DE1157415B - Arrangement for adding and / or subtracting numbers in the 3-excess code - Google Patents

Description

Arrangement for adding and / or subtracting in 3 excess code Present numbers It is known that the individual decimal digits of a multi-digit Represent the decimal number using binary pulse groups. Such a representation of decimal numbers is called binary-decimal encryption. Will two be so encrypted If decimal numbers are added in a binary adder, the result appears in generally no longer in the chosen binary-decimal encryption, but either in purely binary or other form. To in each case the result of the addition to get back in the desired binary-decimal encryption, must after the sum received can be corrected after the addition.

An arrangement is already known which works on this principle and where the individual decimal digits of the decimal numbers to be added as well as the binary digits used to represent each decimal digit, one after the other are fed to both inputs of a purely binary working adder. The pure In addition, an adder operating in binary mode has a third input the carryover resulting from the addition of a lower decimal place is applied will. The result of the addition appears at the output of the adder in purely binary form Form and is in the known arrangement via a delay element a second adder fed, the second input of a correction register the the necessary impulses for correction are supplied. At the output of the second adder the calculation result can be obtained in the desired binary-decimal form. In this known arrangement, the correction register essentially consists of a pulse generator and gate circuits. The effort for the delay element as well as for the correction register is due to the use of electron tubes very high for the gates and the pulse generator. Another disadvantage this arrangement is that the control voltages for the pulse generator at special Points of the circuit arrangement of the first and second adder are removed have to.

In addition, another arrangement has become known in which two completely identically constructed, purely binary adders are used. The output of the first binary adder is connected to the input of the second adder via delay elements, which feed the calculation result in parallel to an auxiliary counter which supplies a correction value. The determination of the correction value necessary for the binary-decimal representation of the sum, i. H. the definition of the pulse group to be added in the second binary adder to the pulse group supplied by the first binary adder takes place in this auxiliary counter. Although the last-mentioned known arrangement has the advantage over the first arrangement that two binary adders of the same type can be used, which in a known manner have three inputs and two outputs, this arrangement also has the disadvantage of considerable complexity.

The measures taken in the above-mentioned known arrangements can be used with both adders and subtractors.

To reduce the expense of such arrangements for the addition or subtraction of numbers present in a binary-decimal code is according to the Main patent has already been proposed, a first group of by clock pulses to provide sequentially controllable and scannable magnetic cores into which each pulses emitted in series by a first full adder or a full subtractor one pulse group can be permanently stored one after the other, and a second group of being provided simultaneously with the magnetic cores of the first scannable magnetic cores, their magnetic cores are remagnetized according to the required correction pulse group and then simultaneously with the magnetic cores of the first group through successive ones Clock pulses are sampled, and the magnetic cores of the second group via a first winding with a preparatory for the last magnetic core of the first group Clock pulse winding and a second winding with the carry or borrow pulse to connect the supplying output of the first full adder or full subtracter in such a way that that in the absence of a carry or borrower caused by one of the clock pulse Current flow through the first winding according to a first and when one occurs Carry or borrow by a current flow caused by this over the second winding remagnetized according to a second correction pulse group will.

Have the known as well as the previously proposed arrangement a delay element between the output of the first and the input of the second Adder or subtracter is arranged and has the task of the first To temporarily store the pulse group delivered but still to be corrected as long as the adder until the necessary correction pulse group has been determined. In addition or subtraction of numbers present in the 3-excess code delays this delay element the pulses supplied by the first adder by exactly four cycle times. The determination the correction pulse group only takes place after the fourth pulse of a pulse group has been put into the delay element by the first adder.

It is also known that the time required for the addition or Reduce subtraction of binary-decirally encrypted numbers. It will proceeded from the knowledge that the impulse groups necessary for the correction at the first digit are the same, while they differ from one another with respect to the other digits differentiate. In particular, an arrangement has become known in which between two switchable adder-subtracters a delay line is connected, the has fewer binary digits than the encrypted decimal digits and in which the selection of the correction group does not begin until the phase-out the first decimal digit is finished. The known arrangement has over others Arrangements have the advantage that between a first adder or subtracter and a second adder arranged delay element only a delay of has to have a total of two cycle times. A disadvantage of the known arrangement but is still the high effort. The present invention therefore resides in the The object of the invention is to create a circuit arrangement that does not have this disadvantage having. In a further development of the circuit arrangement according to the main patent, this will be according to the invention achieved in that the preparatory winding of the fourth magnetic core of the first group with the release winding of the first magnetic core of the first Group and the release winding of the associated magnetic core of the second group is in series.

