DE1136375B - Circuit arrangement counting forward and backward - Google Patents

Description

Up and down counting circuitry The invention relates to is based on an up and down counting circuit that consists of a binary and a quinary counter part.

There are already various counters working forwards and backwards known, so z. B. designed as a ring counter decimal counter, consisting of ten bistable stages that are used to transmit counted values in both directions are connected. The pulses to be counted arrive at two separate inputs the counting circuit. One of these inputs is assigned to an up-counting device and connected to the individual counting stages in such a way that the incoming over it Pulses switch the counter through in forward direction. Incoming via the other entrance Due to the wiring of these inputs with the counting levels, counting pulses are generated a count in reverse direction. This counting circuit has the disadvantage that it requires a great deal of active switching elements. Other numbers are than Biquinary counter with six bistable stages designed in a similar way. The effort is still considerably high here, as it has a total of twelve tubes or transistors requires.

They are also circuits made with magnetic components known for forward and reverse operation. These are in the shape of a ring counter and have a magnetic core with rectangular characteristics for each counting stage.

Two coupling links are provided between the individual stages for counting value transmission in forward and backward direction. Two control lines serve one or the other by applying a control voltage to the coupling elements Direction to choose the counting direction by placing the coupling links in the opposite direction Counting direction are blocked. These counting circuits are disadvantageous in that a visual display of the counter values without extensive additional effort is possible.

In electronic counting devices, which are used in particular in measuring and Test devices are to be used, is a simple connection to a Visual display device of particular importance. This requirement is always then easy to fulfill if the individual counting levels consist of tubes or transistors, which provide output signals with a sufficiently large amplitude. About the effort To keep counting circuits as small as possible has already been proposed to set up a biquinary counter that can only be operated in the forward direction in such a way that that the quinary part of the counter consists of five tubes that are successively conductive and in connection with a bistable stage representing the binary part embody the respective count value. A visual indicator is with the anodes of the tubes of the binary and quinary part in a simple manner.

The object of the invention is now to provide an electronic counting arrangement of the last-mentioned type without much additional effort for a counting operation in advance and backward direction, whereby according to a frequent requirement of the measuring and control technology, the counting pulses are not fed to separate inputs, but rather come in via just one input and, depending on control commands, move forward or counted backwards. Essentially this is achieved in that the Quinary part of five active switching elements that keep each other in their conductive state consists, which under each other by two running in opposite directions Count value transmission paths are connected that the binary part has two of its switching states Has corresponding outputs that correspond to the switching elements of the quinary part or are connected to the decade carry output, and that two counting directions associated control inputs are provided, which on the one hand via blocking circuits with the outputs of the binary part and on the other hand with the transmission paths are connected so that when a control signal occurs in accordance with the selected counting direction has one output and the transmission paths the opposite Direction are locked.

An exemplary embodiment is described below with the aid of a drawing.

A counting circuit is shown which consists of a so-called quinary counter part having five counting stages A, B, C, D, E and a so-called binary counter part connected upstream of this, which has two counting stages F, G. The counting circuit works in such a way that all even count values are represented by one count position of the binary part in connection with the five possible count positions of the quinary part, while all odd count values are represented by the other count position of the binary part in connection with the five count positions of the quinary part Marked are.

The binary part consists of a bistable multivibrator, a flip-flop circuit, which is formed from two transistors 1, 2. The collectors of these transistors are connected via resistors 3 and a common resistor 4 to a line 5 carrying zero potential. Both emitters are connected to zero potential via a resistor 6. The base of the transistor 1 is coupled to the collector of the transistor 2 by a resistor-capacitor combination 7. Likewise, the base of the transistor 2 is also connected to the collector of the transistor 1 by the same switching means. The input 8 of the counting arrangement is connected to the bases of the transistors 1, 2 via capacitor 9 and diodes 10. Resistors 11 form blocking circuits with diodes 10 , which are controlled by the collectors of transistors 1, 2: As a result, the positive input pulses only reach the base of the respective conductive transistor, since the diode 10 of the non-conductive transistor is blocked by a high negative voltage. A capacitor 12 prevents undesired repercussions of the binary part on the quinary part connected to the same operating voltage line 5.

