DE3606410A1 - Electronic modulo-10 counter - Google Patents

Abstract

The electronic pulse counter according to the subject matter of the invention also has only a single flip flop per subcircuit. In contrast to the pulse counter according to P 3605901.3, 2 flip flops have H potential at their counting output in the present pulse counter unless a counting pulse incrementing is currently taking place. If the pulse counter according to P 3606409.2 is sufficiently good in all respects, this further development is not required. <IMAGE>

Description

The invention relates to an electronic modulo 10 counter, the decades of which each consist of 10 simple flip-flops and a pulse circuit which has a double flip-flop as the main component. These pulse circuits also control the decades via 2 pulse lines each. According to the invention, this modulo 10 counter has 2 flip-flops at its counting output z H-potential, unless a counting pulse relay is currently taking place. In the course of a counting pulse forwarding, the flip-flop that tipped into its left position at the last counting pulse remains in its left position and additionally tilts the next flip-flop into its left position and tilts the previous flip -Flop in his right position. Due to the fact that the carry can be controlled in different ways, 2 types of this pulse counter are shown.

In Fig. 1 a decade of the pulse counter type A is shown shortened by 4 flip-flops in switching symbols. In FIG. 2, a decade is the pulse counter Type B by 4 reversed summon Flopps shortened in switching symbols shown. In FIGS. 3 and 4 is shortened a decade of the pulse counter Type A at 4 reversed summon Flopps illustrated in component symbols. In FIG. 5, the pulse circuit 60 is shown. In FIG. 6, the pulse diagram is shown of the pulse circuit 60.

A decade of the pulse counter type A ( Fig. 1 and 3 to 6) consists of 10 simple flip-flops 10 to 19 and 10 AND circuits 20 to 29 with 2 inputs each and 10 AND circuits 30 to 39 with 3 each Inputs and the pulse circuit 60 and the associated lines. The pulse input has the designation E. The carry output is labeled F.

The result outputs C are marked with the associated decimal digits. According to Fig. 3 and 4 is a partial circuit of transistors 41 to 43 3 and 6 diodes 44 to 49 and resistors 50 to 55 6. In this Fig. 3-4, line a is the operating current supply line (operating voltage supply line) and line b is the zero line. In the idle state, the reset line is at L potential and has the designation R.

The pulse circuit 60 consists of 2 simple flip-flops 61 and 62 and 6 AND circuits 64 to 69 and a negation circuit 70 .

The mode of operation of this pulse counter is as follows: Before the start of each pulse count, all flip-flops of each decade must be brought to their starting position by briefly applying H potential to line R , in which the outputs for the digits 0 have H potential and in which the outputs for digits 1 to 9 have L potential. Here, the flip-flops of the pulse circuits 60 are set so that the lines d and k have H potential. Thus, in each decade the flip-flops 10 and 19 are in their left position, in which their counting output z has H potential, and the flip-flops 11 to 18 in each decade are in their right position, in which they are counted -Output z has L potential. In this switch position, not only is the flip-flop 11 pre-activated, but also the flip-flop 10 is pre-activated. At the first counting pulse, the flip-flop 11 thus tilts into its left position, in which its counting output z has H potential, and the flip-flop 19 into its right position, because it has a short time over line 1 Delay is controlled by a reset. Thus, at the first count pulse, the output of the AND circuit 30 changes from H potential to L potential and the output of the AND circuit 31 changes from L potential to H potential, with the first decade indicating the number 1. In this switch position, not only is the flip-flop 12 pre-activated, but also the flip-flop 11 is pre-activated. At the second counting pulse the flip-flop 12 thus tilts into its left position, in which its counting output z has H potential, and the flip-flop 10 into its right position, because it has a short time over line p Delay is controlled by a reset. Thus, at the second counting pulse, the output of the AND circuit 31 changes from H potential to L potential and the output of the AND circuit 32 changes from L potential to H potential, with the first decade indicating the number 2.

