the multilevel number of the modulation method.

22 cl, 17 dwg

FIELD: information technology.

SUBSTANCE: apparatus for transmitting data comprises an encoder for encoding data, a multiplexer for multiplexing the encoded data and a training sequence code (TSC), a modulator for modulating the multiplexed data using a defined modulation scheme and a transmitter for transmitting the modulated data. The modulator modulates TSC based on two constellation points having the highest absolute value and opposite signs among M constellation points in the constellation according to the defined modulation scheme.

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20 cl, 17 dwg

FIELD: information technology.

SUBSTANCE: first evaluation of the wireless channel is obtained during restoration of a variety of parallel data streams on the basis of received pilot symbols. Detection is carried out for the received data symbols using the first channel evaluation to obtain detected symbols for the first data stream. Obtained detected symbols are decoded to receive the decoded first stream of data that are encoded again for obtaining repeatedly modulated symbols. The second channel evaluation is obtained on the basis of the repeatedly modulated symbols. The first and the second channel evaluations are joined together to obtain the third channel evaluation having the higher quality. The interfering signal determined by the first data stream is evaluated and removed using the third channel evaluation. Detection of symbols is carried out when removing the evaluated interference from the main stream using the third channel evaluation to obtain detected symbols for the second data stream. Obtained detected symbols are additionally decoded to receive the decoded data of the second data stream.

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37 cl, 7 dwg

FIELD: radio communications, possible use in demodulators of radio-relay communication systems which use signals with quadrature amplitude manipulation.

SUBSTANCE: in accordance to the invention, error signal is generated every time when on two adjacent clock intervals change of modulating symbol value occurs, not only when sign change occurs. Device contains serially connected solving device (1), adder (4), second input of which is connected to output of solving device (1) through serially connected sign inverter (3) and first delay block (2), and multiplier (6), and also second delay block (5), connected to second input of device. Introduced are serially connected second adder (7), first input of which is connected to output of delay block (2), second input - to output of sign inverter (3), divider by two (8), and third adder (9), second input of which is connected to output of delay block (5), and its output - to second input of multiplier (6). Solving device (1) makes a decision about value of modulating symbol being receipt, and not about its sign.

EFFECT: increased interference resistance of device.

2 cl, 15 dwg, 1 tbl

FIELD: radio communications and radio communication systems.

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EFFECT: enlarged functional capabilities.

1 cl, 1 dwg

FIELD: communications.

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3 cl, 6 dwg

FIELD: radio engineering; demodulating sixteen-position quadrature-amplitude keyed signals.

SUBSTANCE: proposed demodulator, type KAM-16, has three phase detectors, two solvers, two four-position modulators, three subtracters, adder, amplifier, two multipliers, two limiters, low-pass filter, voltage-controlled generator, and four EXCLUSIVE OR gates. Amplitude difference of demodulator quadrature subchannels is detected and eliminated by subjecting signal to following procedures. Demodulator input signal is decomposed by means of recovered carrier signal into cophasal and quadrature components which are passed through first and second controlled amplifiers, supplied to solver, and tetrad of demodulated characters (A, B, C, D) is obtained at demodulator output. Four-position phase keyed signal is obtained across output of first four-position modulator by means of recovered carrier signal and two digital characters (C, D) out of tetrad of demodulated characters (A, B, C, D).

EFFECT: enhanced noise immunity.

1 cl, 5 dwg

The invention relates to electrical engineering and can be used when the reception signal phase or combined amplitude and phase manipulation

FIELD: information technologies.

SUBSTANCE: systems and methods are described, which promote transmission and reception of signals along I and Q branches of a communication channel to suppress the potential T/Q imbalance. The device may transmit a signal along I and Q branches to distribute capacity of transmission substantially evenly for this channel. The device demodulates data with the help of a code or a matrix comprising actual and complex modifiers, creating as a result the signal of I and Q branch for transmission. If the channel comprises multiple resources, the device may alternate or implement transmission along the I branch in one resource and the Q branch in the other resource for this signal, in order to distribute capacity. Besides, the device may apply the code of complex scrambling to distribute the signal along I and Q branches. The device may also use QPSK or modulation of a higher order, to send signals intended for one and the same user.

EFFECT: increased throughput capacity of a communication channel by transmission of data along I and Q branches in order to reduce noise and I and Q imbalance of signal transmission capacity.

37 cl, 11 dwg

FIELD: physics; communication.

SUBSTANCE: invention relates to a communication system. The quadrature modulator includes four amplitude modulators and a combiner. Each amplitude modulator modulates the corresponding carrier frequency signal with the corresponding input signal to provide the corresponding output signal. The combiner then combines four output signals from four amplitude modulators to provide a modulated signal. Each amplitude modulator can be made with a switching amplifier, for example a class-E amplifier with power modulation. Two input signals are obtained through separate summation of an in-phase (I) modulating signal and the inverted modulating signal I with a shift value. Two other input signals are obtained through separate summation of a quadrature (Q) modulating signal and the inverted modulating signal Q with a shift value. The shift value can be selected based on the estimated value of the modulating signals. These four carrier frequency signals are in quadrature with each other.

EFFECT: obtaining optimum noise characteristics and output power.

