DE3016343A1 - Electronic B-C-D counter in 8421 code - resets previous counting decade via transistors having bases coupled to outputs of first flip=flop - Google Patents

Abstract

The counting circuit has a tripping impulse lead. In the intermediate regions of the flip-flops transistors or similar components are installed. The transistors of the impulse lead are controlled from the count outputs of the flip-flops. Flip-flops of type A are not directly tripped from the impulse lead but rather indirectly through control of other transistors. Flip-flops of type B are directly tripped by the impulse lead. The flip-flops are tripped from the L-H flanks of positive impulses or by corresponding formulation from the H-L flanks of negative impulses. The resetting of a counting decade after the tenth counting impulse is effected through the first flip-flop of the next counting decade.

Description

Electronic BCD counter in 8421 code.

The subject of the invention is a new payment circuit in the 8421 code. In this circuit, according to the invention, the knowledge was utilized that only a Zihl pulse only flips the first flip-flop when the number circuit is set to zero is reset and thus the first flip-flop has zero potential on his Number output and that there are only 3 basic positions that have the function must be adapted to the payment circuit. The second basic position is when the first digit is a 1 and the second digit is a zero. The third basic position case occurs when the first digit is a 1 and then another 1 or after this 1 a number of dual ones follow without a zero in between. From it the result is that the sequence of numbers after the first zero upwards is not taken into account must become. If there is a 1 in the first position and a zero must in the second position after the next number pulse the first digit (the first output) will show a zero and the second output a 1.

If two or more digits start with a 1 are occupied, these positions must all be zero after the next number pulse display and the first zero display a 1. (HHLHHHH + H = HHHLLLL).

According to the invention, the problem of the simultaneous tilting of several Flip-flopps in the 8421 code are solved by connecting the number decades with a toggle pulse line were provided, in which transistors are arranged in the intermediate area of the flip-flopps whose bases are at the number outputs of the flip-flopps. These transistors the tilting impulse line is conductive when the potential H is present at its base and blocking when the potential L is applied to its base. This tilting impulse line can be arranged in such a way that the corresponding flip-flopps are directly tipped; in the shown.

In the th case, only transistors are used by the toggle pulse line controlled, which deliver the impulse current from the plus line. In this way I can only a counting decade, but also a very long flip-flop chain, In i'igur 1, the first two number decades of a counting circuit are in the 8421 code shown. The first counting decade is provided with input E. The exits Both counting decades have the designation A 1 to A 4.

As with other counting circuits of this type, each counting decade exists from 4 Flipp-Fiopps. The flip-flopps used are all the same. 10 and 11 are the two transistors of the Flip-Piopps 4 and 12 and 13 are two diodes.

The toggle pulse line transistors are number 14.

15 and 16 are two resistors. The additional circuit of the flip-flopps consists of a transistor 17 and a connection line to zero potential, in which the resistor 19 is arranged. These resistors 19 with connecting line are arranged because the sections a of the toggle pulse line b the potential Must have zero if the L-H edge of the number pulses is used to toggle. The counting pulses are therefore positive in the case shown. d and e are the two Operating voltage supply lines with a correspondingly high positive potential. The Ittid circuit for the transfer to the first flip flop of the next Zihl decade has the number 20. These AND circuits can each consist of two transistors on their lawn the outputs A 2 and A 4 are connected, the collector of the first transistor to the Plus operating voltage is connected. The carry line has the designation f. The resetting of a counting decade after the tenth counting pulse is made possible by the The first flip-flop of the next counting decade does that with its two outputs controls one of the two transistors 21 and 22 via lines h and i, whose collector is connected to the plus potential. An inadmissible provision of further counting decades is avoided by the transistor 23, which the reset T, line of the previous counting decade short-circuited with the zero potential. If so from the Flip-flop 1 of the third counting decade the second counting decade is reset, the transistor 23 prevents the resetting of the first decade number, The mode of operation is as follows: When the payment circuit is set to zero and If a number pulse is received at input E of the first number dercade, only the flip-flop flips 1 of the first decade number in its H position, because the transistor 14 a only then is conductive when the flip-flop 1 is tilted into its H position, in which the Output A 1 has H potential if the number switch is set to 1 and the input E has the When the second counting pulse arrives in the first decade of numbers, both flip-flop 1 flips over as well as the flip-flop 2 in its other operating position, because this is the transistor 14 a is conductive and the transistor 14 b is not yet conductive.

This means that output A 2 has H potential and output A 1 has L potential and the number HL = 2 is displayed. With the third Zihl pulse at input E. of the first counting decade, in turn, only flip-flop 1 flips into its other switching state, because here the transistor 14 a is not conductive.

With the fourth counting pulse at input E of the first decade of numbers, the transistors 14 a and 14 b are conductive and accordingly flip flip-flop 1 to flip-flop 3 into their other switching state and thus the first decade of numbers shows the number HLL = 4 . At the The counting pulse at input E of the first counting decade has flip-flop 1 at its output A1 H potential and flip flopp 2 has L potential and thus tilts with only the first two flip-flops in your other switching state. This means that the first number decade has the potential series HLHL at its outputs and the transfer line f has H potential. With this potential jump from L to H, the capacitor 24 delivers a rapid number pulse to the input of the second counting decade, thus creating the flip-flop 5 flips from L to H, indicating the decimal number 10. Normal 8421 code decoding circuits are required to display the decimal digits of the counting decades.

The basic principle of this number circuit is also as an adding circuit can be used if the circuit has no decimal value jumps, but rather is just a long chain of two-valence jumps. The impulses of the digits of the dual number that is to be added must of course start with a Clock device are entered because for each binary digit the addition process must have expired before the counting pulse is received from the next dual digit. The present basic principle has the advantage that only transistors are driven must and that thus a very long counting chain is possible, which is a pure dual number indicates. This circuit is shown in FIG. The one in the Kipp-Impul @ line b additionally required diodes have the number 18.

L e r s e i t e

Claims (1)

Claims 1) Electronic counting circuit in the 8421 code, thereby characterized in that this is provided with a toggle pulse line (b, in the in the intermediate areas of the dip-flopps transistors (14) or similar parts are arranged 2) Electronic counting circuit according to claim 1, characterized in that dalS the transistors (14) of the toggle pulse line (b) from the counting outputs of the Flip-flopps are controlled. 3) Electronic counting circuit according to claim 1 and 2, characterized in that that the flip-flopps of type A are not flipped directly by the flip-pulse line but indirectly by controlling transistors (17) 4) Electronic Counting circuit according to Claims 1 and 2, characterized in that the flip-flopps at. the type can be tilted directly from the tilting impulse line. 5) Electronic counting circuits according to claim 1 to 3, characterized in that that the flip-flopps are flipped by the L-H edge of positive pulses or at other corresponding training of the H-L flank of negative pulses. #) Electronic counting circuit according to claim 1 to 5, characterized in that that the resetting of a counting decade after the tenth 7J * ihl pulse by the first Flif Fiopp of the next counting decade is effected. 7) Electronic counting circuit according to claims 1 to 3 and 6, characterized in that the previous counting decade is reset via transistors whose bases are at the outputs of flip-flop 1 of the counting decade. 8) Electronic counting circuit according to claim 1 to 3 and 6 and 7, characterized. that unwanted deferrals of Zätil decades by order Transistors (23) is avoided. 9) Electronic counting circuit according to claim 1 to 3, characterized in that that this is also used as an adder circuit without a tens jump. 10) Electronic number circuit according to claim 1 and 2 and 4, characterized indicated that this is also used as an adder circuit without a tens jump will.