A particularly advantageous embodiment is shown on the basis of the drawing and the mode of operation of the circuit arrangement according to the invention explained in more detail.

The arrangement shown consists of the two purely binary adders AD 1 and AD 2, which are connected to one another via a delay element consisting of the four magnetic cores K 1 to K 4 and a correction register consisting of the four magnetic cores K5 to KS. At the two inputs A and B of the adder AD 1 , the two numbers to be added are entered in the form of pulse tetrads. The individual tetrads of these numbers run in series, i. H. Impulse 5 after impulse starting with the least significant digit. The two summands A and B pass through the first full adder AD 1. The subtotal appears at its output S 1 , which, depending on whether the decimal sum is greater or less than 10 , can have four or five digits. # The binary carry that occurs at the output C 2 passes through an intermediate amplifier and is again offered to the carry input C of the adder AD 1 , delayed by a clock time. The structure of such a purely binary series adder is known.

Since in series operation only the fifth binary digit enables the necessary correction pulse group to be determined, the pulse group emitted by the first adder AD 1 at the output S 1 is temporarily stored in the magnetic cores K1 to K4. The correction pulse group to be generated with the aid of the magnetic cores K5 to KS is determined as a function of the occurrence or absence of a carry or borrower pulse at the fifth digit. According to the invention, however, the second, third and fourth pulse of the correction pulse group are only determined with the help of the magnetic cores K6, K7 and K8 when the first pulse of the pulse group to be corrected, i.e. the pulse temporarily stored in the magnetic core K 1 and the associated first pulse of the correction pulse group , which is stored in the magnetic core K 5 , are added to each other. In order to achieve this, on the one hand the output C 1 of the adder AD 1 is connected via an intermediate amplifier with the one setting winding of the magnetic cores K 6, K 7 and K 8 and on the other hand the preparatory winding of the magnetic core K 4 with the second setting winding of the magnetic cores K6, K7 and K8 connected. The preparatory winding of the magnetic core K4 is on the other hand connected in series with the release winding of the magnetic core Kl and release winding of the magnetic core K 5. This ensures that the magnetic cores K6, K7 and K8 are remagnetized in accordance with the required correction pulse group 1100 and 1011 at the same time as the stored pulses from the magnetic cores Kl and K5 and their addition in the adder AD2.

The arrangement works as follows: The first two pulses of a tetrad of the two numbers A and B which are added to one another are entered into the adder AD 1 at time T 1. To form the sum S 1 and the carry C 1 or the amplification of these pulses in the subsequent intermediate amplifiers, exactly one cycle time should be required. At time T2, the first pulse of the sum to be temporarily stored is available. At the same time, the carry appearing at the output Cl of the adder AD1 in the setting winding ESW 1 of the magnetic cores K 6 to K 8 and at the input C of the adder AD 1 becomes effective. The current effective in the setting windings ESW1 should be 1/2, i.e. not sufficient to reverse the magnetization of a magnetic core with only one turn. Thus, none of the magnetic cores K6, K7 and K8 can be remagnetized by the carry or borrow pulse emitted at the output C 1 of the adder AD1, as long as a pulse only appears on the line ESW1. The pulse effective at time T 2 in the storage winding E of the magnetic core Kl, which should also have the size 1/2, is stored in the magnetic core KI by coincidence with a pulse of the same size 1/2 effective in the preparatory winding 17 of the magnetic core Kl . So that the pulse required in the preparatory winding V of the magnetic core Kl can take effect at time T2, this preparatory winding is connected in series to the output T2 of the clock distributor TV with the extraction winding AS of the magnetic core K2 and the extraction winding AS of the magnetic core K 6. In addition, however, the setting winding ESW of the magnetic core K 5 is connected in series with the preparatory winding V of the magnetic core K 1. This has the effect that at time T2 the magnet K5 is not reversed into its "one" position. The pulse delivered at time T3 from the output S1 of the adder AD1 is again stored in the magnet core K2 as before when the pulse was stored in the magnet core Kl by coincidence with a pulse in the preparatory winding V of the magnet core K 2. The pulse emitted at the output C 1 of the adder AD 1 at the time T3 cannot, for the reason given above, be effective in the magnetic cores K6 to K8, just like the pulse emitted at the time T2. At cycle time T4, essentially the same process takes place as at cycle time T3.