From the collectors of the transistors 1, 2 result in output lines 44, 45 via coupling capacitors 13, diodes 14,15 a common line 16, coupling capacitors 17 and switching diode 18 to the bases of transistors 20 to 24 which belong to the quinary part of the counting circuit. The collector of each transistor 20 to 24 is connected on the one hand via a resistor 25 to the line 5 and on the other hand connected via a resistor 26 to the bases of all the other transistors. In addition, a transmission path leads from each collector via a coupling capacitor 27 and a diode 28v, 28r to the bases of the transistors adjacent in the two counting directions. The emitters of the transistors 20 to 24 are at zero potential with the interposition of a common resistor 29; connected. One output line 30, 31 each leads from the collector lines of the transistors 20 and 24 via one coupling capacitor 32, one diode 33, 34 and one common line 35 to a decade transmission output 36 of the counting circuit. The commands for counting in forwards or backwards direction appear on control inputs V, R. The diodes 28v, in conjunction with resistors 37v, form blocking circuits which are activated via a line 38 connected to the control input V. As soon as a sufficiently high positive voltage is applied to the control input V, the diodes 28 v are in the blocking range, so that, for. B. a negative pulse at the collector of transistor 20 does not reach the base of transistor 21 . Likewise, the blocking circuits formed by the diodes 28 r and resistors 37 r are controlled by positive control signals at the input R via line 39, in that a positive control voltage blocks the diodes 28 r for pulse passage.

The lines 38, 39 are connected by resistors 40, 41 on the anode side. connected to the diodes 15, 14 , whereby blocking circuits are formed in the transmission paths between the two stages of the binary part and the input of the quinary part. In the event of a positive signal on one of the control inputs V, R, the corresponding diode 15, 14 for the positive collector pulses on the binary part is brought into the pass band, while it is blocked by the negative voltage normally applied to the control inputs.

Similar blocking circuits are by means of resistors 42, 43 and the diodes 34, 33 arranged in the decade output line 35. These diodes too are blocked in the manner described depending on the control inputs or brought into the pass band.

The mode of operation of the counting device is described below: For this purpose, it is assumed that the counting arrangement is in the counting position zero, that is to say that stages A and F are energized. The incoming counting pulses are to be counted in forward direction. Therefore, a positive control voltage is applied to the control input R, which the transmission paths formed by the switching elements 27, 28 r between the quinary stages ED; DC, CB, BA, AE blocks and the output 44 connected to line 16 of stage F of the binary part opens. In addition, the decade carry output 36 from stage A is also opened by diode 33. The first of the counting pulses subsequently occurring at input 8 reaches the base of transistor 1, which is thereby blocked. A voltage jump developing at its collector becomes effective at the base of transistor 2 and makes it conductive. The positive pulse generated at the emitter of this transistor remains ineffective for the input of the quinary part, since the diode 15 is blocked: Stage G is now live, while stage F is blocked. This state corresponds to count position 1.

The next counting pulse arrives at the base of transistor 2 and resets stage G to the non-conductive state and stage F to the conductive state in the manner described. The positive voltage jump arising during this process at the collector of transistor 1 reaches the bases of transistors 20 to 24 via diode 14, line 16 and diodes 18. However, it is only effective at the base of conductive transistor 20. by blocking it. In this case, the transistor's collector forms a negative = pulse, which runs through the associated capacitor 27 and the diode 28v to the base of the transistor 21 and causes it to become conductive. By connecting the collectors of the transistors 20, 22 to 24 via the corresponding resistor 26 to the base of the transistor 21, the set state is maintained. The circuit arrangement is now in counting position 2, since stages F and B are conductive.

The third counting pulse switches the binary part, so that the stage G becomes conductive in order to mark the count position 3 in connection with level B. As a result of the next counting pulse, the binary part is reset again a positive pulse is triggered on line 16, which blocks transistor 21, so that by the voltage change at its collector, the transistor 22 in the conductive State occurs. The counting position 4 is then by passing the stages F and C characterized. The further connection of the takes place in the same way Counter by dividing the even digits through the conductive state of the stage F in conjunction with a conductive level A bis. E and the odd digits through the conductive state of level G is shown with a conductive level A to E. will.

After the ninth counting pulse has made stages G and E conductive the tenth pulse resets the counting circuit to its original position. The negative voltage jump resulting from this at the collector of the transistor 24 arrives to the base of the transistor 20 and makes it conductive. At the collector of this transistor a positive voltage jump occurs, via line 30 and the open diode 33 is routed to output 36 as a decade carry. With the arrival of further counting pulses the switching of the counter begins again.

If the counting is to take place in the reverse direction, the control input receives V positive and the control input R negative voltage potential. This will be the diodes 28v of the transmission paths in the forward direction between the stages of the quinary part blocked and assigned to the transmission paths in the reverse direction Diodes 28r brought into the pass band. In addition, the diodes 14 and 33 locked and the diodes 15 and 34 opened.

