SU911526A1 - Device for multiplying unit-counting codes - Google Patents

Description

The device is the first 1 and the second 2 inputs, the first and second counters 3 and 4, the first and second blocks 5 and 6 of the elements I, the adder 7, the element 8 I.5

In the device in the counter 3, it is connected with the inlet I of the device, the input of the counter 4 is connected to the input 2 of the device, the output of the counter 3 is connected to the first input of the block 5 And elements, the second input tO of the block 5 And elements connected to the input

2 devices, the output of the counter 4 is connected to the first input of block 6 And elements, the second input of which is connected to the input I of the device, the output of block 515 of elements And is connected to the first input of adder 7, the booster of which is connected to the output of block 6 elements And, the first Bxoti of element 8 And connected to the input 1 of the device, the second input is ele-

menga 8 And connected to the input 2 of the device, the output element-8 And connected to the third input of the adder 7.

The device works as follows, 25

Suppose it is necessary to carry out a transmutations of two sequences of pulses and N, which are represented in FIG. 2. Before starting work counters

3 and 4, the adder 7 is set to zero zero. The first impulse 1 posLocation J will be recorded in counter 1 via code 1

and, I will affect the second input of block 6 of the AND elements, allow the rewriting of the code from counter 4 to the adder 7. But also

as D counter 4 is zero code, then the code in adder 7 will remain unchanged.

Upon arrival of pulse 1 at input 240

Ml-sequences will be written to counter 4, and the same pulse will allow overwriting 1 from counter 3 through the open first block 5 of the elements AND to the adder 7. Thus, 45 at the end of pulses 1 and 1 in counters 3 and 4 will be recorded 1, and in adder 7 is written.

The second pulse 2 of the sequence N will write the number two to the counter 3 and rewrite 1 from the counter 4 to the adder 7, through the open second block 6 of the elements I, i.e., the number will be established in the adder 7. The second impul1, with 2 consecutive; will write down the color of the number in counter 4 and rewrite the level two of the counter 3 into the adder 7 chorgs open first block 5 of the elements I, i.e. Adder 7 will set the number.

Further operation of the device is similar, i.e. Each input impulse, the input to the corresponding input, provides a count of the number of arriving impulses in one of the counters and the transfer of a previously recorded code. another counter in the adder, where the successive addition of the transmitted codes occurs. Thus, in the adder 7 there will always be a code, a number equal to, the product of the number of incoming pulses at the inputs I and 2.

In the case, if the pulses are synchronized, as shown in FIG. 2, i.e. occurs at the same time, the operation of the device as a whole is similar, except that in the adder 7 one additional additional pulse is added each time, indicating the simultaneous arrival of the input pulses.

Example. The first two input pulses I and 1, while simultaneously acquiring, permit the rewriting of codes from counters 3 and 4 to adder 7 through open blocks 5 and 6 of elements I. But, as the counters are in the zero state, nothing will be written to adder 7. These same pulses, arriving simultaneously, will cause the appearance of a pulse at the output of element 8 A, which will be written to adder 7, i.e. . The same pulses with the trailing edge will be written one by one into the strips 3 and 4. The second pulses 2 and 2 allow rewriting of the units from counters 3 and 4 to the adder 7, where the 1 + 1 + 1 3 operation will occur and add one more pulse formed on the probe element 8 I. Further operation of the device is similar, i.e. input pulses provide a rewrite of the previous states of counters 3 and 4 into adder 7, where they are sequentially added and the unit is added in each taKTo to adder 7. It should be noted that in the synchronous arrival mode of the input pulses adder 7 must have a corresponding time delay in its inputs providing the addition of all three signals.

Thus, the device is compared to (photo-thiam does not have frequency multipliers, both pulse sequences are fed one at a time, and the multiplied pulses can arrive simultaneously or at different times.

Claims (2)

1. USSR Author's Certificate No. 579616, KiuGoe F 7/39. 1976. 2. USSR author's certificate N9 45882-6, cl. 006 F 7/52, 1972 (prototype).