DE4229625A1 - Digital electronic arithmetic circuit for addition subtraction multiplication and division - has adder stage combined with registers and single control unit providing control pulses - Google Patents

Abstract

A digital arithmetic circuit is based around an adder circuit that can be controlled together with shift registers to provide all four basic operations. The numbers together with decimal points are entered into shift registers with moves being made to suit the applications. The shift registers are controlled with pulses generated by a circuit (70d) that consists of logic gates and flip flops. The registers provide determination of the decimal point position. USE/ADVANTAGE - Provides four basic arithmetic operations.

Description

The invention relates to the further improvement of type B of the arithmetic circuit according to the main patent application (P 42 23 125.6), which has been improved several times and thus in P 42 23 125.6 and in P 42 26 060.4 and in P. . . . . . . . is shown and described. The arithmetic circuit according to the present patent application is thus also for the input of the first number in the shift register 21 b or in the shift register 22 or to the shift register 21 a provided with a stroke-displacement means where each having a parallel input circuit 32 gate -And- circuits is saved.

In Fig. 1, the digit input circuit 20 is shown, which is shown in the main patent application in Fig. 3. In Fig. 2a to 2e, the control unit 12 is shown, which is displayed in the main patent application in Figs. 4a to 4d. In Fig. 3, the circuit 60 is Darge provides. In Fig. 4a and 4b, the shift register control unit 70 shown. In Fig. 5 the arrangement of the shift registers 21 a and 21 b and 22 is shown in relation to the shift register transfer. In FIG. 6, the pulse counter 80 of the circuit 60 illustrated. The circuit 43 is shown in FIG .

The digit input circuit 20 ( Fig. 1), which is shown in the main patent application in Fig. 3, consists of the keyboard 14 and the OR circuit 1 with 9 inputs and the OR circuit 2 with 2 inputs and the OR circuit 3 with 5 inputs and 2 OR circuits 4 with 4 inputs each and the OR circuit 5 with 8 inputs and the gate circuits 6 and 7 , consisting of 4 AND circuits each with 2 inputs and the OR -Circuit 9 with 3 inputs and the associated lines.

The sub-circuit 12 a of the control unit 12 ( Fig. 2a) be consists of the circuit 18 and the gate circuits 27 and 28 , which consist of 4 AND circuits with 2 inputs each and 4 OR circuits 26 with each 2 inputs and the OR circuit 29 with 2 inputs and the OR circuit 68 with 3 inputs and the AND circuit 69 with 2 inputs and the negation circuits 31 and 32 and the simple flip-flop 25 and the associated lines. The fourfold two-way shift register has the number 90 .

The sub-circuit 12 b of the control unit 12 ( FIG. 2b) consists of 7 simple flip-flops 1 to 7 and the circuit 60 and the AND circuits 10 to 13 , each with 2 inputs and the OR circuits 14 to 16 and 22 with 2 inputs each and the OR circuits 9 and 17 with 3 inputs each and the Negier circuits 21 and 58 and the OR circuit 59 and 6 toggle switches 8 and the associated lines.

The sub-circuit 12 c of the control unit 12 ( FIG. 2 c) consists of the simple flip-flops 25 and 32 and the set pulse circuit 23 and the AND circuits 27 and 38 and 28 and 52 , each with 2 inputs and the OR circuit 30 with 2 inputs and the OR circuit 31 with 3 inputs and the negation circuits 36 and 37 and the gate circuit 67 , consisting of 3 AND circuits with 2 inputs each and the associated lines.

The sub-circuit 12 d of the control unit 12 ( FIG. 2d) consists of the pulse circuit 32 and the pulse changeover circuit 36 and the simple flip-flop 23 and the AND circuits 24 to 29 and 47 with 2 each Inputs and 2 AND circuits 31 with 3 inputs each and the gate circuit 48 , consisting of 3 AND circuits with 2 inputs each and the OR circuits 33 and 46 with 2 inputs each and the OR circuit 34 with 3 inputs and the Negier circuits 31 and 32 and 49 and the associated lines.

