DE3022699A1 - Electronic adder and subtractor for 8421 code - uses five flip=flops per decade to provide display facility - Google Patents

Abstract

A binary circuit for the addition and subtraction of 8421 coded numbers operates together with a decimal display facility. Each decade consists of five or more flip flops, and has the capacity to press the interstage carries that are generated. One decade of the adder/substractor circuit has five flip flops. Voltage is supplied over a common pair of lines, with a further line used for control and reset applied over another line (h). Reset produces the combination to generate a zero display condition. Each flip flop is formed from a cross coupled pair of transistors together with diodes and resistors. Carries are transmitted over transistors.

Description

Electronic adding and subtracting circuit

in the 8421 code with decimal display The subject of the invention is a electronic adding and subtracting: r # circuit in the 8421 diode with decimal display. This adding and subtracting circuit also consists of decades with the numerical value ratio 1 to 10. Each decade also consists of 5 flip-flopps, as in the adding and subtracting circuit according to P 30 19 082.0, whereby the numbers 0 to 31 can also be saved every decade. In this adding and subtracting circuit, too, only the memory area 10 to 19 are used and displayed by means of appropriate decoding circuits. Instead of the number 10, the number 0 is displayed and instead of the number 11, the Digit 1. For entering the decimal digits as dual numbers, there is also an additional A decimal-to-dual conversion circuit is required per decade, so that dual-coded decimal digits are required to enter, e.g. 9 - HLLH. The return of a decade takes place with addition also after exceeding the decade number 9 by subtracting the number 10; at Subtraction takes place a decade after falling below the decade Digit 0 by adding the number 10. The adding and subtracting circuit described here has no continuous toggle pulse lines in the decades, like the adding and Subtraction circuit according to P 30 19 082.0, but normal transmission lines with additional ones Education. This further development of these transmission lines exists according to the invention in that these are two-way at their beginning and a current path is a line from Counting output represents the input of the next flip-flop and the other current path represents a line from the reset output to the input of the next flip-flop. These two-way transmission lines are switched over in the same way, like the control of the control of the transistors of the toggle pulse lines of P 30 19 082.0.

The decoding circuits used are the same as at P 30 19 082.0; thus there is a decoding circuit as shown in the figure for each decade 1 required. In Figure 2 is the first decade of this adding and subtracting circuit shown.

In order to simplify the representation, there are 4 AND circuits And circuit symbols shown. Figure 3 shows the switchover additional circuit for the first and second desade and Figure 4 shows a circuit according to Figure 2, the additionally has base resistances in the flip-flopps. In Figure 5 are in detail all the details of a circuit according to FIG. 2 are shown. The circuit after FIG. 2 thus has 2 additional transistors 42 and 44 and 2 additional transistors per flip-flop Capacitors 41 and 43.

The first decade of this adding and subtracting circuit shown in FIG If the additional training according to Figure 5 consists of 5 flip-flopps 1 to 5, of which the last (fifth) flip flop has no negation because it has no other Plipp-Ylopp of the same decade has to go. The operating voltage supply line has the designation a and the neutral line the designation c. The control line has the designation f and the Pücicstell line the designation h. When resetting of the entire adding and subtracting management, the decades are based on the stored value LHLHL and not reset to the storage value LLLLL, so every decade after the reset shows the number zero. The flip-flopp 1 consists of the transistors 11 and 12 and the diodes 13 and 14 and the resistors 15 and 16. In the transmission conduction path The transistor 17 is arranged in b and the transistor in the carry conduction path d 18. The transistor 19 is arranged to negate the potential of the control line f. In the one-way area e of the transfer line is a diode 20 and a capacitor 21. The capacitor 21 generates a positive when the L - # - potential change Impulse whose L-H edge flips the next flip flop. Part 20 is a diode with blocking effect in the direction of flip-flopp 2 - flip-flopp 1 and part 22 a transistor to generate the input pulses on flip-flop 1. On flip-flop 1 to 4 an additional circuit 23 is arranged, which consists of an AND circuit 24 and a transistor 2) and a resistor 26.

