RU2005102655A - SPECTRALLY EFFECTIVE TRANSMITTER WITH CODE DIVISION OF CHANNELS - Google Patents

Claims (1)

A spectrally efficient code division multiplexer, which includes N information channels, each of which includes a series-connected encoder, an interleaver, a first adder modulo two and a symbol multiplexer, as well as a second adder modulo two and a series-connected address code generator, the first decimator, the second decimator, the output of which is connected to the second input of the symbol seal, the output of the first decimator is connected to the second input of the first adder modulo two, q the generator of the address code is the first input of the information channel, and the third input of the symbol sealer is the third input of the information channel, K call channels, each of which includes a series-connected encoder, interleaver and the first adder modulo two, and the second adder modulo two connected address code generator and decimator, the output of which is connected to the second input of the first adder modulo two, and the input of the address code generator is the first input of the call channel, J channels sync onization, each of which includes a coded encoder and a symbol repeater, and the encoder input is an input of a synchronization channel, a pilot signal channel, a clock generator, the output of which is connected to the input of the synchronization code generator and to the input of the orthogonal code generator, the carrier frequency generator and the channel adder signals, the output of which is the output of the transmitter, characterized in that a series splitter, a second encoder, a second the first interleaver, the output of which is connected to the first input of the second adder modulo two, as well as the second symbol compactor, the input of which is connected to the output of the second adder modulo two, the input of the splitter is the second input of the information channel, the second output of the splitter is connected to the input of the first encoder, the output the first decimator is connected modulo two to the second input of the second adder, and the output of the second decimator is connected to the second input of the second symbol seal, the third inputs of the first and second symbol seal are combined , the output of the first symbol seal is the first output of the information channel, and the output of the second symbol seal is the second output of the information channel, and a splitter, a second encoder, a second interleaver, the output of which is connected to the first input of the second adder modulo two, are introduced into the circuit of the call channel the input of the splitter is the second input of the call channel, the second output of the splitter is connected to the input of the first encoder, the output of the first adder modulo two is the first output of the call channel, and the output d of the second adder modulo two - by the second output of the call channel, the decimator output is connected to the second input of the second adder modulo two, the output of the symbol follower is the output of the synchronization channel, the output of the pilot channel is connected to its input, and the orthogonal generator is additionally introduced into the transmitter circuit M-codes, the input of which is connected to the output of the clock generator, 2 (n + k) modulators, each of which has m information inputs (n = N / m; k = K / m) and M = 2 ^m reference inputs, (n + k + J + 1) a signal spectrum shaper, each of which includes a first adder modulo two in series, a second adder modulo two, a smoothing filter, a multiplier, and the adder, the output of which is the output of the signal spectrum former, as well as the third adder modulo two, the fourth adder modulo two, the second smoothing filter, the second multiplier, the output of which is connected to the second input of the adder, the first input of the first adder modulo d and is the first input of the signal spectrum shaper, the first input of the third adder modulo two is the second input of the signal spectrum shaper, the second inputs of the second and fourth adders modulo two are combined and are the third input of the signal spectrum shaper, the second input of the first adder modulo two is the fourth input signal spectrum shaper, the second input of the third adder modulo two - the fifth input of the signal spectrum shaper, the second input of the first multiplier - the sixth input of the spectrum shaper ignal, and the second input of the second multiplier is the seventh input of the signal spectrum shaper, all information channels are divided into n = N / m groups of m channels each, all the first outputs of the information channels of the n-th group, each separately connected to the corresponding inputs ( 2n-1) -th modulator, all the second outputs of the information channels of the n-th group, each separately connected to the corresponding inputs of the 2n-th modulator, the output of the (2n-1) -th modulator is connected to the first input of the n-th signal spectrum former , and the output of the 2nth modulator is connected to the second the input of the nth signal shaper, the output of the nth signal shaper, individually, is connected to the corresponding inputs (1 to n) of the channel signal adder, all call channels are divided into k = K / m groups of m channels in each , all the first outputs of the channels of the call of the k-th group, each individually connected to the corresponding inputs of the (2n + 2k-l) -th modulator, all the second outputs of the channels of the call channels of the k-th group, individually, connected to the corresponding inputs (2n + 2k) th modulator, the output of the (2n + 2k-1) th modulator is connected to the first input of the (n + k) th pho the signal spectrum shaper, and the output of the (2n + 2k) th modulator is connected to the second input of the (n + k) th signal shaper, the output of the (n + k) th signal shaper, each individually connected to the corresponding inputs ( with n + 1 no n + k) the adder of channel signals, the output of the J-th synchronization channel is connected to the first and second inputs of the (n + k + J) -th signal shaper, the output of the (n + k + J) -th waveformer signal, each individually connected to the corresponding inputs (with n + k + 1 no n + k + J) of the adder channel signals, the output of the pilot channel sub is connected to the first and second inputs (n + k + J + 1) of the signal spectrum shaper, the output of which is connected to the (n + k + J + 1) -th input of the channel signal adder, each of the first n outputs (1 to n) the reference code generator, each separately, is connected to the corresponding third input of the nth signal shaper, each of the following k outputs (with n + 1 no n + k) of the reference code generator, each individually connected to the third input (n + k) th signal spectrum shaper, each of the following J outputs (with n + k + 1 no n + k + J) of the reference code generator, each separately connected is connected to the third input of the (n + k + J) th signal spectrum former, (n + k + J + 1) th output of the reference code generator is connected to the third input of the (n + k + J + 1) th signal spectrum former , the first output of the synchronization code generator is connected to the fourth inputs of all signal spectrum shapers, and its second output is connected to the fifth inputs of all signal spectrum shapers, the first output of the carrier frequency generator is connected to the sixth inputs of all signal spectrum shapers, and its second output is connected to the seventh inputs all signal spectrum formers Ala, the outputs of the generator of orthogonal М-х codes (from 1 to 2 ^m ), each separately, are connected to the corresponding inputs (from 1 to 2 ^m ) of all modulators.