SU1451872A1 - Discrete signal transceiver - Google Patents

Abstract

This invention relates to radio. The purpose of the invention is to improve noise immunity. The device contains transmitting and receiving sides. On the transmitting side, a signal is not generated that is manipulated in frequency (with an increasing or decreasing frequency of the carrier oscillation) in accordance with the polarity of the messages from one source of discrete signals and the initial phase, as well as being manipulated according to the relative principle from the other source of discrete signals. At the receiving side, the received packets are divided into two groups by increasing and decreasing the frequency of the carrier oscillation and at the same time converting them into signals of the same constant frequency over the duration of all packages for both groups. The goal is achieved due to the high reliability of the transmission of discrete signals, which is important when organizing communications in multipath conditions. 3 il. § (L s

Description

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The invention relates to radio and can be used in information transmission systems operating in multipath conditions.

The purpose of the invention is to improve noise immunity.

Figure 1 shows the electrical circuit diagram of the transmitting side of the proposed device; Fig. 2 is a structural electrical circuit of the receiving side of the proposed device; Fig. 3 is a diagram of a clock extraction unit.

A device for transmitting and receiving discrete signals on the transmitter side generates 1 clock pulses, a controlled oscillator 7. carrier oscillations, a generator 3 signals with a linearly increasing amplitude, a generator 4 signals with a linearly decreasing amplitude, a switch 5, a frequency modulator 6, a phase handler 7, relative recoding unit 8, the first 9 and second 10 sources of discrete signals, and on the receiving side the first 11 and second 12 mixers, the reference generator 13 with a linearly increasing frequency, the reference generator 14 linearly decreasing frequency, first 15 and second 16 band-pass filters, frequency detector 17, clock extraction unit 18, first 19 and second 20 amplitude detectors, comparison unit 21, adder 22, demodulator 23, first 24 and second 25 decisive blocks are the first 26 and second 27 register blocks.

In addition, the clock pulse allocation unit 18 comprises a double-field rectifier 28, a differentiation unit 29 and a driver of 30 clock pulses.

The demodulator 23 contains a delay line 31 and a phase detector 32.

The device on the transmitting side works as follows.

The clock pulse generator 1 generates short pulses with a frequency equal to the duration of an elementary burst and is intended to synchronize generators 2,3 and 4. Parcels from the second source 10 of discrete signals to be transmitted are sent to the third control input of the switch 5. In accordance with the polarity of the parcels, the switch 5 connects to the first input frequency

modulator 6 generator output 3 signal with a linearly increasing or generator 4 signal with a linearly decreasing amplitude. For example, with a positive polarity of the parcels, the switch 5 connects the output of the generator 3 of the signal, and if negative, the output of the generator of the 4 signal. The frequency modulator 6 output changes the frequency of the carrier oscillation with the frequency fc received at its second input from the output of the generator 2. The frequency of the oscillation at the output of the frequency modulator 6 changes smoothly in the interval of sending from to to fo + + Fcj (increasing) or from f + Fq to fo (decreasing) depending on the increasing or decreasing voltage of the frequency modulator 6 arriving at the first input. From the output of the frequency modulator 6, the signals are sent in frequency (with increasing or decreasing). frequency carrier wave for sending interval duration) are applied to a second input faz.ovogo manipulator 7, a first input of which receives from the first source ps5sylki 9 binary signals proschedshie unit 8 relative transcoding (introducing relativity). And phase manipulated torus. 7, the initial phase of the carrier oscillation is manipulated with a varying frequency over the interval of the parcel in accordance with the polarity of the parcels from the first source 9 discrete signals: with a positive polarity of the parcel, for example, the initial phase is 4, and with a negative 180, Thus , from the output of the phase manipulator 7, the output of the transmitting side receives a signal that is manipulated in frequency (with an increasing or decreasing frequency of a silent oscillation) in accordance with the polarity of the parcels from the second source 10 discrete signals and the initial phase, as well as manipulated on the relative principle of the premises from the first source of 9 discrete signals.

