DE1549382C - Electric table calculator - Google Patents

Description

In electric desktop calculators with two registers it is used to carry out certain arithmetic Operations necessary that a certain, z. B. the greater number, in a given Register, e.g. B. the view register is located. On the basis of the previous operations or on The reason for entering the numbers incorrectly, however, is the correct assignment of the numbers to the registers of the machine is not always guaranteed. So in such a case there is no need to re-enter the numbers becomes necessary, the operator must enter the two numbers stored in the two registers can be exchanged with one another directly in the machine.

The invention is based on the object of an electric table calculating machine with a device to create with the mutual exchange of numbers in two registers of the machine in easier and is convenient to do.

Based on an electric table calculator with at least two multi-level registers, their individual stages each provided for the storage of a digit one after the other by means of Counting pulses fed in via gates can be advanced to the starting position and, in doing so, carry pulses which are used to recognize the digits stored in the individual register levels serve, this object is achieved according to the invention in that in a buffer counter and in a bistable Circuit by means of a control through the transfer pulses of the register the amount or the The sign of the difference between two digits with the same value from the two registers can be stored, and that the buffer counter can be advanced by means of the counting pulses and thereby emits a carry pulse, which, together with the output of the bistable circuit, is used to control two gates, by means of which of a number of sufficient to advance the buffer counter to the starting position Counting pulses the counting pulses of the higher digit that occur before the carry pulse of the buffer counter storing register stage and the counting pulses occurring after the carry pulse of the buffer counter can be supplied to the register level storing the smaller number.

The circuit according to the invention is based on the idea of the difference between the digits in two register levels determine and save and the register level in which the higher digit is saved, the complement of the determined difference and the level in which the smaller digit is stored, to pass on the difference yourself. The circuit according to the invention is extremely simple below Using just a few elements built. It has the particular advantage that when there is mutual exchange, 55 ' exchange of numbers in multi-level registers, the exchange process is carried out separately for each level and is completed, so that when the individual register stages are controlled one after the other no carry-overs from one stage are saved until the next stage is dealt with Need to become.

The determination and storage of the difference and its sign in the buffer counter or in the The easiest way to make a bistable circuit is to send a carry pulse to each register received carry memory with one emitting a carry signal and one its negation Output is connected and that two gates, each a carry signal from a carry memory and receive the negation of a carry signal from the other carry store, respectively a control input of the bistable circuit directly and jointly the supply of counting pulses to the Control buffer counter. To enter the sign and the amount of the difference in the bistable circuit or the buffer counter are in this training anyway, apart from those for other operations necessary carry-over memories, -only two gates required.

The control of the exchange process such that during a first half of the exchange period the amount and the sign of the difference are stored and that during a second half the exchange period, the two register levels by the complement of the difference or the difference The best way to do this is to use a counter that counts for every ten counting pulses received emits a control pulse via a gate to a second bistable circuit, one of which has an output the gates controlled by the carry memory and their second output that of the buffer counter and prepared the bistable circuit controlled gate.

The activation of the two gates, the one corresponding to the complement of the difference or the difference Forward number of pulses to the two register stages through the output of the bistable circuit and the transfer pulse of the buffer counter happens in a simple .and more reliable Way in that the two gates are connected to the output of the bistable circuit and these can be changed via a third control input by means of the transfer pulse of the buffer counter is and that one of the gates is a control of the supply of counting pulses to one of the two registers Inverter is connected downstream.

So that the circuit is immediately correct when the digits are exchanged in two further register levels is prepared, the buffer counter is expediently by means of an upstream of its input Gate, which is prepared by the second output of the second bistable circuit and receives the carry pulse of the buffer counter, in its carry position persistent.

The invention is described below with further advantageous details on the basis of schematic Drawings explained in more detail using an exemplary embodiment. It shows

F i g. 1 is an isometric view of a desktop calculating machine,

F i g. 2 is a block diagram of part of the clock control of the calculating machine,

F i g. 3 and 4 related block diagrams for the mutual exchange of numbers essential elements of the calculating machine in two registers.

The desktop calculating machine shown in Fig. 1 comprises a housing 1 with a desk-shaped front part 2, on which a numeric keyboard 3 and a control keyboard 4 are arranged. Behind the front part 2 there is a window in front of several number display tubes 6, which belong to a viewing register 20 and each serve to display a digit entered in one of the levels of the visual register.

A button 7 on the front part 2 can be used

Insert a decimal point into a number entered in the view register. The position of the decimal point is indicated by one of the indicator lamps 8. Another key 9 is used to delete the view register, so that an entered number is lost and all display tubes show zero.

