DE1175275B - Circuit arrangement for influencing the counting capacity of an electronic pulse counter - Google Patents

Description

Circuit arrangement for influencing the counting capacity of an electronic Pulse counter The invention relates to a circuit arrangement for influencing the counting capacity of an electronic pulse counter.

In the case of counters made up of binary levels, there is a special feature that only integer powers of the ratio 1: 2 can be achieved.

It is known to increase the counting capacity of an electronic meter Use of maintenance with diodes and diode gates, high vacuum tubes or transistors to influence so that the desired capacity is achieved. It is necessary to that the binary levels emit a continuous signal. But now there are binary levels that you Emit signal in pulse form and its information is not queried non-destructively can be. Such stages are e.g. B. from magnetic cores with a rectangular hysteresis loop built up. It must be used as a switching means as a gate in binary levels constructed in this way Find use, have the ability to save.

The object on which the invention is based is to provide a circuit arrangement indicate that fulfills the above conditions.

This object is achieved in that a transfluxor with an over a drive and a blocking winding connected in a feedback circuit transistor is provided and that this transfluxor also has a number of windings is provided, with one or more windings arranged on the adjustment yoke that are connected to the "1." or "0" outputs of certain trigger stages, so that when tilting one or the other or all of these windings connected Steps in the "1" or "0" position the Transfluxor is set that also these windings are each connected to a winding arranged on your transfer yoke are that when adjusting the magnetic flux around the transfer hole no voltage can induce in the drive winding of the transistor and that on the carry yoke one or more windings W 2 are present, which start with one or more "1" - or "0" outputs of the bistable stages are connected, so that when tilting this Steps in the "1" or "0" position reverse the direction of the magnetic field and the Transfluxor to emit an output signal and to block is prepared and that one or more further windings W 1 on the transfer yoke are available that are coupled with the »1« or »0« outputs of other stages are that when a "1" or "0" occurs at their output, the transfluxor is activated Output signal emits and is thus blocked, and that more on the blocking yoke Windings are applied, which either with the "1" or the "0" inputs specific Stages are connected, so that when the transfluxor is blocked, these stages in the "1" or "0" position and thus the end position of the counter prematurely is achieved.

An advantage of the invention is that the transfluxor in connection can be used universally with a counting chain because there are many windings on its core can be accommodated, so that a very large number of mutually different, if necessary, switchable counters can be produced with the help of a component can.

In the following, on the basis of FIG. 1 and 2 the function of an exemplary embodiment explained.

F i g. 1. shows the structure of a three-process counter, which consists of four bistable stages connected in a chain. The stages each consist of a magnetic core M 1 to M 4 and two transistors T 1 to T B. Each core has five windings, of which the windings W 1 c and W 2 c with the collectors and the windings W 1 b and W 2 b are connected to the base terminals of the transistors. The winding Ws is used to control the magnetic core and lies between the capacitor C and the resistor R. The structure of all four stages is the same, the inputs of stages two to four are each at the outputs of stages one to three. An additional winding Wo, which is attached to each core, is used to reset the counter, which is done by a pulse Ir that is applied to the reset input. The Transfluxor Tr is provided with six turns W 1 to W 4, We, Wb. The winding W 1 is in series with the collector winding W lc of the transistor T 1, the winding W 3 is connected in series with the setting winding We and the collector winding of the transistor T7. The winding W 4 serves as a control winding for the transistor T9, the collector of which is connected to the blocking winding W6 and the windings W 5 on the core M3 and the winding W 6 on the magnetic core M2. The winding W2 is connected in series with the collector winding of the transistor T5.