At the receiving side, the received signal is fed to the first inputs of the first 11 and second 12 mixers and often connected in series 3 and block

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a detector 17 and a block 18 for extracting clocks. Block 18 allocation, clock pulses generates short pulses corresponding to | the signal bounds, and serves to trigger the reference oscillators 13 and 14 and synchronize the decision blocks and 25. The frequency detector 17 converts the frequency of the input IQ signal bursts into a voltage with zero threshold corresponding to the frequency fo +, the full-wave rectifier 28 is made using a bridge circuit on diodes. Differentiating unit 29 consists of 15 KS-circuit. Shaper 30 short pulses forms durations with a repetition rate equal to the duration of the elementary parcel. At the receiving side, the received parcels are divided into two groups in ascending and descending frequencies of the carrier oscillation and simultaneously transforming them into positons of a signal with a constant frequency of 25 times the duration of all the parcels for both groups. For this, the reference generators 13 and 14 oscillations are synchronized with the incoming parcels, respectively, with increasing and decreasing frequency. The average frequency fc of the oscillations is shifted relative to the average frequency fr of the transmitted signal, and the laws of variation and frequency deviation are the same as on the transmission side. At the same time, at the output of the bandpass filters 15 and 16, whose bandwidth is the same, oscillations with a frequency equal to the difference between the average 40 frequencies of the received signal and the reference oscillation f are separated. Mixers 11 and 12 are insensitive to the phase of the received signals, therefore the initial phase of the band filters 45 ° 15 and 16 saves the phase of the bursts of a signal transmitted to the line by the transmitting side. If at this time interval the signal is present at the output of one of the band 50 filters 11 (12), then at the output of the other band filter 12 (P) it is absent (there will only be interference). Further, separated and transformed

phase-shift signals according to the phase comparison method. In the bursting unit 25, controlled by the clock pulses, parcels are formed that correspond to the transmission of discrete signals from the first source. Further, these parcels arrive at the first recording unit 26 (this may be a printing device, a display). At the same time, parcels are received from the second source I) of discrete signals. For this, the converted signals are sent to comparison unit 21 through amplitude detectors 19 and 20. In essence, bandpass filters 15 and 16, amplitude detectors 19 and 20, and comparison unit 21 are a frequency detector that receives frequency-controlled ( with increasing and killing) the signal sendings. According to the result of the comparison, in the decision block 24, respectively received parcels from the second source 10 discrete signals are formed, which are fed to the second recording unit 27 (printer, display).

Thus, the use of an inventive shadow allows to significantly increase the noise immunity of the device without additional power consumption, while maintaining rapid synchronization, which reduces the time of the communication session.

The proposed device can be used in various receivers of transmitters with a sufficiently high reliability of transmitting discrete signals, which is especially important when organizing communications in conditions of multipath.

Summary of the Invention A device for transmitting and receiving discrete signals, containing on the transmitting side first and second sources of discrete signals, a clock generator, a frequency modulator and a phase manipulator, and a receiving mixer, the first mixer, the first band-pass filter, which you connected to first entrance

the signal bursts are combined into an adder-55 sum whose output is connected

the torus 22 into a continuous sequence of signals sent to the input of the demodulator 23. The demodulator 23 receives

with a demodulator input, a second-pass filter and a frequency detector, characterized in that, in order to improve the noise immunity

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phase-shift signals according to the phase comparison method. In the bursting unit 25, controlled by the clock pulses, parcels are formed that correspond to the transmission of discrete signals from the first source. Further, these parcels arrive at the first recording unit 26 (this may be a printing device, a display). At the same time, parcels are received from the second source I) of discrete signals. For this, the converted signals are sent to the comparison unit 21 through the amplitude detectors 19 and 20. Essentially, the bandpass filters 15 and 16, the amplitude detectors 19 and 20, and the comparison unit 21 are a frequency detector that receives frequency-controlled increasing and killing) the signal sendings. According to the comparison result, in the decision block 24, respectively received 10 parcels of discrete signals from the second source are formed, which are fed to the second recording unit 27 (printer, display).

Thus, the application of the invention allows to significantly increase the noise immunity of the device without additional power consumption, while maintaining rapid synchronization, which reduces the time of the communication session.

The proposed device can be used in various transceiver devices with a sufficiently high confidence in the transmission of discrete signals, which is especially important when organizing communications in multipath conditions.

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Formula of the invention A device for transmitting and receiving discrete signals, comprising on the transmitter side first and second sources of discrete signals, a clock pulse generator, a frequency modulator and a phase manipulator, and on the receiving frequency a first mixer, the first band-pass filter whose output is connected to the first by the entrance

adder whose output is connected

with a demodulator input, a second band-pass filter, and a frequency detector, characterized in that, in order to improve noise immunity.