A full cycle of the clock distributor TV is thus ended per se. Of the total of four pulses emitted at the output S 1 of the adder AD 1 , however, only three have been stored in the magnetic cores K1 to K3. The fourth pulse, which occurs at cycle time T5 , is only stored in magnetic core K4 at cycle time T1 of the next cycle of the clock distributor. For this purpose, the preparation winding V of the magnetic core K4 is connected in series with the release winding AS of the magnetic core Kl and the release winding AS of the magnetic core K5. In addition, the setting winding ESW2 of the magnetic cores K6, K7 and K8 is connected in series with the preparation winding V of the magnetic core K 4. This setting winding ESW2 has one winding on the magnetic core K 6 , two windings on the magnetic core K 7 and also two windings on the magnetic core K 8. The direction of winding of these windings is the same in all three magnetic cores, while the direction of winding of the setting winding ESW1 in the magnetic core K6 has the same direction, but in the opposite direction in the magnetic coreK7 and in the magnetic coreK8. This ensures that at the same time as the clock pulse TI of the next clock distributor cycle occurs, a pulse is stored in the magnetic core K6 when a pulse occurs at the output C 1 of the adder AD 1 , while storage in the magnetic cores K7 and K8 is prevented. In the absence of a pulse at time T 1 (= T 5) at the output C 1 of the adder AD 1 , on the other hand, the magnet cores K7 and K8 are remagnetized, while a remagnetization of the magnet core K6 is not possible due to the lack of the second half-current 1/2 necessary for coincidence is.

At the same time T 1 , however, a pulse is also effective in the extraction windings AS of the magnetic cores Kl and K5 , which extracts the pulses stored in these magnetic cores and feeds them to the two inputs A and B of the adder AD 2 for addition via the extraction windings A of these none. The definition of the second, third and fourth pulse, which is achieved with the help of the magnetic cores K 6, K7 and K8, takes place at a time when the first pulse of the pulse group to be corrected and the associated first pulse of the correction pulse group is already in the adder AD 2 can be added to each other. Thus a whole cycle time has been gained compared to the known arrangements, in which the addition of the first pulse of the pulse group to be corrected and the first pulse of the correction pulse group is only carried out one cycle time after all the pulses of the correction pulse group have been determined.

Claims (2)

PATENT CLAIMS: 1. Adders or subtractors for numbers present in the 3-excess code, in which a first group of magnetic cores that can be controlled and scanned one after the other by clock pulses is provided, into which the pulses emitted in series by a first full adder or a full subtractor a pulse group are permanently stored one after the other, and in which a second group of simultaneously with the magnetic cores of the first scannable magnetic cores is provided, whose magnetic cores are remagnetized according to the required correction pulse group and then scanned simultaneously with the magnetic cores of the first group by successive clock pulses and in which the Magnetic cores of the second group are connected via a first winding to a clock pulse winding which prepares the last magnetic core of the first group and via a second winding to the output of the first full adder or full subtractor which supplies the carry or borrow pulse ind that in the absence of a carry or borrower caused by a current flow through the first winding caused by the clock pulse, they are remagnetized in accordance with a first winding and, if a carry or borrower occurs, by a current flow caused by the latter through the second winding in accordance with a second correction pulse group, characterized in that the preparatory winding of the fourth magnetic core of the first group is in series with the release winding of the first magnetic core of the first group and the release winding of the associated magnetic core of the second group. 2. Arrangement according spoke 1, characterized in that the setting winding of the first core of the second group is connected in series with the preparatory winding of the first core of the first group. References Considered: British Patent No. 761522. Prior Patents Considered: German Patents Nos. 1090 453, 1 121 383.