This additional circuit 23 causes an input of the adding or Subtraction pulses with a time interval. This time interval is a matter of course only as big as required and therefore very small. The capacitors 27 generate the necessary positive pulses for Ansteuerurlg the transistors 22. If direct control of the flip-flops is possible with the capacitors 27, the transistors 22 are omitted.

The additional reversing circuit is shown twice in Figure 3 (for 2 decades) shown. The section i belongs to the first (shown) decade and the section k to the second decade, which is not shown. So there is one additional circuit per decade with input p required. The input m is the input with which the entire circuit is set to addition or subtraction. The operating voltage supply line also has the designation a and the zero line the designation c. A decade changeover additional circuit consists of 3 transistors 31 to 33 and 2 diodes 34 and 35.

For adding, the connection point m is placed at H potential and is present the input p automatically at H-potential and has the output n, to which the control line f is connected, H-potential. With addition reset (subtraction of the number 10) p automatically changes from H potential to L potential and has the output n here L potential.

For subtraction, the connection point m is connected to L potential and the input p is also automatically at H potential and the output n has to the the control line f is connected, B potential. With subtraction reset (Adding the number 10) p changes automatically from H-potential to L-potential and the output n has H potential.

The mode of action results in jlctl like lolgl: When the first decade denotes the Display value 6 and thus the memory value 16 and the flip-flop chain of this Decade at their counting outputs (left-hand side) thus the potential series HLLLL and the number 8 (HLLL) is to be added, the circuit must first can be set to addition. This setting is made by the input m is connected to H potential, which also causes output n and thus the control line f has H potential if the same potential (H potential) is also present at input p.

The addition of the number 8 = HLLL takes place because input E 4 is applied to H potential and by applying H potential to input ES the addition is triggered. The flip flop 4 tips over here because it is through the L-H edge of the transistor 22 d is driven directly. The flip flop 3 tips over in this case not because the diode 20c to the flip-flop 3 does not have a positive pulse lets through. The flip-flop 5 does not tip over because the control line f has H potential for adding and thus transistor 17 d has L potential at its base and thus the b-e transmission line from flip-flopp 4 is blocking. After this Addition assigns the potential series to this first decade at the counting outputs of your flip-flopps HHLLL = 24. This decade has exceeded the memory value 19 and will be of the OR circuit 40 and the non-circuit 41 the resetting of the first Decade and the carryover to the second decade triggered. In this case, the Output B 1 the input p is set to L potential, whereby the output n and thus the control line f has L potential and thus this decade has been switched to subtraction is. The output B 2 causes here with its L-H potential change over a corresponding Conducted a toggle impulse on the first flip-flop of the second decade, the one for this also has a secondary input E 1 b.

The output B 3 causes its L-H potential change over a corresponding line a tilting pulse at the secondary input E 2 b of the first decade and the output B 4 in the same way a somewhat delayed toggle pulse on Secondary input E 4 b of the first decade. The automatic subtraction then took place the dual numbers LLEL and HLLL and the automatic marriage Addition of Number 1 in the second decade and the resetting of the first decade is ended. The first decade has the memory value 14 and the display value 4 and the second Decade the memory value 11 and the display value 1.

(6 + 8 - 4 + 10 = 14).

The setting for subtraction is made by applying L potential to input m. Here, all outputs n have L potential, in their decade circuit the input p at H potential) weighs. If the first decade shows 6 and has the memory value 16 and the second decade the display value 2 and the memory value 12 and the flip-flop chain of the first decade at its Lähl outputs (left exits) thus has the potential series IILLLL and of these the number 8 (HLDL) is to be subtracted, input E 4 of the first decade is at H potential placed and by applying H potential to the input R S of the first decade the subtraction is triggered. The flip flop 4 also tips because it is driven directly by the L-H edge of the transistor 22 d. The flip flop 3 does not tip over here because the diode 20c for the flip-flop 3 does not pass positive impulse. The flip-flopp 5 flips here following #lipp-flopp 4, because the control line f has L potential and thus the transistor 19 d Actuates transistor 17 d and because with it the L-H potential change at the counter output of flip-flop 4 comes into play by the capacitor 21 d a positive pulse generated, the L-H edge of which the flip flopp 5 in its other switching state tilts.