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on the transmitter side, a signal generator with a linearly increasing amplitude, a signal generator with a linearly decreasing amplitude, a controlled carrier oscillator, a relative transcoding unit, and a switch, the output of which is connected to the first input of the frequency modulator, the second input of which is connected to the output of the controlled oscillator carrier oscillations, the input of which is connected to the output of the clock generator, with the input of the signal generator with a linearly increasing amplitude JI with the input of the signal generator with lin A killer amplitude, the output of which is connected to the first input of the switch, the second input of which is connected to the output of the signal generator with a linearly increasing amplitude. The output of the first source of discrete signals is connected to the first input of the phase controller, the second input which is connected to the output of the frequency modulator, and the output of the second discrete source: signals connected to the third input of the switch, and on the receiving side a reference oscillator is inserted with a linearly increasing frequency, reference oscillator with linearly decreasing frequency, second mixer, clock selection unit, two recording blocks, two decision blocks, block

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comparison, two amplitude detectors, the outputs of which are connected to the corresponding inputs of the comparison unit, the output of which is connected to the first input of the first decision unit, the second input of which is connected to the second input of the second decision unit, to the input of the reference generator with a linearly increasing frequency, to the input of the reference generator with the linearly killing frequency and with the output of the clock extraction unit, the input of which is connected to the output of the frequency detector, the input of which is connected to the first inputs of the first and second mixer the outputs of which are connected by the inputs of the first and second band-pass filters, respectively, the output of the reference generator with a linearly increasing frequency is connected to the second input of the first mixer, the output of the reference generator with a linearly decreasing frequency is connected to the second input of the second mixer, the output of the second band pass filter is connected to the input The second amplitude detector and the second input of the adder, the first input of which is connected to the input of the first amplitude detector, the output of the demodulator is connected to the first input of the second decisive a block, whose output is connected to the input of the first registriruyu-, present unit, an output of the first casting unit is connected to the input of the second recording unit.

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Claims (1)

Formula invent A device for transmitting discrete signals, containing on the transmitting side the first and second sources of discrete signals, a clock pulse generator, a frequency modulator and a phase manipulator, and at the receiving frequency, a first mixer, a first bandpass filter, the output of which is connected to the first input of the adder, the output of which is connected with a demodulator input, a second band-pass filter and a frequency detector, characterized in that, in order to increase noise immunity, a signal generator with a linearly increasing amplitude, a linearly decreasing signal generator, a controlled carrier oscillator, a relative transcoding unit and a switch whose output is connected to the first input of the frequency modulator, the second input of which is connected * ίο to the output of a controlled carrier oscillator, the input of which is connected to the output of the clock pulses, with an input of a signal generator with a linearly increasing amplitude of 15 • and with an input of a signal generator with a linearly decreasing amplitude, the output of which is connected to the first input to switch, the second input of which is connected to the output of the signal generator 20 with a linearly increasing amplitude, while the output of the first source of discrete signals through the relative transcoding unit is connected to the first input of the phase, manipulator, 25 The second input of which is connected to the output of the frequency modulator, and the output of the second source is discrete signal is connected to the third input of the switch, and on the receiving side 30 introduced a reference oscillator with a linearly increasing frequency, a reference generator with a linearly decreasing frequency, the second mixer clock extracting unit, two registriruyu- _{3 £.} main blocks, two decision blocks, a comparison block, two amplitude detectors', the outputs of which are connected to the corresponding inputs of the comparison block, the output of which is connected to the first input of the first decision block, the second input of which is connected to the second input of the second decision block, with the input of the reference generator with linearly increasing frequency, with the input of the reference oscillator with a linearly decreasing frequency and with the output of the clock selection block, the input of which is connected to the output of the frequency detector, the input of which is connected to the first inputs and the first and second mixers, the outputs of which are connected to the inputs of the first and second band-pass filters, the output of the reference generator with a ramp frequency is connected to the second input of the first mixer, the output of the reference generator with a linearly decreasing frequency is connected to the second input of the second mixer, the output of the second band-pass filter connected to the input of the second amplitude detector and to the second input of the adder, the first input of which is connected to the input of the first amplitude detector, the output of the demodulator is connected to the first input of the second casting unit, whose output is connected to the 'input of the first-conductive filing unit, an output of the first casting unit is connected to. the input of the second recording unit.