SU1091347A1 - Reversible pulse counter - Google Patents

Abstract

REVERSIBLE COUNTERS PULSES containing the input bus and p bits, each of which contains three ternary elements, output and installation bus, the last of which is connected to the second folding input of the first and the first subtractive input of the second ternary elements, the output of the first ternary element is connected to the first and the second folding inputs of the second ternary element, the output of which is connected to the output bus and the first folding input of the first ternary element. The first SCT of the third ternary element is connected in each discharge, except for the first, with the output of the third ternary element of the previous discharge, the first folding input of the third ternary element of the first discharge is connected to the first subtractive input of the first ternary element and the input bus, which differs in that, in order to increase speed, in each discharge the second folding input of the third ternary element is connected to the output of the second ternary element, the second subtracting input of which is connected With the output of the third ternary element, the first subtraction (L is the melting input of which is connected to the corresponding clock bus, the first folding input of the third ternary element is connected to the third folding input of the first ternary element, the output of which is connected to the first subtractive input of the first (About the ternary element of the subsequent discharge with 4 1

Description

The invention relates to a pulse technique and can be used in the design of reversible counters of digital computing devices. A reversible pulse counter is known, containing an input bus and bits, each of which contains a set of ternary elements P, Disadvantages of this device, relative complexity and poor performance. The reverse pulse counter, proposed by the technical nature, containing an input bus and bits, each of which contains three ternary elements, an output and an installation bus, the last of which is connected to the second folding input of the first, the first subtractive input of the second tertiary elements, you the stroke of the first ternary element is connected to the first and second folding entrances of this third ternary element, the output of which is connected to the output bus and the first folding entrance of the first ternary element, the first folding input of the third ternary element is connected in each discharge, except for the first, to the third ternary the element of the previous bit and the first and second subtractive inputs of the first trig racial element of this bit, in each bit the output of the first ternary ele1 "nta is connected to the first subtracted 1 chm input Om of the third ternary element, the first folding input of which in the first discharge is connected to the input bus and the first and second subtractive inputs of the first ternary element 2j. A disadvantage of the known devices is the low speed, since in each bit the signal transfer is formed in two phases of clock power, thus, the state of the highest n-th bit of the reversible pulse counter is formed in 2 n phases of clock power. The purpose of the invention is to increase the speed of the counter. To achieve this goal in a reversible pulse counter containing an input bus and n bits, each of which contains three ternary elements, an output and installation bus, the last of which is connected to the second folding input of the first and the first read input. the second .troic elements, the output of the first ternary element with the first and second folding inputs of the second ternary element, the output of which is connected to the output bus and the first folding input of the first the first ternary element, the first folding input of the third ternary element is connected in each discharge, except for the first, with the output of the third ternary element of the previous discharge, the first folding entrance of the third ternary element of the first discharge is connected to the first subtractive input of the first ternary element and the input bus, in each discharge, the second folding input of the third ternary element is connected to the output of the second ternary element, the second subtractive input of which is connected to the output of the third ternary element, n rvy subtracting input of which is connected to the corresponding input of the third ternary element is connected to a third input of the first folding ternary element, whose output is connected to a lane) zym BL reading input of the first element of the ternary subsequent discharge ,, FIG. 1 shows a diagram of a reversive three-digit pulse counter; in fig. 2 is a timing diagram for the operation of a three-bit reversible pulse counter. The counter contains ternary elements 1-3 of the first bit 4, ternary elements 5-7 of the second bit 8, ternary elements 9-11 of the third bit 12, input bus 13, mounting tires 14-16, output tires 17-19 and clock buses 20-22, respectively, bits 4, 8 and 12, The outputs of elements 1 and 5 are connected respectively to the first and second folding 1 inputs of elements 2 and bis by the