The sub-circuit 12 e of the control unit 12 ( FIG. 2e) consists of the circuits 13 and 30 and the simple flip-flops 34 and 35 and the AND circuits 36 to 43 with 2 inputs each and the OR circuit 45 with 4 inputs and the negation circuit 47 and the associated lines. The circuits 13 and 30 are shown and described in P 42 18 870.9. The circuit 13 consists of a transcoding circuit which transcodes the relevant digit from the 5211 code into the counting code, and a pulse counter. Circuit 30 is a programming circuit for the number of multiplier digits.

The circuit 60 ( FIG. 3) consists of the pulse counter 80 and the start circuit 38 and the simple flip-flops 32 and 35 and the AND circuits 21 to 27 and 37 with 2 inputs each and the AND circuit 28 with 3 inputs and the OR circuits 29 and 30 with 2 inputs each and the Ne gier circuits 33 and 34 and 39 and the OR circuits 41 to 43 with 2 inputs each and the AND circuits 44 and 45 with 2 inputs each and the negation circuit 46 and the flip-flop 47 and the associated lines.

The shift register and comma control unit 70 ( FIGS. 4a and 4b) consists of the flip-flops 1 to 5 and the circuit 43 and 5 AND circuits 6 with 2 inputs each and 3 AND circuits 7 with 2 inputs each and the AND circuits 8 and 9 , each with 2 inputs and the OR circuits 10 and 11 , each with 2 inputs, and the OR circuits 12 and 13 , each with 3 inputs, and 5 OR circuits 14 , each with 2 inputs, and the OR circuit 15 and 2 OR circuits 17 with 3 inputs each and 2 OR circuits 16 with 2 inputs each and the OR circuit 18 with 5 inputs and the OR circuit 19 with 4 inputs and the associated lines.

The pulse counter 80 of the circuit 60 ( FIG. 6) consists of 10 flip-flops 1 to 10 and 8 AND circuits 11 with 2 inputs each and 4 AND circuits 12 with 2 inputs each and the negation circuit 13 and the OR circuit 14 with 5 inputs and the further simple flip-flop 15 and 2 AND circuits 16 and 2 AND circuits 17 , each with 2 inputs and 2 negation circuits 18 and the associated lines. The pulse input has the designation a. The switching output has the designation b. The reset input has the designation r.

The circuit 43 ( FIG. 7) consists of the simple flip-flop 1 and 7 AND circuits 2 with 2 inputs each and 8 AND circuits 3 with 2 inputs each and the OR circuit 4 with 7 inputs and the OR circuit 5 with 8 inputs and the AND circuits 6 to 9 with 2 inputs each and the negation circuit 10 and the associated lines. The additional clock input has the designation a. The post-clock output for the shift register 22 and for the comma shift register 50 c / 1/2 has the designation b. The post-clock output for the shift register 21 b and the comma shift register 50 a has the designation c.

The additional circuit 55 ( Fig. 5) for the shift register transfer clock control 90-21 b and 90-22 and 90-21 a and the associated gate circuits consists of the gate circuits 61 to 63 , which consist of 4 AND circuits with 2 inputs each and the simple flip-flops 67 to 69 and 3 AND circuits 71 and 16 diodes 72 and the associated lines. The shift register 90 is shown in FIG. 2.

The shift registers are controlled by the outputs 1 to 7 of the circuit 70 as follows: From the output 1 , the shift register 22 is clock-controlled, shifting to the left. From the output 2 , the shift register 21 a and 21 b is clock-shifted to the left. The shift register 90 is clock-shifted from output 3 to the left. From output 4 , the shift register 90 is clock-shifted to the right. From the output 5 , the comma shift register 50 c / 1/2 is shift-clocked to the left. From the output 6 , the comma shift register 50 c / 1/2 is clock-shifted to the right. From the output 7 , the comma rail register 50 a is left-shifting clock-driven.