The first counting pulse switches the counter from counting position 0 to the counting position 9, whereby a decade carry is generated. This is done by the pulse makes transistor 2 non-conductive. Thereupon runs from its collector a positive pulse through diode 15, line 16 and diode 18 to the base of the transistor 20. This is blocked and its collector supplies a negative voltage jump via the corresponding diode 28r to the base of the transistor 24 and makes it conductive. The counter thus assumes: Counting position 9. When the transistor becomes conductive 24 forms a positive voltage jump on its collector, which exceeds Line 31, capacitor 32 and the opened diode 34 to the decade transfer output and represents the decade carryover.

A subsequent counting pulse brings level G into the blocking and the Stage F in the conducting state, which is in connection with the still conducting stage E of the Counting position 8 corresponds. The third pulse makes stage G conductive, with the quinary part is switched back to level D, so that the counting position 7 for display got. In this way the counter is switched through until the tenth pulse has brought the counting circuit to zero.

Should the counting circuit for a special purpose as a counter only for one Direction are used, the control inputs V, R are used in this counting direction accordingly firmly connected to the required plus or minus voltage.

A known display device, e.g. B. a decadic indicator tube or a glow lamp arrangement, are used. to For this purpose, the collector lines of the transistors 2, 20 to 24 are connected via isolating resistors 46 output lines 47 coupled directly to the correspondingly adapted display device or one of these upstream intermediate storage devices. An additional Effort for coupling to the display device is not required because a Decoder does not need to be interposed.

The invention is not restricted to the exemplary embodiment described. So z. B. the blocking circuits built in the present case with diodes and resistors in the transmission paths between the stages of the quinary part, between the binary and the quinary part and between stages A and B and the decade transfer output can be replaced by any other blocking or gate circuits.

Furthermore, the operation of the counting circuit is not limited to that Principle of the distinction between even and odd digits by the preceding binary part limited. The arrangement can also be purely biquinary in a known manner work by adding the binary part after the quinary part. The count then takes place in two groups zero to four and five to nine. Each group consists from a connection of the quinary part. Serve to distinguish the groups the two positions of the binary part.

In such a case, the input of the counting circuit is connected to the input of the quinary part, in the example shown with the line 16, connected. Of the The output of the quinary part, which was previously used as the decade carry output 36, is then coupled to the input of the binary part, its associated with the two stages Outputs via the gate circuits shown and controlled by the control inputs are connected to the decade carry output. The control inputs block or also open the transmission paths between the stages of the quinary part, the outputs of the quinary part and the outputs of the binary part. Furthermore the operation of such a counting circuit is the same as that used in conjunction was described with the drawing.

Claims (6)

PATENT CLAIMS: 1. Up and down counting circuitry with a binary and a quinary counter part, characterized in that the Quinary part of five active switching elements that keep each other in their conductive state (20 to 24), which are divided by two in opposite directions running count transmission paths are connected that the binary part has two Has outputs (44, 45) corresponding to the switching states, which correspond to the switching elements of the quinary part or with the decade carry output, and that two control inputs (V, R) assigned to the counting directions are provided; the above Locking circuits (28, 37, 14, 15, 40, 41) on the one hand with the outputs of the binary Part and on the other hand are connected to the transmission paths so that when they occur of a control signal in accordance with the selected counting direction an output and the transmission paths in the opposite direction are blocked. 2. Circuit arrangement according to claim 1, characterized in that the first and last stage (A, E) of the quinary part each has an output (31, 30) with each other and with the Decade carry output (36) or are connected to the input of the binary part and by blocking circuits (33, 34; 42, 43) from the control inputs (V, R) in accordance with the selected Counting direction can be made effective individually. 3. Circuit arrangement according to claim 1 or 2, characterized in that the blocking circuits (28, 37, 14, 15, 33, 34, 40 to 43) consist of a resistor-diode link. 4. Circuit arrangement according to claim 3, characterized in that the blocking circuits (28, 37, 14, 15, 33, 34, 40 to 43) each consist of a switching diode controlled by a resistor. 5. Circuit arrangement according to one of claims 1 to 4, characterized characterized in that as active switching elements (1, 2, 20 to 24) of the binary and quinary part transistors are provided: 6. Circuit arrangement according to a of claims 1 to 5, characterized in that the switching elements (2, 20 to 24) of the binary and quinary part in a known manner with a display device are connected.