SU338905A1 - CORRELATION COUNTER ELECTRIC PULSES - Google Patents

Description

.The proposed correlation counter of electrical pulses to be used in studying the probabilistic nature of two electrical loads or two other different correlated quantities.

Correlation pulse counters are known for investigating atmospheric transfers. Also known are devices for calculating the calculation of the altitude distribution of wind waves in the sea over predetermined periods. These devices provide a correlation table.

However, such devices need a large number of output counters depicting a correlation table, with the usual tendency to divide the field of measurement of probability values into as small ranges as possible.

With the same number of divisions K by both coordinate axes of the field of measurement of probability values, the number of necessary output counters in is equal to / C. The value of K is also characterized by the amount of information removed and processed to obtain correlation characteristics.

The purpose of the invention is to simplify the determination of the correlation characteristics of two probabilistic values.

pulses additional blocks are introduced that multiply the number of pulses perceived by the counters of the input pulses during the measurement interval; summation of the received works with indication on the electromechanical counter.

The calculation of the correlation characteristics is carried out according to the output of electromechanical output meters, the number of which is equal to (). In this case, the readings 2 / g of the output counters depict tables of distributions of the two, their probabilistic values. (2 / g + 1) -th electromechanical counter shows the sum of multiplications.

A correlation counter circuit is shown in the figure.

The counter contains two counters 1 n 2 input pulses with keys 3 and 4, the state of which is determined by the time interval generator 5. An additional code 6 counter with an output matching circuit 7 is connected to the counter /, MEMORY 8 register 8 and the additional counter code 9 with a matching circuit 10 at the output and a key 11 at the entrance. The key // switches pulses of the generator of counting pulses 12 and is common to counter 9 and the counter of the sum of products 13. In addition, the decoders 14, 15 and electromechanical distribution counters 16, 17 are included for recording the distribution of probability values.

The overall control of the circuit is carried out by the control unit 18.

The device can work in any code. Assume that the device has been built to perform operations in binary code. All counters 1, 2, 6, and 9 n pterHCTp Pa. mi 8 have the same number of bits. The maximal number that can be registered in any of them, L (). Matching schemes 7 and 10 generate an overflow signal when code 7 (- () is detected in counters.

The device operation consists of two standards. In the nepiBOM stage, the duration of which is determined by generator 5, there is an accumulation of the number of input signals i and / in the counter / and 2. In the second stage, the accumulation results f and / in the counters 16 and 17 are recorded. the product of the current values of ij and the summation of these products is calculated, i.e., the calculation of the current value of the sum.

In the initial state, all counters I, 2, 6, and 9. and memory register 5 are cleared. The control unit 18 cyclically turns on the generator 5, the open keys 3 and 4. During the counting interval, the counters 1 and 2 are filled with pulses from inputs I and II. The number of pulses / and /, accumulated respectively in counters 1 and 2, is the code of the average value of the measured value for the counting interval.

At the end of the interval, the keys 5 and are locked. At the command of the control unit 18, the cell of the decipherors 14, 15 is triggered, which corresponds specifically to the output in the counter 1, 2, and sends an impulse to the corresponding TS; counter 5 to from counter 2 to register 8 and counter 9. In this case, additional codes of numbers recorded in the counters and 2 are transferred to counters 6 and 9, i.e., if there were binary codes in counters 1 and 2 i and /, then in the counters 6 vi 9 there appear the additions of these codes to; (2 ™ -1), i.e. the codes (2 ™ -) - i and () - /.

After the information has been transferred to counters 6 and 9, control unit 18 suppresses the recording of counters 1 and 2, preparing them again for counting the input pulses during the next counting interval. In counters 6, 8, and w 13, the second stage of operation begins — the calculation of the product and the summation of it. This is done as follows: the control unit 18 opens the key 11, and the pulses of the generator 12 begin to flow in parallel to the counters 9 and 13. As in the counter 9, the code (2 ™ -) - / is already recorded, then after passing / pulses to the counters 9 To 13 the circuit will work, the master 10, the signal of which adds a unit to the counter 6 and enters the control unit 18. The latter suppresses the recording of the counter P and produces a new entry to the counter 9

From memory register 8. Thus, after / Pulses counted by counters 9 and 13, code (2 ™ -1) - / appears again in counter 9. To overflow counter 9, it will again require pulses, after which the coincidence circuit 10 is triggered, and again adds one to counter 6. Then the process repeats until the overflow enters counter 6. Then the signal of the ow circuit; In control unit 18, which locks key 11, stopping the flow of pulses to counters 9 and 13. Since code 6 () -i was recorded in counter 6, counter 6 overflows after it has been generated by circuit C; E. After i cycles of the counter 9. Taking into account i.mpulsy from key // arrive simultaneously in counters 9 and 13 and for each work cycle the counter through a key

passes / Impulses, the total amount of impulses arriving at counters 9 and 13 in one single stage of transmission is equal to i-j. Since the counter 13 has no chains of enlarging, the summation of products takes place in it.

Simultaneously with locking the key 11, the control unit 18 extinguishes the counters 5 and 5 and the memory register 8, returning the circuit to its initial state.

Subject invention

1Korrell 1Zionny counter electric pulses, containing two channels, each of which is made in the form of sequentially

a connected input key, an input pulse counter, a deflector, an electromechanical counter, as well as a control unit, the outputs of which are connected to the input pulse counters and dephaser,

and the input through the interval generator is connected to the input key-m, characterized in that, in order to simplify the device, it further comprises a counting pulse generator, a key, a counter of the sum of products,

and the first channel contains an additional code counter connected to the corresponding coincidence circuit, some inputs of the additional code counter are connected to the input pulse counter, others to the control unit, the output of the coincidence circuit is connected to the control unit, the second channel contains an additional code counter connected to the corresponding circuit match, the inputs of the additional user code

through an additional Bined-in register, the memory is connected to the corresponding outputs of the input pulse counter, one input of the additional code counter and the output of the matching circuit are connected to the control unit; the output of the generator of counting pulses is connected via an additional key from the input of the counter of the sum of products and the counter of the additional code of the second channel; the second input of the additional key is connected