RU2204205C2 - Data transmission method - Google Patents

Abstract

FIELD: radio engineering; communication systems of tactical control sections. SUBSTANCE: proposed method involves generation of phase-keyed signal on sending end of radio link simultaneously with analog voice message transmitted by using narrow-band (frequency) modulation; this signal functions to transmit low-frequency digital information and is added to narrow-band voice signal. Total signal is processed simultaneously in linear channels of transmitter and receiver. EFFECT: enhanced noise immunity and security; enlarged amount of data transmitted. 1 dwg

Description

 The invention relates to the field of radio engineering and may find application in communication systems of tactical control units.

 A known method of transmitting information in radio networks based on the use of common frequency bandwidth and code division multiplexing by subscribers of the network, implemented in the Qualcomm communication system (USA, Qualcomm, may, 1992), as well as a cellular telephone communication method based on the use of spread spectrum signals for voice communication between mobile and fixed telephone exchanges, as described in patent ЕВП 0484918 Н 04 В 7/26.

 The disadvantage of these methods is the high level of mutual interference with a large dynamic range of signal levels of subscribers, as well as the complexity of the hardware implementation.

 A known method of temporary separation of transmission channels used in the "Pan-European Digital Cellular Communication System" (GSM), described in the article by Gromakov Yu. A. and Zhuravlev V.I. “Signal formation and processing in communication systems with moving objects (Express-Information magazine, series“ Information Transmission ”, edited by MD Benediktov, Moscow, 1994, 28, whose disadvantage is low noise immunity and secrecy of transmitted messages .

 A known method of separating communication channels by frequency, described in the monograph by Ratinsky M. V. "Fundamentals of cellular communications", ed. Zimina D.E., Moscow, Radio and Communications, 2000, p. 69.

 This method is based on the allocation to each user of their frequency band Δf (frequency channel) and the transmission of each selected channel of analog information.

 The disadvantage of this method is the low noise immunity and secrecy of the transmitted messages.

 Closest to the proposed method is a method of transmitting information on radio networks with the same type of radio stations, described in the technical description on the radio station P-159 ("Radio P-159. Technical description and operating instructions").

 The prototype method is based on the frequency separation of channels, in which when transmitting with an analog speech signal, harmonic oscillation is modulated, the modulated narrow-band signal after conversion and amplification at intermediate and output frequencies is emitted in the frequency band Δf allocated for each channel, when received after filtering and amplification at the input and intermediate frequencies demodulate the received signal.

 The disadvantage of the prototype is the low noise immunity and secrecy of the transmission of information, as well as the small amount of transmitted messages.

This drawback is eliminated due to the fact that in the method of transmitting information based on the separation of communication channels by frequency, in which a frequency band Δf is allocated for each communication channel, in which analog voice information is transmitted using a narrow-band frequency modulation method in a single frequency band Δf, in each frequency channel, simultaneously with a narrow-band speech signal, low-speed digital information is transmitted, the signal of which is formed due to its phase manipulation according to a pseudo-random law that carries the frequency of the generated phase-shifted digital signal is chosen equal to the average frequency of the spectrum of the narrow-band speech signal, and its clock frequency F _{t is} selected in accordance with the ratio F _t = Δf / 2, while both signals, narrow-band speech and wide-band phase-shifted digital are summed and processed in common linear transmission and reception paths, and upon reception, separate signal demodulation is performed. In this case, the demodulation of the broadband phase-shifted signal is performed after its correlation processing.

 The proposed method is based on the frequency separation of channels when transmitting information in radio networks with the same type of radio station, in which for each communication channel (radio direction) a frequency band Δf is allocated, in which simultaneously with the analog voice information transmitted using the narrow-band frequency modulation method in the frequency channel Δf band transmit low-speed digital information, the signal of which is formed due to phase manipulation of the input digital signal, and the carrier frequency of the generated zomanipulirovannogo digital signal is selected equal to the average frequency spectrum of the narrowband signal modulated by frequency analog voice information.

The value of the clock frequency (F _t ) of the pseudo-random sequence used in the formation and reception of a broadband phase-shifted signal is chosen equal to F _t = Δf / 2, when transmitting and receiving, phase-manipulated digital and narrow-band speech signals are processed in common linear paths, and their separate processing is carried out at demodulation, while the demodulation of the phase-shifted digital signal is performed after its correlation processing.

 The proposed method is based on the following sequence of actions on a signal.

 At the transmitting end of the radio line simultaneously with the analog voice message transmitted using the narrow-band (frequency) modulation method, a phase-manipulated digital signal is generated, which is formed by phase manipulation of the input signal, which is summed with the narrow-band signal, and then the total signal is processed simultaneously in the linear paths of the transmitter and receiver.

 When forming a phase-shifted digital signal, its carrier is chosen equal to the average frequency of the spectrum of a narrow-band signal, modulated in frequency by analogue speech information.

The clock frequency of the phase-shifted digital (F _t ) signal is chosen equal to
F _t = ΔF _m / 2 = Δf / 2,
where ΔF _m is the width of the spectrum of a narrowband speech signal.

 Both signals, broadband digital and narrowband speech, the spectral width of which is the same and equal to Δf, are amplified simultaneously during transmission and reception at intermediate output and input frequencies, they are separately processed when they are modulated and demodulated, which is performed for the phase-shifted digital signal after its correlation processing.

An example of hardware implementation of the proposed method is shown in the drawing, where it is indicated:
1 - microphone amplifier;
2 - frequency modulator;
3 - adder;
4 - pathogen;
5 - power amplifier;
6 - transmitting antenna;
7 - the first frequency synthesizer;
8 - shaper broadband phase-shift keyed signal;
9 - receiving antenna;
10 - high frequency amplifier;
11 - a path of intermediate frequencies;
12 - frequency discriminator;
13 - receiver of a broadband phase-shifted signal;
14 is a second frequency synthesizer.