After this subtraction, this first decade points to the counting outputs their flip-flopps have the potential series LHLDL = 8.

This decade has fallen below the storage value 10 and will of the OR circuit 40 and the non-circuit 41 the resetting of the first Decade and the carryover to the second decade is triggered. Here is initially from Output B 1, the connection p placed on L potential, whereby the output n and thus the line f has H potential and thus this decade has been switched to addition. Output B 2 causes a change in potential with its lt-H potential via a corresponding one Leading a toggle impulse9 with the first flip-flop of the second decade and thus the Subtraction of the number 1 on the second decade via the side entrance R 1 b of the second decade. The output B 3 causes change with its L-H potential Via a corresponding line, a tilting pulse at the secondary input E 2 b of the first Decade and the output B 4 in the same way a somewhat delayed tilting pulse at the secondary input E 4 b of the first decade. The automatic addition then took place of the binary numbers LLHL and HLLL in the first decade and automatic subtraction the dual number LLLH in the second decade and is therefore the position of the first decade ended. The first desade thus has the memory value 18 and the display value 8 and the second detade the memory value 11 and the display value 1. (26 - 8 = 8 + 10 = 18).

In the circuit according to FIG. 2 (and also in the circuit according to FIG 4) two additional transistors are required per flip-flop because every change in potential the line f can trigger incorrect carry pulses. These additionally required Transistors and lines are shown in the detail drawing in FIG. These Detail drawing shows the corresponding areas of flip-flop 1 and flip-flop 2. If at the base of the transistor 18 H potential comes to the plant, comes also at the capacitor 41 H-potential to the plant and thus arises at the base of the Transistor 42 a positive voltage pulse, through which the voltage pulse of the Capacitor 21 is derived into the neutral line. The same is true with regard to the transistor 17 and the capacitor 43 and the transistor 44.

In the first decade of the adding and subtracting circuit shown in FIG Type B the blipp-flopps are additionally provided with basic resistors 51 and 52, to improve the effectiveness of the control. These resistors 51 and 52 are only as large as necessary to enable the flip-flopps to function in any other way Relationship is not significantly affected. These resistors 51 and 52 are so arranged on each flip-flop and have a very low resistance. Even In this circuit according to FIG. 4, the first four flip-flopps of every decade must corresponding to Figure 5 with 2 additional transistors 42 and 44 and 2 capacitors 41 and 43 urld be provided with the corresponding additional lines at the type S of this adding and subtracting circuit are at the points p and q of the Flip-flopps placed additional resistances.

Claims (4)

Claims 1. Electronic adding wid subtracting circuit in the Lual code with decimal display consisting of 5 or more flip flopps per decade and in which the stored value of the decades is higher than their display value, thereby marked that the carry over of the flip-flop to your next flip-flop normally arranged transmission lines takes place. 2) Electronic adding and subtracting circuit according to claim 1, characterized in that the transfer lines of the flip-flopps are double and when adding the L-H potential changes of the reset output of the flip-flopps generates the toggle pulse for the next flip-flop and, when subtracted, the L-H potential change the counting output of the flip-flop generates the toggle pulse for the next flip-flop. 3) Electronic adding and subtracting circuit according to claim 1 and 2, characterized in that the potential switching of the carry lines this makes it possible that unintentionally arising carry pulses into the Zero line can be derived. 4) Other electroxiic adding or subtracting circuits or other combined adding and subtracting circuits in dual - &, or with Decimal display, characterized in that the stored values of the decades by one certain amount are higher than the display values of the decades.