The numeric keypad 3 includes ten keys, each of which is one of the digits zero to nine in let the machine enter. To do this, the buttons operate switching contacts in a known manner in such a way that that of periodically generated ten pulses PO to P 9, of which the pulses Pl to P 9 are the switching contacts a number of pulses corresponding to the number on a pressed key arrives at an output line 12 of the keyboard 3 (FIG. 4). Namely z. B. when pressing the key rhit the number 9 the impulses P1 to P 9, when pressing the key with the number 8 the impulses Pl to P 8, etc. forwarded. Pressing the "0" key does not trigger the transmission of an impulse out.

The pulses P1 to P 9 come from the ten outputs of a decadic ring counter 13 (see FIG. 2), which is advanced with counting pulses GD generated by an oscillator 14. The counter 13 is designed using an anode and a cathode comprising tens counter tube so that at any given time only one of its ten outputs performs a pulse that, for so at a particular count GD '. B. at the first output the pulse P 0, at the next counting pulse GD at the second output the pulse P1 etc. until after the pulse P 9 at the tenth output a new cycle begins with the output of another pulse PO at the first output . The oscillator can be controlled by means of a gate 11 which switches off the oscillator if it simultaneously receives a signal Γ0 (explained below) and a signal ST which occurs after a delay after one of the keys on the keyboards 3 or 4 has been pressed.

The pulse P 9 generated at the end of each cycle can reach two clock generators 15 and 18 for the viewing register 20 or the keyboard 3 and two storage registers 22 and 23 via a gate 17. The clocks 15 and 18, like the counter 13, are constructed as ring counters and in principle work like this. However, the clock generator 15 has fourteen stages and emits the pulses T0 to T13 at fourteen outputs. The clock generator 18 has thirteen stages and emits the pulses T1 to T13 at correspondingly thirteen outputs. Since the two clock generators 15 and 18 are controlled by means of the pulses P 9, they are each advanced by one output at most once per cycle of the counter 13.

The outputs TZ to Γ13 of the clock generator 15 are, as shown in FIG. 3, each connected to one of the stages R 3 to R 13 of the viewing register 20. The output Γ 2 is led to a further stage VDPC of the visual register that stores the decimal point. Two register stages R 1 and R 2 are only used for computing purposes and are therefore not shown. The register stages are connected together with a main line 21 via which, controlled by gates shown in FIG. 4, the counting pulses GD can be fed.

.'Eines the control gate is a gate 41 which is connected to an input to the output line 12 of the keypad 3 and a second input connected to the output 12 of the clock 1 eighteenth The gate 41 is used to enter the individual digits of a number in the individual levels of the visual register. As soon as a key on the keyboard 3 is pressed down, as already mentioned, during each cycle of the counter 13 a number of pulses corresponding to the number on the pressed key reaches the gate 41. As soon as a pulse ί 12 is pending at the same time, this gives the way for an equal number of pulses GD via the main line 21 to the viewing register 20 free. Since the pulses / 12 and Γ12 coincide in time due to a control (not shown) for the first digit to be entered, the number of pulses corresponding to the digit on the pressed key goes to step R 12 of the visual register 20. Step R 13 is only used for display of carry-over numbers from level R 12.

ao Since the clock 18 is one step less than the Has clock generator 15 and both are controlled with the same pulses P 9, the clock generator 18 rushes

- The clock generator 15 when entering the next digit "by one step ahead, so that the pulse 1 12 time-

Hch coincides with the impulse Γ11 and a number of impulses corresponding to the new digit reaches the stage R 11 of the visual register that follows stage R 12 on the right. Further digits are transferred accordingly to the next following right level of the visual register.

The two storage registers 22 and 23 each include stages r 3 to r13 for storing the digits and a stage PDPC for storing the decimal point (see FIG. 3). The stages are each connected to one of the outputs / 2 to / 13 of the clock generator 18. A switch 24 which can be actuated by means of the keys R 1 and R 2 of the control keyboard 4 determines which storage register is used. Two numbers in the view register and one of the storage registers are gradually interchangeable. The "φ" key on the control keyboard is used to initiate the exchange. A switch (not shown) can be used to supply a positive voltage to the gates described below at points marked with the symbol φ. By means of gates which are not shown and which intervene in the control of the clock generators 15 and 18, it is ensured during the exchange period that the clock generators 15 and 18 work synchronously.

A gate 25 (FIG. 4) for counting through the stages of the viewing register 20 is connected, like the gate 41, to the main line 21 and enables the supply of counting pulses GD to the individual stages of the viewing register 20 when its inputs φ and C— are controlled. In a corresponding manner, a gate 27 (FIG. 3) for counting through the stages of the storage register 22 or 23 is connected to a line which supplies the counting pulses GD to the switch 24 and supplies the counting pulses GD to the

Storage registers free during the first half (C-) of the exchange period.