The other controls are as follows: The output Nd controls the input nd. The output N3 drives the display circuit 45 . Output A1 controls input a1. Output B1 controls input b1. The output M8 controls the input m8. Output A3 controls input a3. The output B3 controls the input b3. Output A7 controls input a7. Outputs S2 control inputs s2. The outputs D are fourfold and control the parallel inputs q4 of the display circuit 45 . Output I controls input i. The output K controls the input k. Output A4 controls the resetting of the comma shift register 50 a. The output B4 also controls the resetting of the comma shift register 50 a. Output A5 controls input a5. The output B5 controls the input b5. The output C5 controls the input c5. Output C controls input c. The output F4 controls the input f4. Output F5 controls input f5. Input h is reset-controlled either by output H or by output N. The outputs NK control the inputs nk. The output L1 controls the resetting of the shift register 21 b. From the output L2, the gate circuit between the memory row 25 and the shift register 21 b is driven and thus the content of the memory row 25 is faded into the shift register 21 b. The output L3 controls the resetting of the memory array 25 . The output C6 controls the restricted total reset, in which only the shift register 90 and the comma shift registers 50 c / 1 and 50 c / 2 are not reset. Output L5 controls input l5. The output L6 controls the input l6. Output L7 controls input l7. Output C7 controls input c7. Output E controls input e. The Q output controls the q input. The output V controls the input v. Output V2 controls input v2. The output V3 controls the input v3. The output P controls the input p. The outputs S1 control the inputs s1. The outputs W control the inputs w. The outputs F control the inputs f. The inputs t1 and t2 and t3 are driven with the clock frequency. In the operating state, inputs u2 are constantly at H potential. The inputs r are reset-controlled by branches of the output R1. Output E5 controls input e5. Output E4 controls input e4. Output E7 controls input e7. Output E8 controls input e8. The output Y controls the resetting of the shift register 90 and the comma shift registers 50 c / 1 and 50 c / 2. The output C8 controls the input c8. The output F8 controls the input f8. The output S8 controls the input s8. The output Z1 controls the input z1. Output Z2 controls input z2. The output Z3 controls the input z3. The inputs and outputs a to h of the circuit 60 ( FIG. 2b) have the correct designation in FIG. 3.

In the embodiment, the B shift register 21 a and 21 b shift clock-controlled separately and thus, the circuit 70 b of eight outputs. ( 21 b shifting left; 21 a shifting left).

The circuit 60 ( Fig. 3) therefore has a pulse counter 80 for the delivery of 9 H pulses, because when dividing the shift of the comma index n of the comma shift register 50 c / 1/2 nine H pulses required are. For this reason, the shift register 90 has a length of 9 sub-circuits.

In version C, the pulse counter 80 of the circuit 60 can be switched over and supplies eight H-pulses with the pre-control 1 and 2 9 H-pulses with the pre-control 2 . In this case, the shift register 90 has only 8 subcircuits.

When entering the first number (first summand or minuend or multiplicand or dividend), the effect is as follows: Before typing in the first number, this arithmetic circuit must be reset by pressing the R key, unless it has already been reset. In this basic position, the input ND is driven by the output ND with H potential and the gate circuit 6 is thus driven before and the output N3 controls the display circuit 45 with H potential. The first number is thus typed into the shift register 90 via the inputs s1 when it is typed in via the keyboard 14 and this number appears in the display because the display circuit 45 is driven with H potential. A possible comma is also typed in at the correct point using the P key and is thus shifted left-shifting into the comma shift registers 50 a and 50 c / 1, whereby both comma indexes m and n are shifted to the left by the corresponding number of digits are.

