SU828204A1 - Radio signal simulator - Google Patents

Description

The invention relates to simulators of radio signals and may find application for training operators of radio systems.

A known radio signal simulator containing 5 a master oscillator, which is directly and through a shaper of time diagrams connected to a pulse shape converter connected via an RF filter to an output unit, and 10 a carrier frequency generator [1].

A disadvantage of the known simulator is the low quality of simulating the movement of signals on the time axis.

The purpose of the invention is improving the quality of 15 imitations. Signals.

This is achieved by the fact that the simulator has a delay unit, and one of the outputs of the time-chart generator through the carrier frequency generator is connected to the first 20 input of the delay unit, the second input and output of which are connected to the pulse shape converter.

In addition, the delay unit has a multi-section delay line, a counter and 25 switches, while the output of the carrier frequency generator is connected to the input of the multi-section delay line, the output of each section of which is connected to the corresponding first input of the switch, the second inputs of which are connected through one of the outputs to the counter pulse shape converter.

The delay unit has a pulse shaper, a ramp generator and a threshold voltage level generating circuit, while the output of the carrier frequency generator is connected through a serially connected pulse shaper and a ramp generator to the first input of the threshold voltage level generating circuit, the second input and output of which are connected to pulse shape converter.

In FIG. 1 shows a structural diagram of a radio signal simulator; in FIG. 2 - delay node; in FIG. 3 - the same option; in FIG. 4 is a timing diagram illustrating a change in a period and a phase of a high frequency filling of a radio pulse.

The radio signal simulator comprises a master oscillator 1, a timing driver 2, a pulse waveform converter 3, a carrier frequency generator 4, a delay unit 5, an RF filter 6, an output unit 7.

The simulator of radio signals works as follows.

The signal of the master oscillator 1 is fed to the shaper 2 of the time diagrams, from the output of the latter to the converter 3 pulses are sent, the sequence of which corresponds to the time chart - the sequence of pulses of the simulated signal.

When the next pulse arrives from the driver 2 to the converter 3, the latter starts to form the leading edge of the simulated signal, converting the input pulse into a pulse signal, the leading edge of which changes according to the desired law, and the high-frequency filling parameters are set by the carrier frequency generator 4 and delay unit 5. The carrier frequency generator 4 receives a pulse signal from the shaper 2, after which pulses begin to form at the output of the generator 4, following each other with a given time interval, depending on the required period of the carrier frequency of the high-frequency filling of the simulated radio pulse signal. The output pulses of the generator 4 are supplied to the delay unit 5, where they are delayed for a certain time interval. If this interval is constant during the entire time the converter 3 generates a simulated signal, the carrier frequency of the radio pulse is constant, but if under the influence of control signals supplied to the delay unit 5 the interval changes from pulse to pulse, then the period of the carrier frequency turns out to be variable, which allows you to simulate a change in the carrier frequency of the radio pulses, a phase change - "phase incursion". The control signals to the node 5 are supplied from the conversion unit 3, which provides a change in the period of the carrier frequency and phase in a given section of the simulated signal.

The pulse signal generated by the converter 3 with a given law of envelope variation, with a carrier frequency and a high-frequency filling phase that is changed according to the required law, is fed to the output unit 7 through a radio-frequency filter 6, filtering out the spectrum components of the radio pulse signal generated by the converter 3 that are not included in the spectrum of the simulated signal.

In FIG. Figures 2 and 3 show implementation options for delay unit 5.

In FIG. 2, the delay unit 5 is implemented based on the delay line 8 with taps, the switch 9, and the counter 10. The delay unit 5 works as follows.

The pulse signal from the generator 4 of the carrier frequency is fed to the input of the delay line 8, at the outputs of which the pulses are delayed for predetermined time intervals. The switch 9, controlled by a counter 10, provides a delayed pulse from the outputs of the delay line 8 to the output of the block in the required sequence. The input pulse signals to the counter 10 are received from the Converter 3 as the formation of the radio pulse signal.

In FIG. 3, the delay unit 5 is implemented on the basis of a pulse shaper 11 of standard amplitude and duration, a ramp generator 12, a threshold unit 13 and a threshold setting unit 14. Its operation is illustrated by the diagram in FIG. 4, where a is the initial pulse sequence, b are the pulses at the output of the pulse shaper 11, c is the output signal of the generator 12, d is the threshold level at the output of block 14, e is the output pulse sequence of block 5.

In this case, the delay unit 5 operates as follows.

Upon receipt of the pulse from the generator 4 to the driver And (Fig. 4a), the latter generates a standard pulse in amplitude and duration (Fig. 46), which is supplied to the generator 12 of a ramp voltage. Upon reaching the linearly varying output voltage (Fig. 4c) of the generator 12 set by the block 14 of the threshold level (Fig. 4d), the threshold block 13 is triggered, from the output of which a pulse (Fig. 46) is output to the output of node 5 and then to the converter 3. Threshold the voltage level is set and changed in accordance with the required law with the help of the threshold setting unit 14, to which the control signal is supplied from the converter 3 in the process of signal formation.