first subtractive inputs of elements 5 and 9. The outputs of elements 2, 6 and 10 are connected respectively to the first folding the inputs of elements 1, 5 and 9, the second one adds the inputs of elements 3, 7 and 11 and you one tires 17–19. The outputs of elements 3 and 7 are connected respectively to the second subtractive inputs of elements 2 and 6, the third folding inputs of elements 5 and 9, and the first folding inputs of elements 7 and 11. The output of element 9 is connected to the first and second folding inputs of the element 10. The output of the element 11 is connected to the second subtractive input of the element 10. The input bus 13 is connected to the third folding and first subtractive inputs of the element 1 and to the first folding input of the element 2. Setting tires 14 - 16 are connected respectively to the second warehouses Elements 1, 5, and 9, and the first subtraction inputs of elements 2, 6, and 10. Clock buses 20–22 are connected to the first subtraction inputs of elements 3, 7, and 11, respectively. Each ternary element is described by a truth table. These operations form a functionally complete system of logical functions and can be implemented, for example, in magnetic logical cells. The outputs of the transfer of the first bit 4 are the outputs of the elements 1 (negative pulses) and 3 (positive pulses), the outputs of the transfer of the second bit 8 - the outputs of the elements 5 (negative pulses) and 7 (positive pulses), the outputs of the transfer of the third bit 12 outputs elements 9 (negative impulses) and 11 (positive impulses). When a single pulse arrives from the input bus 13 or from the transfer outputs of the first or second discharge, the corresponding discharge changes its internal state to the opposite. When the counter discharge goes from one to the O state at the output of the elements 3, 7 or 11 a positive transfer pulse appears in the next counter discharge. When pulses of positive polarity arrive on the bus 13, the reversible counter performs the functions of a summing counter, and on receipt of negative pulses, it functions as a subtractive counter. Transfer during addition is represented by a positive impulse at the output of elements 3, 7 and i1, and when subtracted it is represented by a negative impulse at the output of elements 1, 5 9. The presence of feedback allows one to store the result of the addition (subtraction), i.e. provides storage of co-worth or 1 discharge of the counter in the form of generation of pulses of positive polarity on its output bus. When a positive pulse arrives at the installation tires 14-16, the counter discharge is set to state 1, and when a negative pulse is received, elements 2.6 and 10 compensate for the pulses of the counter discharge state, i.e. counter reset. If it is necessary to write, the code of a certain number is applied to the installation buses 14-16 of the counter bits, the values of the bits of the recorded number are applied. I The clock circuit feeding system of the counter circuit is three-phase. The first-phase clock pulse reads the information from elements 6, 9, and 1, and pulses are received through the input bus 13 to the inputs of elements 1 and 3; second phase pulse - from elements 1, 3 and 10; the impulse of the third phase - from elements 2, 5 and 7; the pulses on the installation bus 14-16 arrive respectively during the clock pulses of the first, second and third phases. Clock buses 20-22 are supplied respectively to the generation of pulses with a clock frequency during the clock pulses of the first, second and third phases to the first subtractive inputs of elements 3.7 and P, and in the absence of pulses at their other inputs they are pulse generators. FIG. Figure 2 shows the time diagram of the forward counting from 000 to 100 and the reverse counting of pulses from 100 to 111, and the following designations are accepted: 23-25 are the time diagrams of the first, second and third phases of the clock supply, respectively; 26 is a timing chart of signals on the input bus 13; 27 - 35 - timing charts of signals, respectively, at the outputs of ternary elements 1-3; 5 - 7 and 9 - 11. The meter operates as follows. When the first pulse arrives on the bus 13 by the clock pulse of the first phase of the first clock according to the element truth table, a positive signal is transmitted to the third slot; No. The starting input of the element 1 and the first folding input of the element 3, as well as the bus 20, a positive signal is transmitted to the first subtractive input of the element 3 The second-phase impulse positive signal from element 1 is transmitted to the first folding input of element 2, the third-phase impulse positive signal from element-2 is transmitted to the first folding input of element 1 and The second folding input of the element 3 and arrives at the output bus 17, the first counter of the counter. The resulting state of the counter on the output tires 17-19-19. When the second pulse arrives on the bus I3 by the clock pulse of the first phase of the second clock cycle, a positive signal is transmitted to the third folding input of element 1 and the first connecting input of element 3, as well as to bus 