If multiplication is carried out, the M key is pressed first. Here, the flip-flop 1 of the circuit 12 b flips into its left position and the circuit 23 is clock-controlled during the duration of this tapping and thus the transfer 90-22 is controlled , in which the circuit 23 supplies the control pulses and Circuit 60 provides nine H-pulses for the clock transfer 90-22 . The gate circuit 6 is also pre-activated from the output A1 via the input a1 and the multiplier is thus also typed into the shift register 90 after the multiplicand is already in the shift register 22 . In this case too, the display circuit 45 is connected to H potential from the output N3 and thus this number also appears in the display. The required resetting of the comma shift register 50 a before typing this multiplier is done by means of an H pulse from output A 4. The comma of this multiplier is also typed in at the correct position using the P key and is shifted to the left in the comma -Shift register 50 a and 50 c / 1/2 typed in, the decimal places of the multiplicand and the multiplier in the decimal shift register 50 c / 1/2 add up and the display of the decimal places of this multiplier also from the comma shift register 50 a off that was reset when the M button was pressed. Input a3 is controlled by output A3 with an H potential and input a5 is controlled by output A5 with an H pulse. The circuit 60 is thereby bridged-controlled by the output M8, because in this case it is not used (in the case of multiplication). Here, too, the gate circuit 64 of the display circuit 45 is pre-activated by the output E4. After entering these two numbers via the keyboard 14 , the G key is pressed and thus the multiplication sequence is triggered, which ends when the last multiplier number has been worked up. In this case, the number 7 is the last number if the number 728 is processed as a multiplier. The multiplication result number is then stored in the memory row 25 and is transferred by fading into the shift register 90 and is automatically clocked to the right by 2 digits if the number 2345.25 is multiplied by the number 64, because then the two Zero digits after the decimal point are omitted. The number 150096 is then, on the other hand, supplemented with the digits 0 in third and fourth place in the display circuit 45 .

If a division is carried out and the first number (in this case the dividend) has already been entered into the shift register 90 , the further operation of the number input is as follows: In this case, the D (division) key is then pressed. Here, the flip-flop 2 of the circuit 12 b tilts into its left position and the circuit 23 is clock- controlled and also the transfer 90-21 a is controlled during the duration of this tapping, in which the circuit 23 supplies the control pulses and the circuit 60 provides nine H-pulses for the clock transfer 90-21 a. From the output of B1 via the input b1 the gate circuit 6 and gate circuit 7 is in this case driven upstream and the divisor is thus keyed into the shift registers 22 and 90 after the dividend is already stored in the shift register 21 a. Here, too, the display circuit 45 is at the H potential from output N3 and this number also appears in the display. The required resetting of the comma-shift register 50 a before this input of the divisor takes place by means of an H pulse from output B4. The decimal point of this divisor is also typed in at the correct position using the P key (left-shifting in the comma shift register 50 a and right-shifting in the comma shift register 50 c / 1/2). The display of the decimal places of the di visor also takes place from the comma shift register 50 a, which was reset when the D key was pressed. Input b3 is controlled by output B3 with H potential and input b5 is controlled by output B5 with an H pulse. The division is triggered by tapping the G key. In this case, the output F8 of the circuit 60 initially delivers nine H pulses, with which the input f8 is driven and with which the comma index n of the comma shift register 50 c / 1/2 is shifted to the right by 9 digits. Then follows the actual division process, in which the pulse circuit 32 is clock-controlled all round. If the division result number (quotient), which is formed in the shift register 90 , has a length of 8 or 9 digits, the circuit 60 comes into effect again, because here the pulse counter 80 of the circuit 60 from the output of the AND circuit 10 of the circuit 12 b with counting pulses being is controlled and thus after 8 or 9 counting pulses at the output of the aND circuit 37 has H potential. Thus, the Divi sions sequence is switched off so that the flip-flop 5 of the circuit 12 b is flipped into its right position from the output of this AND circuit 37 (via the OR circuit 17 ). After the division process has ended, the output E5 has H potential and thus the gate circuit 66 of the display circuit 45 is pre-activated and thus supplies the comma shift register 50 c / 1/2 with the comma index for the result number, which is located in shift register 90 . The result number (quotient) is then clocked to the right in circuit 45 and provided with the necessary zeros.