21 cl, 6 dwg

FIELD: physics.

SUBSTANCE: IQ-modulator pre-distortion device includes two digital filters for compensating for IQ-modulator generated amplitude errors and filtering intermodulation from quadrature to the inphase component of the signal, a first shift compensator for compensating for shift errors of the inphase signal component and a second shift compensator for compensating for shift errors of the quadrature signal component, two iteratively updated digital filters (gQ0, gQ1, gl0, gl1) for filtering each branch of the IQ-signal to compensate for IQ-modulator generated amplitude errors in each branch.

EFFECT: compensation for amplitude and phase errors.

12 cl, 8 dwg

FIELD: electronics.

SUBSTANCE: the circuit generates interfacing signal between first and second integration circuits. Circuit contains supporting signal circuit (622), which outputs supporting signal, interfacing circuit (600) and analog signal transmission circuit (626). Interfacing circuit is realized on first integration circuit (600), during operation it connects to supporting signal circuit (622), receives supporting signal and input data signal and generates interfacing signal. Analog signal transmission circuit (626) is realized on second integration circuit, during operation it connects to control circuit (614), receives interfacing signal and outputs output signal. Supporting signal may represent a voltage or current signal and may be generated on first or second integration circuit. Interfacing circuit may be realized containing current mirror, connected to an array of switches, and may operate in re-digitization mode to simplify filtration requirements. Interfacing signal may represent a differential current signal, having resolution of several (for example, four, eight or more) bits. Analog signal transmission circuit (626) may represent, for example, distributed amplification amplifier, modulator or a different circuit.

EFFECT: improved interfacing between integration circuits with usage of lesser amount of signal lines, generating increased noise.

9 cl, 6 dwg

FIELD: technology for transferring signals, possible use for correcting signal processing circuits transfer characteristics.

SUBSTANCE: method for preliminary correction of signal processing circuit transfer characteristic includes receiving difference between output signal of signal processing circuit and input signal of preliminary correction means, gradient of aforementioned difference is approximated on basis of aforementioned produced difference and approximation of aforementioned transfer characteristic and control values of aforementioned signal of preliminary correction means are renewed on basis of aforementioned approximated gradient. Device meant for preliminary correction of transfer characteristic of signal processing circuit contains comparison means, meant for producing difference between output signal of signal processing circuit and input signal of preliminary correction means, means for approximation of gradient of aforementioned difference and for approximation of aforementioned transfer characteristic and renewal means, meant for receiving control values.

EFFECT: increased precision of signal processing circuit signal transfer.

2 cl, 5 dwg

FIELD: technology for processing data before transmission.

SUBSTANCE: method includes stages: control signal is received for adjusting one of parameters: amplification coefficient and shift current, - of circuit element, connected to transmission signal route, while adjusted aforementioned parameter causes phase rotation in data signal in aforementioned route, and provides for maintained phase turn compensation value, appropriate for operation state, set by received control signal, while maintained phase turn compensation value is approximately of the same value and opposite direction relatively to phase turn value, caused by adjusted parameter, and phase rotation is performed of at least one of a) data signals, b) expanding series for expanding spectrum of aforementioned data signal, and c) bearing signal for modulation of data signal, by means of stored phase compensation value.

EFFECT: compensation of phase turn, caused by adjustment of adjustable circuitry elements, in signal transfer route.

2 cl, 9 dwg

FIELD: electronic engineering.

SUBSTANCE: device has data processing circuit, transmitter, commutation unit, endec, receiver, computation unit, and control unit.

EFFECT: high reliability in transmitting data via radio channel.

4 dwg

The invention relates to modulation, transmission and reception of information signals

The invention relates to radio

FIELD: radio engineering, communication.

SUBSTANCE: cylindrical scanning, lateral radiation antenna comprises: a cylindrical waveguide formed by two (top and bottom) parallel metal discs; a dielectric cylinder which is a filling of the cylindrical waveguide and is capable of operating as a matching transformer between the cylindrical waveguide and free space, and as a beam-forming element; a rectangular array of radiators directed normally to the plane of the array, placed asymmetrically in the cylindrical waveguide; the plane of the array lies parallel to the base of the cylindrical waveguide; two metal cylinders respectively placed over the top and under the bottom discs and capable of operating as auxiliary cylindrical radiators which adjust the beam pattern in the elevation plane.

EFFECT: broader functional capabilities by providing full circular scanning.

7 cl, 10 dwg

FIELD: radio engineering, communication.

SUBSTANCE: in one aspect, power control (PC) is supported in several PC modes such as "up-down" PC mode and delete-based PC mode. One PC mode may be selected for use. Overhead may be sent to indicate the selected PC mode. If the "up-down" PC mode is selected, a base station assesses the quality of the received signal for the terminal and sends PC commands to instruct the terminal to adjust its transmission power. If the delete-based PC mode is selected, the base station sends delete indicators which indicate whether code words received from the terminal are deleted or not. In both PC modes, the terminal controls its transmission power based on a power control feedback (e.g. PC commands and/or delete indicators) in order to attain the desired level of efficiency (e.g. desired delete frequency for code words). Delete indicators may also be used for handover.

EFFECT: reduced noise and achieving high efficiency for all terminals.

9 cl, 11 dwg

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