SU602953A1 - Time-probability converter - Google Patents

Description

(54) TIME-PROBABILITY CONVERTER

The drawing shows the block diagram of the described Converter time-to-t-ness.

The device consists of a generator of 1 clock pulses, generating commands to the converter 2 "code-probability, block 3 of the storage of the time interval and counter 4, counter 5, elements 6, 7, controlled by the corresponding outputs of block 3, element 8 and the overflow trigger 9.- The input of the element 8 is connected to the output of the converter 2 “time-accuracy”.

The device works as follows.

Before starting, all blocks and elements of the device are in the initial (zero) state, element 6 is open, the remaining elements are closed.

The operation of the device begins when the counter 5 is in the zero state. Converter 2 converts the binary number of counter 5 into probability, so that any n (n is an integer, n is $ 100) recorded in counter 5 corresponds to the probability () of the occurrence of the symbols "1 in the LiFell sequence generated by converter 2.

Thus, at the beginning of operation n 0, converter 2 generates a Bernoulli sequence with probability I 0, but in this case, counter 4 will not have time to fill and issue an overflow signal to trigger 9 until it arrives from the "end of interval" pulse 3.

At the end of the first cycle, block 3 writes the code "1 through element 6 into the counter 5, and by the beginning of the second cycle in the counter 5 the number n will be found. With a further increase in the cycle number, the number n accumulated in the counter 5 increases, the probability P increases the converter 2 and, accordingly, the overflow time of counter 4 is reduced. The beginning of each cycle is determined by the signal "start of interval, output by block 3. At this, the AND 7 element opens and from the output of converter 2 to counter 4 enters a Bernoulli follower awn probability of occurrence of individual characters which corresponds to the current state of the counter 5.

Depending on the duration of the interval being converted, the following cases are possible.

The converted time interval is less than the overflow time of counter 4. In this case, the counter 4 is filled until the output of the block 3 signal appears at the end of the interval supplied through the open element 6 to the counting input of the counter 5. The latter changes its state by one , and converter 2 forms a Bernoulli sequence with a new value of probability P. With the appearance of the signal "the end of the interval, the action of the signal" the beginning of the interval stops, the element And 7 closes, the generator 1 resets 4 is in zero position and prepares block 3 for the next cycle.

The converted time interval is greater than or equal to the overflow time of the counter 4, which corresponds to the appearance of the signal "the end of the interval before or simultaneously with the appearance of the overflow signal supplied from counter 4 to the overflow trigger 9. The last transition to the one state, the element And 6 is locked, and element 8 is opened, so that the Bernoulli sequence with a given probability P for the occurrence of symbols of units, outputted by converter 2, is transferred from the output of the device to the external devices. Thus, the probability P of the "1" symbols in the specified output sequence is directly proportional to the magnitude of the transformed time interval.

The use of block 3 for storing the time interval, counter 4, trigger 9 and element I 7 in their new relationship with converter 2, generator 1 and counter 5 made it possible to significantly increase the conversion speed:

the absolute, and the expense of replacing the two-step conversion scheme ("time-code - 1 stage," code-probability - II stage) with a single-stage ("time-accuracy); relative, determined by the conversion time, related to the entire Bernoulli sequence, containing up to several thousand characters. The latter circumstance is especially significant when using such converters in probabilistic computing machines, the specifics of which require multiple (up to several thousand hours) coding of the same value. The essential advantage of this preformer is that, once having determined the transformed value of the input (time) variable, the transformer can output this value as many times as desired. This makes it possible to increase the accuracy and speed parameters of probabilistic computing machines.

Claims (2)

1. Authors certificate of the USSR To 370717, cl. H 03 K 13/02, 1974. 2. Yakovlev V. V., Fedorov R. F. Stochastic Computers. Ed. “Machine building, Leningrad, 1974.