 The proposed device contains a first frequency synthesizer 7, as well as a series-connected microphone amplifier 1 and a frequency modulator 2, the output of which is connected to the first input of the adder 3, the output of which is connected to the pathogen 4, the power amplifier 5 and the transmitting antenna 6, the first output of the first synthesizer frequency 7 is connected to the reference input of the frequency modulator 2, and the second and third outputs of the frequency synthesizer 7 are connected to the second and third reference inputs of the exciter 4, respectively; the inputs of the microphone amplifier 1 and the driver of the phase-shifted digital signal 8 are the first and second inputs of the device, and the output of block 8 is connected to the second input of the adder 3; the receiving antenna 9 through the high-frequency amplifier 10 is connected to the first, signal input of the intermediate frequency path 11, the second and third reference inputs of which are connected to the first and second outputs of the frequency synthesizer 14, respectively, and the output of the intermediate frequency path 11 is connected to the input of the frequency discriminator 12 and the input the receiver phase-shifted digital signal 13, the outputs of which are the outputs of the device.

 A device that implements the proposed method works as follows.

At the transmitting end of the radio line, a speech signal is supplied to the first input of the transmitter, which, after amplification in block 1, is supplied to block 2, where it modulates in frequency the harmonic oscillation coming from the output of block 7 to the reference input of block 2. A formed narrow-band speech signal having a spectrum width ( ΔF _hm ), equal to the band Δf allocated for this channel, from the output of block 2 is supplied to the first input of block 3.

A digital signal is fed to the second input of the transmitting part of the device, which is fed to the input of block 8, where a phase-shifted digital signal is generated, the carrier frequency of which (f _n ) is chosen equal to the average frequency f _{о of the} narrow-band speech signal, and the clock frequency f _t used to form the phase-shifted digital signal, selected according to the ratio
F _t = ΔF _hm / 2 = Δf / 2,
the phase-shifted digital signal from the output of block 8 is fed to the second input of block 3, where it is added to the narrow-band speech signal supplied to the first input of block 3 from the output of block 2. The total signal is fed to the first signal input of block 4, to the second and third reference inputs of which harmonic oscillations are supplied from the second and third outputs of block 7, respectively, providing the conversion of the total signal to an intermediate and output frequency. From the output of block 4, the total signal through block 5, where it is amplified by power, is transmitted to the transmitting antenna 6.

 At the receiving end of the radio link, a high-frequency sum signal from the output of the receiving antenna 9 is supplied to block 10, where it is filtered and amplified. From the output of block 10, the total signal is fed to the first signal input of block 11, to the second and third reference inputs of which harmonic oscillations from block 14 are supplied.

 In block 11, the signal is converted first to the first and then to the second intermediate frequencies, and at each of the intermediate frequencies the signal is amplified and filtered.

 From the output of block 11, a signal representing a mixture of phase-shifted digital and narrow-band speech signals is supplied to the inputs of blocks 12 and 13.

 In block 12, analogue speech information is highlighted, while the phase-shifted digital signal does not interfere with block 12, since block 12 responds only to frequency.

 The narrow-band speech signal is suppressed in block 13 by a factor of B, that is, its effect on the reception of information in block 13 can be neglected.

 In block 13, synchronization with a phase-manipulated digital signal, its correlation processing and demodulation are performed. Moreover, in the receiver 13, due to the correlation processing, the narrow-band speech signal is suppressed by a factor of B, where B is the base of the phase-shifted digital signal, which virtually eliminates the influence of the speech signal on the reception of the digital signal.

 Blocks 8 and 13 are typical transmitter and receiver of phase-shifted digital signals and can be performed, for example, as is done in AS 300,946 H 03 C 3/40.

 The prototype method is based on the frequency separation of channels, when each radio line is allocated its own frequency band Δf, in which analog voice information is transmitted using the narrow-band (frequency) modulation method, while the secrecy and noise immunity of message transmission is not provided.

The proposed method provides simultaneous transmission of analog and digital information in the frequency band Δf allocated for a given channel, while digital information is transmitted by a signal that is formed due to phase manipulation of the input digital signal, the noise immunity and stealth of which is determined by its base (B), which in this case is determined by the ratio B = Δf / ΔF _c , where ΔF _c is the width of the spectrum of the transmitted digital signal, determined by the speed of information transfer.

 The lower the speed of transmitted digital information, the more B.

Let Δf = 10 kHz, ΔF _c = 10 Hz, then B = 1000.

 Thus, the proposed method provides an increase in the amount of transmitted information and the possibility of noise-immune and covert transmission of messages in accordance with the implemented base of phase-shifted digital signal.

 In addition, the simultaneous transmission of a narrowband speech signal and a phase-shifted digital signal provides masking of voice messages.

Claims (1)

A method of transmitting information based on the separation of communication channels by frequency, in which for each communication channel a frequency band Δf is allocated, in which analog voice information is transmitted using a narrow-band frequency modulation method, characterized in that in a given frequency band Δf in each frequency channel simultaneously With a narrow-band speech signal, low-speed digital information is transmitted, the signal of which is generated due to the phase manipulation of the input digital signal according to the pseudo-random law, which carries an hour the frequency of the generated phase-shifted digital signal is chosen equal to the average frequency of the spectrum of the narrow-band speech signal, and its clock frequency F _{t is} selected in accordance with the ratio F _t = Δf / 2, while both signals, narrow-band speech and phase-shifted digital, are summed and processed in common linear paths transmission and reception, and when receiving separate demodulation of the signals is carried out, while the demodulation of the phase-shifted digital signal is performed after its correlation processing.