As in Fig. As shown in FIG. 3, the outputs of all stages of view register 20 are shown with a carry store 26 connected, the a carry signal COl and its negation ^ tCOl corresponding to the carry pulses from the individual levels of the visual register. The outputs of all stages of the storage registers 22 and 23 are in a corresponding manner with a

5 6

Carry memory 28 connected, which is a carry with the outputs C - and C + according to FIG. 3

signal C 02 and its negation φ C 02. a gate 37 connected upstream, which at its inputs

A gate 29, which is used to determine whether one of the pulses P9, φΤΟ and φ receives. The order

Digit in the memory register is greater than the corresponding one is made so that with a first series of ten

chendc number in the view register, is according to F i g. 4 to 5 counting pulses during the activation of the output

one to the input of a decade buffer counter 35 C - the circuit 36 the difference between the

leading line 40 and at an input α of a digit in two register stages is determined and

bistable circuit 31 connected. The exact that a second series of ten counts to the

The circuit of the gate 29 is based on FIG. 4 shows where the exchange of correction pulses is used, see above

at 9 'means the pulses P1 to P9. A gate 30 io that the digits contained in the two register stages

to determine whether a digit in the view register is greater than distant during the activation of output C +

is than the corresponding digit in the memory register, can be exchanged with each other. Intended for that

is according to FIG. 4 also to the line 40 and to the bistable circuit 36 with the gate 37 den

an input β of the bistable circuit 31 is the time of the entry of correction pulses into the

closed. The circuit 31 has an output Y 15 relevant register stages during the second

and a further input Bφθ, at which it is half (C +) of the exchange period. The bistable

in a stage 44 inverted carry output ß = 0 circuit is also used to use the output

of the buffer counter 35, which also receives a passage C- the passage of only every other pulse

Another input to line 40 is connected to P 9 through gate 17 (FIG. 2) to the clock generators

Senen gate 42 is supplied for the zero detection. 20 15 and 18 to be admitted. By means of an input φ

The two gates 30 and 29 receive the over- the gate 17 is ensured that it is only during

carrying signals COl and ^ fcC02 or C 02 and ^ COl. can block an exchange.

From these signals, the difference between the following explained mode of action of the

the desktop calculators stored in the view register and in the storage register when exchanging numbers

determined digits. For this purpose, a series of 25 refers to the related F i g. 3

ten counting pulses correspond to the relevant levels of the visual and 4.

registers and the memory register one after the other

guided. If the exchange key »φ« is pressed in one step of a register and thereby a positive

stored digit has been counted further until zero, tive potential to all gate marked with »φ«

a carry pulse is applied and the output of the over 30 inputs. The counting gate 25 opens,

Tragspeichers 26 or 28 (F i g. 3) a carry signal so that pulses GD via the main line 21 to a

generated that one of the two gates 29, 30 opens stage of the view register 20 are forwarded,

and arrives at the bistable circuit 31. If that also opens the counting gate 27, so that counting

Gate 29 opens first, this means that a digit pulse GD via switch 24 to the corresponding

fer in the memory register greater than a digit in the 35 level of the selected memory register 22 or 23

View register is. In this case, they reach the entrance. The counting pulses GD are in the two

the bistable circuit 31 forwarded signals transmit connections synchronously and arrive

cause output Y to become positive. Therefore, if at the same time to the relevant registers 20

on the other hand, a digit in the view register greater than and 22 or 23, with a first group of ten

is a digit in the storage register, the pulse becomes 40 counts of the lowest level of each register

COl delivered before the pulse C 02 and the gate is fed. Each counting pulse switches one in

30 opened in front of gate 29, in which case a digit introduced into a register step further by one,

Signal to the other input β of the bistable switching to zero and then the original digit again

device 31 and the output Y becomes negative. That is enough. Goes through a stage of view register 20

Difference between the view register and the memory 45 zero, the carry signal COl is triggered and from

The digits entered in the memory register are thereby transferred to the carry-over memory 26. In the same way

is true that the through a carry signal COl or is at the zero crossing of a stage of a Speieher-

C 02 opened and the negation φ C 02 or φ C 01 registers triggered the carry signal C 02 and from

of the other carry signal again blocked gate carry memory 28 released. The signals COl and

ter 30 or 29 act on the line 40 and 50 C 02 arrive at the correspondingly designated

through the temporary forwarding of counting pulses ends of the two differential gates 29 and 30, respectively.