After the ninth count pulse, the AND circuit 20 is effectively precontrolled, as a result of which the flip-flop 10 tilts into its left position during the tenth count pulse and the flip-flop 18 tilts into its right position with a short time delay . The output of the AND circuit 39 thus changes from H potential to L potential and the output of the AND circuit 30 changes from L potential to H potential. Because the output of the AND circuit has 20 H potential at the tenth count pulse, the carry output F also has H potential at the tenth count pulse. Thus, the tenth count pulse in the pulse circuit 60 of the second decade is the first decade count pulse which flips the flip-flop 11 of the second decade into its left position. In this second decade, the flip-flop 19 then tilts to its right position as soon as the flip-flop 11 has z H potential at its counting output. In the first decade, the output for the number 0 has H potential and in the second decade the output for the number 1 H potential, with which this pulse counter indicates the number 10.

The decade of the pulse counter type B shown in FIG. 2 has the difference in comparison with the decade of the pulse counter type A shown in FIG. 1 that the carry is not controlled by a branch of the output of the AND circuit 20 , but from a branch of the output for the number 0. However, the use of this carry control is only made possible by the arrangement of an additional circuit 70 , which consists of a flip-flop 71 and an AND circuit 72 . This additional circuit 70 prevents the carry outputs F from inadvertently triggering a wrong counting pulse after the total reset for the next decade. When this pulse counter is reset, not only is the line R driven with a short H pulse in each decade and the pulse circuit 60 is reset so that the lines d and k have H potential, but also that Flip-flop 71 reset so that its output q has L potential.

The decade of the pulse counter type A 2 shown in FIG. 7 has the difference in comparison with the decade of the pulse counter type A shown in FIG. 1 that the AND circuits 30 to 39 each have only 2 inputs and thus are not controlled by the right-hand outputs of the count-flip-flops, which are shown without these right-hand outputs.

The decade of the pulse counter type B 2 shown in FIG. 8 has the difference in comparison with the decade of the pulse counter type B shown in FIG. 2 that the AND circuits 30 to 39 each have only 2 inputs and thus are not controlled by the right-hand outputs of the count-flip-flops, which are shown without these right-hand outputs.

The input s of the flip-flop 71 does not have to be controlled by a branch of the output for the number 2, but can also be controlled by a branch of the output for the number 3 or 4 or 5 or 6 or 7 or 8.

Claims (6)

1) Electronic modulo 10 counter, consisting of decades, the sub-circuits of which have a simple flip-flop or another potential storage circuit as the main part and in which the control of the sub-circuits via two pulse lines ( m and n ), which are alternately fed with the counting pulse, characterized in that outside the switching times there are two flip-flops in the position in which their counting output ( z ) has H potential. 2) Electronic modulo 10 counter according to claim 1, characterized in that special circuits are used as pulse circuits ( 60 ) which have 2 flip-flops ( 61 and 62 ) as main parts. 3) Electronic modulo 10 counter according to claim 1 or according to claim 1 and 2, characterized in that the sub-circuits as main part each have a simple flip-flop ( 10 to 19 ) and that the respective flip-flop to be reset is reset by the counting output z of the flip-flop after next when it changes from L potential to H potential. 4) Electronic modulo 10 counter according to claim 1 or according to claim 1 and 2 or according to claim 1 to 3, characterized in that the triggering of the transmission in the next decade from a branch ( b ) of the output of the AND circuit ( 20th ) he follows. (Type A and A 2 ). 5) Electronic modulo 10 counter according to claim 1 or according to claim 1 and 2 or according to claim 1 to 3, characterized in that the control of the transmission in the next decade from a branch ( c ) of the output for the number 0 (zero ) and that this type of carry control is made possible by a blocking circuit ( 70 ), which blocks the transfer of a transfer at the first zero digit in each decade. (Type B and B 2 ). 6) Electronic modulo 10 counter according to claim 5, characterized in that the blocking circuit ( 70 ) consists of a flip-flop ( 71 ) and an AND circuit ( 72 ).