SU879755A2 - Sensor of random equal-probability time intervals - Google Patents

Description

(54) D. TCHIK OF RANDOM UTILITY CURRENT TEMPORARIES The invention relates to computing and can be used to construct special calculators and to simulate the reliability of electronic equipment. A random random time intervals sensor is known, which contains two clock generators, a synchronization unit, a generator of a Poisson pulse flow, two triggers, two AND elements, and an OR element. The generator output of the Poisson flow and the pulses is connected to one of the clock of the synchronization unit, the input of the second clock generator and one of the inputs of the first trigger, the second input of which is connected to one of the inputs of the other trigger, and the output with one of the inputs of the first element And the second input of which is connected to the output of the second clock generator, the output of the first element AND is connected to one of the inputs of the OR element, the second input of which is connected to the output of the first clock generator 's pulse, and the output - to one of the inputs of the second flip-flop, whose output is the output of the whole device, and to one input of the second element interval, and the other input of which is connected to the output of the second flip-flop. The output of the second And element is connected to one of the inputs of the synchronization unit, the output connected to the input of the first clock pulse generator 11. However, this device does not allow to obtain rectangular pulses with discretized random equal durations. The purpose of the invention is to extend the functionality by obtaining rectangular pulses with discretized random equal durations. The goal is to achieve that, in a random equal-period time interval sensor, containing a generator of a Poisson pulse flow, the first clock pulse generator whose output is connected to the first input of the first element I, the second input of which is connected to the output of the first trigger, the output of the first element And connected to the first input element OR, the second input of which through the second clock pulse generator is connected to the output of the synchronization unit, the first input of which is connected to the output of the second element And,

the first input of which is connected to the output of the OR element and the first input of the second flip-flop., the second input of which is connected to the second input of the first flip-flop, and the output of the flip-flop is connected to the second input of the second And element, additionally introduced a frequency divider, a trigger and an And element whose output is connected to to the input of the first clock pulse generator, to the second input of the synchronization unit and to the first input of the first trigger, the first input of the additional element I is connected via a frequency divider with the second input of the first trigger, and the second one od via an additional trigger generator connected to the output Poisson stream of pulses.

The essence of the invention is that polling pulses are generated from the input deterministic clock pulse sequence by dividing its frequency, and by converting the input clock pulses and Poisson-stream pulses, a random binary sequence is formed that synchronizes the operation of the entire device.

The drawing shows the functional diagram of the sensor.

The sensor contains a Poisson flow generator 1, pulses, 2 and 3 clock pulse generators, synchronization unit 4, element OR 5, elements AND 6-8, triggers 9-11, frequency divider 12, bus 13 clock pulses and output bus 14 ..

The device works as follows.

The clock pulses on the bus 13, arriving at the input of the divider 12, are converted into polling pulses at its output and, arriving at one of the inputs of the And 8 element, are converted at its output into a random binary sequence. The first impulse of a random binary sequence triggers both oscillators 2 and 3 and simultaneously flushes trigger 9, preventing the generator from generating its own impulse 2 through element OR 5 to S-input of trigger 10 and through element AND 7 to stop input of synchronization unit 4. The first pulse .c divider 12, arriving at the R input of the trigger 10, forms the leading edge of the first output pulse. The same impulse transfers trigger 9, preparing element Ib for impulse passing from generator 2, if generator 3 is not started before the previous polling pulse appears, the second impulse of random binary sequence again flips trigger 9 and closes element 6, synchronizes generator 2 but does not affect the operation of generator 3, since block 4 starts the generator 3 with a random pulse; the binary sequence from the output, -jieMeHTa And 8 only after the stop signal, which is generated by the pulse from the output of the element OR 5. This same pulse, being fed to the S input of the trigger 10, forms the trailing edge of the output pulse of random duration.

Since before the appearance of the first polling pulse, the generator 3 was started, its second pulse, passed through the element OR 5, is fed to the input of the trigger 10 and forms the trailing edge of the first output pulse of random duration. The same impulse from the output of the element OR 5 will pass through the open element AND 7 to the input of the stop of the synchronization unit 4, which will ensure the restart of the generator 3 with the next impulse of a random binary sequence.

The second impulse polling from the output of the divider 12, throwing the trigger 9, will open the element And b, and throwing the trigger 10, will form the leading edge of the second output pulse of random duration. The back front of this pulse will form its own clock pulse from generator 2, since after the pulse, there was not a single pulse of random binary sequence that would start generator 3 and forbid the passage, and pulse from generator 2 through element 6. will continue similarly.

Thus, in comparison with the known, this device allows to additionally receive rectangular pulses with discretized random equipotential durations. Moreover, the number of discrete durations can be easily adjusted from 1 to N by changing the division factors of the divisor -.

Claims (1)

1. USSR author's certificate No. 794627, C. 07 C 15/00, 1979,