Effect GD to buffer counter 35. If the signal COl arrives before the signal C 02,

The output Y of the circuit 31 is connected to the input. Since the digit in the view register is the higher, an output of a gate 32 is carried, the output of which conducts a diode 33 with a transistor comprising a transistor via a signal to the input β of the bistable circuit 31 . If, on the other hand, the signal C 02 arrives first, which is connected to its output on the main line 21 because the digit in the memory register is the higher, the connected inverter 34 is connected. conversely, a signal to the input of the bistable

A circuit 31 is routed to the line leading to the switch 24. If COI arrives before C 02, closed, in FIG. The gate 38 shown in 3 also controls the input of the buffer counter 35 freely depending on the number of pulses GD received in the buffer counter 60, so that the buffer counter counts the number of pulses stored after 35 the supply of counting arrival of the signal COl received counting pulses GD to the stages the storage register 22 counts. However, when the signal or 23 occurs, it ceases to count in such a way that the difference C 02 ends the signal ^ C02, whereby any further reference or the complement of the difference between the supply of counting pulses to the buffer counter 35 g the number of those in a storage register and which is blocked in 65. In the state then reached, the pulses with the buffer counter stored in the view register have stored a number of pulses which is the difference in the number of pulses in the

The view register and one stage corresponding to the digit input of a bistable circuit 36

Corresponds to the storage register. On the basis of the polarity of the output Y of the circuit 31, which depends on whether the input \ or ή has been activated, it is determined in which of the registers the larger number is stored.

After nine pulses have been received, the pulse P 9 is passed via the gate 37 into the bistable circuit 36, causing it to switch over and activate output C 4 instead of output C-. The signal C + goes to an input of the gate 32. If the digit stored in the view register is greater than the digit stored in the memory register, the input Y of the gate 32 is driven negatively, so that the transistor of the inverter 34 blocks and the forwarding of counting pulses on the main line 21 releases. As a result, a number of pulses corresponding to the complement of the number of pulses stored in the buffer counter is passed into the appropriate stage of the view register. However, the output Y of the circuit 31 changes its polarity after the input of the inverted carry output B = O of the buffer counter 35, so that * the main line 21 is blocked and, by means of the gate 38, the line to the switch 24 in front of the storage registers 22, 23 is released and thereby the rest the ten counting pulses occurring during the second half (C +) of the exchange period is entered into one of the two storage registers.

On the other hand, if a digit stored in the memory register is greater than a digit in the view register, the opposite effect occurs, whereby the difference stored in the buffer counter is transferred to the View register and the complement of the difference is given in a storage register.

The above operation is performed for each stage of the view register and a storage register repeated until all digits stored in one register have been exchanged for those in the other register are. The operation is carried out in a similar way for those storing the position of the decimal point Steps carried out and thereby a change in the position of the decimal point in accordingly effected in the same way in the view register and in the storage register.

Claims (5)

Patent claims: 1. Electric desktop calculator with a device for mutual exchange of the Numbers in two multi-level registers of the machine, each of which is for storage Steps provided for a digit one after the other by means of counting pulses supplied via .Gate can be continued up to the starting position and thereby emit transfer pulses, which to identify the in the individual register levels stored digits are used, characterized in that in a buffer counter (35) and in a bistable circuit (31) by means of a control by the carry pulses (COl; C02) the register (20; 22; 23) the amount or the sign of the difference between two digits with the same value from the two registers can be stored and that the buffer counter can be advanced by means of the counting pulses (GD) and a carry pulse (B = O), which, together with the output (Y) of the bistable circuit, serves to control two gates (32, 38), by means of which, from a number of counting pulses sufficient to advance the buffer counter to the starting position, the counting pulses occurring before the carry pulse of the buffer counter the register stage storing the higher digit and the counting pulses occurring after the carry pulse of the buffer counter can be fed to the register stage storing the lower digit. 2. Table calculating machine according to claim 1, characterized in that at each register (20; 22, 23) a carry pulse receiving the carry memory (26; 28) with a carry signal (COl, C 02) and one of its negation (^ = COl, φ C 02) output is connected and that two gates (29; 30), which each receive a carry signal from a carry memory and the negation of a carry signal from the other carry memory, each have a control input (λ; β) of the bistable circuit (31 ) directly and jointly the supply of counting pulses (GD) to the buffer counter (35) control. 3. Desktop computer according to claim 2, characterized in that a counter (13) for every ten received ^! Counting pulses (GD) emits a control pulse (P9) via a gate (37) to a second bistable circuit (36), one output (C-) of which is the gates (29; 30) controlled by the carry memory (26; 28) and their second output (C +) prepared by the buffer counter (35) and the bistable circuit (31) controlled gates (32: 38). 4. Desktop calculating machine according to one of claims 1 to 3, characterized in that the two gates (32; 38) are connected to the output (Y) of the bistable circuit (31) and this via a third control input by means of the carry pulse (B = O) of the buffer counter (35) is convertible and that one of the gates (32) is the supply of counting pulses (GD) to one of the. two registers (20) controlling. Inverter (34) is connected downstream. 5. table calculating machine according to claim 3 and 4, characterized in that the buffer counter (35) by means of a gate (42) connected upstream of its input, which is passed through the second Output (C 4-) of the second bistable circuit (36) is prepared and receives the carry pulse (B = O) of the buffer counter in its Transfer position can be stopped. For this purpose 2 sheets of drawings 109643/130