The F i g. FIG. 2 shows the timing diagram of the FIG. 1 shown three-process counter. The top row shows the counting rate from 0 to 16. Lines 1 to 4 show the counting process in a normal binary counter, a vertical line above the horizontal means that the binary level has the content "1", a vertical line below the horizontal has the content "0". Since the three-process code is structured in such a way that only the binary tetrads from 0011 to 1,100 are used, it must be ensured that the first three and the last three tetrads are skipped. A single pulse Ir brings the counter to a three-step zero position. Counting begins with the first pulse at input E. The incoming square pulse is differentiated on the RC combination, ie a positive pulse is first obtained from the leading edge, which wants to bring the magnetic core M 1 into the "1" position . However, since the first stage is already in the "1" position according to the three-process zero position, the positive impulse has no effect. Only the negative pulse obtained from the trailing edge of the square pulse causes a magnetic flux in the winding Ws which is directed so that the transistor T2 is opened by a voltage induced in the winding W 2b. The collector current from transistor T2 flows through winding W 2 c and supports the process of magnetization reversal until the magnet core is completely magnetized in the "0" position. In the following, the two possible remanence positions are to be identified by "0" and "1" positions if the transistors T 2 to T 8 or T 1 to T 7 are controlled to be transparent. The core Ml is therefore brought into the "0" position by the first pulse. In this case, a pulse is emitted by the transistor T2 and the core M2 is activated. The further processes in the three-process counter take place in the manner of a normal binary counter. The Transfluxor is not affected for the time being. From the pulse time diagram it can be seen that the reset must be triggered at time t 1 so that the counter returns to the state it was in at time to, ie at the start of counting. When the counter is set to 1000, the collector current of the transistor T 7 flows via the setting winding We of the transfluxor and the winding W 3 on the transfer yoke to the negative potential. The transfluxor is set in such a way that the magnetic flux flows clockwise around the transfer hole. The next three impulses that arrive at the input do not change anything in the state of the transfluxor. When the counter reading is 1100, the collector current of the transistor T5 flows through the winding W 2 on the transfer yoke and reverses the magnetic flux around the transfer hole in a counterclockwise direction. This prepares the Transfluxor to block. The next pulse must switch the counter back to its starting position. Since the next binary trade is 1101 . the newly occurring "1" can be used in the first stage as a criterion for resetting to the three-process zero state. For this purpose, a winding W 1 is applied to the transfer yoke, through which the collector current of the transistor T1 flows, the magnetic flux around the transfer hole being reversed again in the clockwise direction. The voltage induced in the winding W 4 opens the transistor T9. The collector current blocks the transfluxor via the winding Wb, flows via the winding W 5 of the third stage and sets the core M3 back to "0", continues to flow via the winding W 6 and sets the second stage to "1". The third stage emits an impulse when it is tilted into the "0" position, which brings the fourth stage into the "0" position. This means that an increment pulse is given via output A, and the three-step counter has resumed its zero position. The application of the transfluxor is of course not limited to producing a special three-process counter. The Transfluxor can just as well be combined with more or less than four binary levels. It is also possible to use a transfluxor in connection with binary stages which are constructed differently than the stages consisting of magnetic cores and transistors.

Claims (2)

Claims: 1. Circuit arrangement for influencing the counting capacity of an electronic pulse counter consisting of bistable elements that can assume the two states "0" and "1" by forward and / or backward limitation, characterized in that a transfluxor with a control - (W4) and blocking winding (Wb) is provided in feedback circuit connected transistor and that this transfluxor is provided with a number of windings, one or more windings (We) are arranged on the adjustment yoke, which are marked with the »1« - or »0 «Outputs of certain trigger stages are connected, so that when one or the other or all stages connected to these windings are tilted into the» 1 «or» 0 «position, the Transfluxor is set so that these windings each have one on the transfer yoke arranged winding (W3) are connected so that when adjusting the magnetic flux around the transfer yoke no voltage in the Ansteuerwick ment (W4) of the transistor and that one or more windings (W2) are present on the transfer yoke, which are connected to one or more "1" or "0" outputs of the bistable stages, so that when these stages are tilted the direction of the magnetic field can be reversed in the "1" or "0" position and the transfluxor is prepared to emit an output signal and to block, and that one or more further windings (W 1) are present on the carry yoke, which are coupled to the "1" or "0" outputs of other stages in such a way that when a "1" or "0" occurs at their output, the transfluxor sends an output signal and is thus blocked, and others on the blocking yoke Windings (Wb) are applied, which are connected to either the "1" or the "0" inputs of certain stages, so that when the transfluxor is blocked, these stages are brought into the "1" or "0" position and so the end position of the counter prematurely is achieved. 2. Circuit arrangement according to claim 1 for counting pulses after Three-process code, characterized in that on the adjustment yoke of the transfluxor a winding is attached, on the one hand with the "1" output of the last stage is connected and on the other hand with a winding applied in opposite directions the transfer yoke is connected in series, so that when switching the last stage the Transfluxor is set in the "l" state, in such a way that the flow around the The transfer yoke does not induce a voltage in the control winding of the transistor can that further a winding in the same direction as the first winding on the transfer yoke coupled with the "1" output of the first stage, another one with the same direction Winding is provided on the transfer yoke as a control winding of the transistor and that further a blocking winding is applied to the blocking leg, which on the one hand is connected to the collector of the transistor and on the other hand via an additional winding on the magnetic core of the third stage, the same winding sense as the control winding has the same stage, and an additional winding on the magnetic core of the second stage, which like the opposite winding sense the control winding has the same stage, a voltage source is performed, and that the transfer yoke also has the opposite winding, the one with the "1" output the third stage is linked, so that with it the sense of direction of the magnetic field can be turned around in the set state and thus the Transfluxor for dispensing of a signal and being prepared for blocking.