If an addition is carried out and the first number (in this case the first summand) is already stored in the shift register 90 , the further effect of the number input is as follows: In this case, the key A (addition) tapped. Here, the flip-flop 3 of the circuit 12 b tilts into its left position and the circuit 23 is also clock-controlled and thus the transfer 90-21 b is controlled by the circuit 23 during which the circuit 23 controls the control pulses provides, and the circuit 60 provides nine H-pulses for the clock transfer 90-21 b. From the output of B1 via the input b1 the gate circuit 6 and gate circuit 7 is in this case driven upstream and the second term is thus keyed into the shift registers 22 and 90 after the first Sum mand stored b already in the shift register 21st Here, too, the display circuit 45 is connected to H potential from the output N3 and thus this second summand also appears in the display. In this case, the comma shift register 50 a is reset by means of an H pulse from output C4 and then the comma index of the second summand is only typed into the comma shift register 50 a. The comma index of the first addend is thus in the comma shift register 50 c / 1 and the comma index of the second addend is in the comma shift register 50 a. The first summand is thus in the shift register 21 b and its comma index in the comma shift register 50 c / 1 and the second summand in the shift register 22 and its comma index in the comma shift register 50 a. This is followed by tapping the G key and thus triggering the addition sequence, the circuit 60 initially providing nine additional clocks for the circuit 43 via their output C8, which are not used or are only used in part. If the first term, which is stored b in the shift register 21, two point-points more than the second term, which is stored in the shift register 22, lie therefore fert the output of the circuit c 45 two H pulses, with which the second term (Shift register 22 ) and its associated comma index (comma shift register 50 a) are clocked to the left. In the opposite case, the shift register 21 b and the comma shift register 50 c / 1 are clocked 2 places to the left. Then follows the actual addition sequence, in which the pulse circuit 32 is clock-controlled only once, because the inputs e7 and e8 are at H potential. The addition process is switched off by the output of the AND circuit 47 of the circuit 12 d with an H pulse. Here, the flip-flop 5 of the circuit 12 b tilts to its right position. The addition result number is then faded in by the memory row 25 in the shift register 90 as in multiplication and then, if necessary, clocked to the right and supplemented with the required zero digits, which the display circuit 45 provides as an additional function.

In the case of subtraction, the A key is not pressed when entering the subtrahend, but the S key is pressed. In this case, the output A7 has only L potential and the tetrad circuit 6 is thus pre-activated for subtraction. The subtrahend is thus typed into the shift register 22 after the key S has been pressed. The other mode of action when entering these two numbers is exactly the same as for addition.

If a previous result number is processed further, the R key (reset) is not touched and thus the A key is immediately pressed and then the second summand is typed into the shift registers 22 and 90 or the S key is pressed immediately and then the subtrahend is pushed into the slider gister 22 and 90 typed in or the key M typed in and then the multiplier just typed in the shift register 90 or the key D just typed and then the divisor typed in the shift registers 22 and 90 .

The pulse circuit 23 does not have the flip-flop 7 ; As a result, the output c remains at the H potential until this pulse circuit is reset.

The output B3 is from a branch if necessary of the output DC pre-activated.

Claims (4)

1. Electronic arithmetic circuit for all 4 arithmetic operations, the main circuit ( 10 ) of which consists of a switchable tetrad circuit ( 6 ) for addition and subtraction and a gate circuit system ( 100 ) and which is displayed by inserting the memory row ( 25 ) brings into the shift register ( 21 b) the main number transfer actions and for the number shifts from the shift register ( 90 ) to the shift register ( 21 a) and from the shift register ( 90 ) to the shift register ( 21 b) and from Shift register ( 90 ) in the shift register ( 22 ) brings the shift register clock shift to use, characterized in that the shift register control unit ( 70 ) detects all shift register clock controls. 2. Electronic arithmetic circuit according to claim 1, characterized characterized in that the addition and subtraction the comma indexes are interchanged and that hence the comma index (s) the comma index of the first Is summands or minuends and the comma index (m) the comma index of the second addend or subtrahend is. 3. Electronic arithmetic circuit according to claim 1 or according to claim 1 and 2, characterized in that the output (C 7) of the pulse circuit ( 23 ) after the clock control of this pulse circuit ( 23 ) until the next reset of this pulse Circuit ( 23 ) remains at H potential. 4. Electronic computing circuit according to claim 3, characterized in that the pulse circuit ( 23 ) forms the output (C7) with the output of its last flip-flop.