SU584426A1 - Radio signal simulator - Google Patents

Description

(54) RADIO IMITATOR

one

The invention relates to computing and to be used in simulating a radio signal such as "signal + noise or only" noise.

Known radio signal simulator, containing a noise generator, a delay line and adders. However, the known simulator does not allow receiving signals of complex shape. The closest technical solution to the invention is a radio signal simulator containing a switch, the first input of which is connected to the output of a random number sensor, and the outputs through the first and second nonlinear converters are connected to the inputs of the first and second counters, respectively, the outputs of which are connected to the second and third inputs switch, respectively {2. This simulator is characterized by the impossibility of obtaining alternating signals of the type "signal + noise" and only "noise with specified statistical laws determining the intervals of the sequence.

The aim of the invention is to extend the functionality of the simulator by providing the possibility of obtaining alternating processes of the form "signal + noise and" noise with predetermined statistical laws defining the intervals of each type of signal. In the proposed simulator, this is achieved by the fact that it contains

pseudorandom number generator, first and second valuation units, shift register, key and adder, the output of which is the simulator output, the first input through the key and the first valuation unit, and the second input through the second valuation unit and the shift register are connected to the output of the pseudo-random number generator, the control input of the key is connected to the output of the first counter.

The drawing shows the block diagram of the proposed simulator.

It contains a random number sensor 1, the output of which is through switch 2, nonlinear converters 3 and 4 are connected to the inputs

counters 5 and 6, the outputs of which are connected to the inputs of switch 2. In addition, the simulator contains blocks 7 and 8 of normalization, key 9, 10 pseudo-random number generator, the output of which is through block 7 of normalization and key

9, as well as through the shift register 11 and the normalization unit 8 is connected to the inputs of the adder 12, the output of which is the output of the simulator. From the output of sensor 1 do random

numbers Depending on the state of the switch 2, the first number is fed to the input of the converter 3 or 4. Suppose that this number goes to the input of the first nonlinear converter 3, where the non-linear conversion method is the inverse distribution function.

a random number is generated with a given distribution law. This number is recorded in counter 5 and determines the duration of the open state of the key 9 and, therefore, the duration of the arrival at the first input of the adder 12 random numbers from the geerator 10, amplified in block 7 in accordance with the specified conditions for generating signals (i.e. according to a given average power). Key 9 is open during read cycles from counter 5 of the random number received from converter 3. At the same time, switch 2 disconnects the inputs of converters 3 and 4 from sensor 1 during these cycles. In addition, from the generator 10, the numbers go to register 11, providing the time shift of the sequences and the inputs of the adder 12 by an interval longer than the autocorrelation interval. The rationing unit 8 provides the rationing (predetermined average power of the sequence).

Thus, the noise is simulated, and in general, the output of the adder 12 is the signal + noise sequence for the time when the key 9 is open, i.e. in accordance with the law of the signal + noise signal durations.

After cleaning the counter 5, the first “zero” from its output connects the sensor 1 to the converter 4 and closes the key 9, with the result that the sequence “noise” follows from the output of the adder 12. The random number in converter 4 is subjected to a conversion similar to that in block 3, but for its own distribution function. The number obtained in converter 4 is written to the bis output counter of the latter begins to be read to the input of switch 2. At the same time, switch 2 disconnects sensor 1 from the inputs of converters 3 and 4.

As a result, the output of block 8 receives "noise for a period of time determined by the law of the distribution of intervals between sigpals (for telephone signals, durations of pauses).

After cleaning the counter 6, the first zero from its output connects the sensor 1 to the input of the converter 3, and the operation of the simulator proceeds as described.

The use of the proposed simulator makes it possible to increase the efficiency of research related to the optimization of signal processing methods, parameters of the AGC systems, voice detection devices and others, as well as allows the investigation of multichannel signal transmission systems and simulate sequences of group signals in noise.

formula of invention

A radio signal simulator containing a switch, the first input of which is connected to the output of a random number sensor, and the outputs through the first and second nonlinear converters - to the inputs of the first and second counters, respectively, whose outputs are connected to the second and third inputs of the switch, respectively, characterized in that in order to expand the functionality of the simulator due to the formation of alternating processes such as "signal + + noise and" noise, the simulator contains a pseudo-random number generator, the first and second blocks are normal the shift input, the key and the adder, the output of which is the simulator output, the first input through the key and the first valuation unit, and the second input through the second valuation unit and the shift register are connected to the output of the pseudo-random number generator, the control input of the key is connected to the output of the first counter.

Information sources,

taken into account in the examination

1. USSR author's certificate No. 470905, cl. P OZV 29/00, 1974..

2. USSR author's certificate No. 507874, cl. G 06G 7/26, 1974.