SU320063A1 - LIBRARY. E. Bobrov - Google Patents

Description

The proposed ferrite-transistor cell counter can be used in computer circuits, especially when building control devices, in automation and instrument engineering circuits.

The known counters on ferrite-transistor cells, for all their efficiency in terms of the number of cells in a stable state, require a rather complicated circuit for the expansion of all states.

The goal of the proposed invention is to reduce (the number of cells in the counter with the decoder and the tight coupling of the pulses at the outputs of the decoder to the counting pulse at the counter input. For this, the functions of the decoder on the two light-colored elements with the counter functions, and the upper two cells of the two The main circuit is entered into the first push-pull ring shift register, and the lower-russ cells is entered into the second push-pull ring shift register.

In addition, the special scheme of connecting the cells of two brown elements and mutually simple (not having the greatest common multiplier more than one) coefficients of recalculation of the shift registers significantly reduce the number of cells in the counter with the decoder and the pulses at all outputs of the decoder appear to be a clock in which the pulse to the input of the counter.

The drawing shows a diagram of the counter.

The counter consists of Q ferrite-transistor cells, has one counting input and requires for operation a four-cycle system of pulses ti, ti + i, ti + z and g + s, shifted RELATIVE

each other. The counter can contain no more than two feedbacks, each of which contains one cell Q + 1, Q + 2. Cells 1, 2, 3 .... i-1 .... L form one

a push-pull ring shift register with a conversion factor i and cells 1, ... Q form a second push-pull ring shift register with a conversion factor / V2. The counting input of the counter is connected to the windings of reading of all odd cells 1,3

...., 1-1, i + 1, .... JV-1, N + l, N + 3

/ V + 3, / -1, / + 1, Q-1 (excluding the feedback cell), forming a two brown circuit. Emitters of all odd cells first

The push-pull ring shift register is connected to the collectors of all the similar cells of the second shift register, and the resulting individual connections of the two light circuits can be connected to the outputs of the decoder. A collector of odd-numbered cells of the first register (1, 3 ... yV-1) is connected to the write winding of the corresponding even cell of the same register (2, 4 ... N), the collectors of which, in turn, are connected cells (3, 5, t-1, i -} - l, ... N-1, 1). The collectors of all the odd cells of the second register, ... Q-1, except that they are each connected to the emitters of all the odd cells of the first register, are connected to the write winding to the corresponding even cells of the second register (L + 2, N + 4, .. ., j ..., Q). Collectors of even cells (, N + 4, ... Q) are applied to the winding of the record of the corresponding right cells of the second shift register L + 3, ... / - 1, +, Q-1, ... L + b To the read windings all even cells of shift registers {2, ...., i, ... N-2, N, N + 2, .... /, .... Q) a constant clock ti + i is applied, going along time is always within the cycle ti (although it is also possible to connect this field to the source of the biasing current). The outputs of the circuit are the individual connections between the odd cells of the first and second shift registers (marked with dots in the drawing). One or two output circuits can be connected to one or two feedback cells Q + 1, Q + 2, and the output of the circuit is applied to the windings or write windings of the Q + 1, Q + 2 cells. The read inputs of these cells are connected to the read input ti + 2 and ti + 3 cycles, one after the other following ti + i. The collector Q + 1 cells can be nodan on the winding of the one and the winding of the record of the other cell of the upper Rus of the two light circuit. The collector Q + 2 cells are similarly connected to the cells of the lower rus. Installation circuits ensuring that only one unit is entered in the first and second registers are not shown in the drawing for simplicity.

For normal operation, an initial meter installation is performed. If we assume that the installation provides for recording the units in the first and L / -f 1st cells of the counter, then, but the arrival of the first pulse at the counting input (reads all the cells belonging to the two positives at the same time). The N + 1 cells and the remaining cells are not prepared for underscore.As a result, the output current impulses but individually in the individual communications of cells 1 and 1, which corresponds to deciphering one of the steady states of the counter. Simultaneously operation in a pair of N + 1 and 1 cells causes record one The eggs are in the corresponding even cells of the first and second shift registers. Of these cells, the units are fed but also ti + i to the odd cells of the first and second registers, where they are before the next pulse arrives at the counting input. Next, the work proceeds in the same way. that the division ratio (recalculation) of the second register Kz is less than Ki, then, according to the Kz-Ky, the counting pulse triggers Q-1 and the corresponding cell in a two-circuit scheme. In cycle, the Q cell will work, ensuring that units are located in the N + 1 cell and the operation cycle of the second shift register closes. Similarly, the first register cycle after the / Ci-ro counting pulse is closed. When the (KiKz) counting impulse arrives, the N-1 and Q-1 cells are triggered simultaneously in a two-light circuit. An individual link pairing these cells can be entered into the Q-I-1 and Q + 2 cells, which serve as a delay in the feedback link. These cells (in ticks) ti + z and g + s, respectively, will give impulses that ensure the elimination of the required number R of steady states, so that Kc Ki-Kz is R, where / Co is the counting factor.

It should be noted that if K.c is represented as a product of Ku Ki-K2 and KiKz are mutually simple, then feedback cells Q + 1 and Q-I-2 are not required.

Subject invention

Claims (2)

1. A pulse counter, made on ferrittransistor cells, containing two two-stroke ring shift registers, characterized in that, in order to simplify the device and increase speed, each emitter of all cells connected to the counting tact bus of one register is connected to the collectors of all similar cells another register and connected to the “output bus. 2. A counter according to claim 1, characterized in that, in order to obtain a conversion factor that is different from the product of the register conversion factors, feedback cells are connected to the counter, connected at the input to the output with the output of the counter, and at the output with the windings, quenching and Understand the corresponding register cells. ° t., Post-full tact about t- Account Log Permanent,:, f77 {7n t t