20 a positive signal The second subtractive input of element 3 is transmitted to the first subtractive input of element 3. Positive signals from elements 1 and 3 are transmitted to the first folding input of element 2 and the second subtractive input of element 2, the third folding input of element 5, respectively. , the first folding input of element 7, as well as via bus 21, a positive signal is transmitted to the first subtractive input of element 7. A third-phase pulse P1 positive pulse from element 5 is transmitted to the first folding input of element 6, the first phase of the third cycle is transmitted by a positive signal from element 6 The first folding input of the element 5 and the second folding input of the element 7 enter the output bus 18, forming the second discharge of the counter. The resulting state of the counter on the output tires 17-19-19. When the third pulse arrives on the bus 13 with the clock pulse of the first phase of the third cycle, a positive signal is transmitted to the third folding input of element 1 and the first folding input of element 3, and so the bus 20 sends a positive signal on the first subtractive input element .3. The second-phase impulse positive signal from element 1 is transmitted to the first folding input of element 2, and a positive signal is transmitted via bus 21 to the first subtractive input of element 7. The third-phase pulse positive signals from elements 2 and 5 are transmitted to the first folding input of element 1, respectively the second folding input of element 3 and the output bus 17, forming the first raer q of the counter and to the first folding input of element 6, the impulse of the first phase of the fourth clock cycle positive signal from element 6 is transmitted to the first folding the input element 5, the second folding input element 7 and the output bus 18, forming the second digit of the counter. The resultant state on the output buses 17–19– 011. When the fourth pulse arrives on the bus 13 with the clock pulse of the first phase of the fourth cycle, the positive signal is transmitted to the third folding input of element 1 and the first folding input of element 3, as well as through bus 20 positive the signal is transmitted to the first subtractive input of element 3. The second phase impulse positive signals from elements 1 and 3 are transmitted respectively to the first folding input of element 2, the second subtractive input of element 2, the third folding input of the element 5, the first) 1st folding 1st input of element 7, as well as the bus 21, a positive signal is transmitted to the first subtraction of the 1st input of element 7. The third phase pulse positive signals from elements 6 and 7 are transmitted respectively to the first folding input of element 6, the second subtractive input element 6, the third folding input of the element 9, the first folding input of element II, and also via bus 22 a positive signal is transmitted to the first subtraction and input of the element I1. The pulse of the first phase of the fifth cycle, a positive signal from element 9 is transmitted to the first folding; the second input of the element 10. By the pulse of the second phase, a positive signal from element 10 is transmitted to the first folding input of element 9, the second folding input of element 11 and the second bus 19, forming the third bit counter The resulting state of the counter of the output tires 17 is 19-100. When the fifth time arrives on the bus 13 with the clock pulse of the first start of the fifth cycle, a negative signal is transmitted to the first subtractive input of element 1, as well as via extension. Table 1091347 10 Continuation of the table

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Claims (1)

A REVERSE PULSE COUNTER containing an input bus and η discharges, each of which contains three ternary elements, an output and installation bus, the last of which is connected to the second folding input of the first and the first subtracting input of the second ternary elements, the output of the first ternary element is connected to the first and second the folding inputs of the second ternary element, the output of which is connected to the output bus and the first folding input of the first ternary element, the first folding input of the third ternary element nen in each category, with the exception of the first, with the output of the third ternary element of the previous category, the first folding input of the third ternary element of the first category is connected to the first subtracting input of the first ternary element and the input bus, characterized in that, in order to improve performance, in each the second folding input of the third ternary element is connected to the output of the second ternary element, the second subtracting input of which is connected to the output of the third ternary element, the first subtracting input of which connected to a corresponding bus clock, a first input of the third folding ternary element is connected to a third input of the first folding ternary element, whose output is connected to a first subtractor input of the first element of the ternary subsequent discharge. SU _t . 1091347>