Claims (3)

The signal of the master oscillator 1 is fed to the shaper of 2 time diagrams, from the output of the latter to the converter 3, pulses are sent, the order of which corresponds to the time pattern - the order of the pulse of the simulated signal. When the next pulse arrives from the generator 2 on the converter 3, the latter begins to form the leading edge of the simulated signal, converting the input pulse into a pulse signal, the leading edge of which changes according to the desired law, and the parameters of high frequency filling, frequency, and node 5 delay. The carrier frequency generator 4 receives a pulse signal from the imaging unit 2, after which, at the output of the generator 4, pulses begin to form, following each other with a predetermined time interval depending on the required period of the carrier frequency of the high-frequency filling of the simulated radio pulse signal. The output pulses of the generator 4 are supplied to the delay node 5, where they are delayed for a certain period of time. If this interval is constant during the entire time that the converter 3 simulates a signal, the carrier frequency of the radio pulse is constant, but under the action of control signals given to the delay unit 5 the interval varies from pulse to pulse, then the period of the carrier frequency turns out to be variable, which makes it possible to simulate a change in the carrier frequency of radio pulses, a change in phase — a "phase shift. The control signals to node 5 are supplied from conversion unit 3, which provides for a change in the carrier frequency and phase periods in a predetermined portion of the simulated signal. A pulse signal generated by converter 3 with a predetermined law of variation of the envelope, with the required carrier frequency and high-frequency filling phase, is fed to the output unit 7 through an RF filter 6, eliminating the components of the spectrum of the radio pulse signal generated by converter 3 that are not included in spectrum of the simulated signal. FIG. 2 and 3 are embodiments of node 5 delay. FIG. 2, a delay node 5 is implemented on the basis of a delay line 8 with taps, a switch 9 and a counter 10. In this case, the delay unit 5 operates as follows. The pulse signal from the carrier frequency generator 4 is fed to the input of the delay line 8, at the outputs of which the pulses are delayed for predetermined time intervals. The switch 9, controlled by the counter 10, provides for the output of a block of delayed pulses from the outputs of the delay line 8 in the required sequence. The input pulse signals to counter 10 arrive from converter 3 as a radio pulse signal is generated. FIG. 3, a delay unit 5 is implemented on the basis of a generator of II pulses of standard amplitude and duration, a generator of linearly varying voltage, a threshold unit 13 and a threshold setting unit 14. His work is illustrated in FIG. 4, where a is the initial emulsion sequence, b is the pulses at the output of the driver of 11 pulses, c is the output of the generator 12, d is the threshold level at the output of block 14, d is the output pulse of the continuity of block 5. In this case, the delay block 5 functions as follows in a way. When a pulse arrives from generator 4 to shaper 11 (Fig. 4a), the latter forms a standard pulse in amplitude and duration (Fig. 46), which is applied to generator 12 of a linearly varying voltage. When the linearly varying output voltage (Fig. 4e) of the generator 12 is set by the block 14 of the threshold level (Fig. 4d), the threshold unit 13 is activated, from which the pulse (Fig. 45) is output to the output of the node 5 and then to the converter 3 The threshold voltage level is set and changed according to the required law using the threshold setting unit 14, to which the control signal is supplied from the converter 3 in the course of signal generation. Claim 1. A radio signal simulator comprising a master oscillator, which is connected directly and through a time generator to a pulse shape converter connected via an RF filter to an output unit and a carrier frequency generator, characterized in that, in order to improve the quality of signal imitation, it has a delay node, while one of the outputs of the time diagrammer is connected to the first input of the delay node via a carrier frequency generator, the second input and output of which are connected transmitter pulse shape. 2. Radio signal imitator according to claim 1, characterized in that the delay node has a multi-section delay line, a counter and a switch, wherein the output of the carrier generator is connected to the input of a multi-section delay line, the output of each section of which is connected to the corresponding first switch input, the second the inputs of which through the counter are connected to one of the outputs of the pulse form converter. 3. The radio signal simulator according to claim 1, characterized in that the delay node has a pulse shaper, a linearly varying voltage generator, and a threshold voltage level circuit, wherein the output of the carrier frequency generator through the serially connected pulse shaper and the linearly varying generator This is connected to the first input of the voltage threshold circuit, the second input and output of which are connected to a pulse shape converter. Sources of information taken into account in the examination 1. USSR author's certificate No. 752456, cl. G 09B 9/00, publ. 1980 5 /} OK 2 On $ Lok 3  From f / yukl 3 Fig.Z