DE1268664B - Circuit arrangement for checking the time interval between electrical signals - Google Patents

Description

Circuit arrangement for controlling the time interval electrical Signals The invention relates to a circuit arrangement, in particular for control mechanical processes, the movement of which is converted into electrical signals and which supplies a control signal as long as the signals arriving via two channels fall below a certain time interval.

Circuits are known which convert electrical signals into direct voltages convert. Such a circuit is known in the literature under the designation "charging diode circuit" known. The charging diode circuit generates a DC voltage whose size is determined by the time interval between the input signals. The DC voltage is the greater the smaller the signal spacing.

There are also known circuit arrangements in which the output a charging diode circuit to the input of a threshold value transmitter (e.g. Schmitt trigger) is led. The threshold value transmitter supplies a DC voltage signal as long as the DC voltage present at the input exceeds or exceeds a certain value signals carried to the input of the charging diode hold a certain time Distance below.

Furthermore, so-called OR circuits are known which have an output signal as long as there is an input signal at one of several inputs.

Like any rectifier circuit, the charging diode circuit adheres to the The disadvantage is that the input signals must have a constant level and that a large number of signals have to arrive before the final value of the DC voltage is reached has set. This means that the control signal is above all with a large Time delay appears when the final value of the DC voltage is only a little is above the trigger threshold of the threshold value transmitter.

Another disadvantage is that especially when following At very short time intervals between the input signals, these suddenly become temporal Have a distance that is only slightly below the specified criterion, the charging diode circuit It takes a very long time until the new value of the direct voltage is set has, whereby the control signal is also terminated with a very large delay.

The DC voltage output by the charging diode circuit also has a DC voltage due to the effective charge and discharge time constant, a ripple, creating a certain Voltage range exists, in which the threshold value transmitter in the rhythm of the ripple is triggered. The circuit arrangement is not clear in this transition area Statement as to whether the input signals fall below the specified time interval. The transition area can be narrowed by using a threshold value transmitter with a great hysteresis.

This means, however, that there are large differences between the temporal There are distances between the input signals at which the control signal appears and where it is ended again. Another possibility is the integration time constant the charging diode circuit to be designed very large. In this case, the described increases time delays with which the control signal appears and ends, considerably. Due to the larger the larger the input signal distance The ripple that is created can be used in particular with semiconductor components Hardly use charging diode circuits for the purpose described here, if the circuit arrangement should respond at signal intervals .r 10 (i ms.

During various mechanical processes, their movements are transformed into electrical ones Signals are converted, the signals appear depending on the direction of movement via two separate channels. There is often the requirement that the circuit arrangement No control signal is allowed to emit if signals appear alternately via both channels (oscillating around a point due to vibration, etc.).

A movement control with the help of two charging diode circuits downstream threshold value transmitter, the outputs of the threshold value transmitter on a OR circuit is not possible because the delayed Occurring output signals of the threshold value transmitter when changing direction an interruption of the control signal.

The purpose of the invention is to create a circuit arrangement which delivers a control signal as soon as the input signals have reached a certain time Distance below.

When the input signals are fed in, no control signal may appear, if an input signal is fed in alternately via the two channels.

The circuit arrangement should also be able to be used for long time intervals and the delays that occur should be twice the value specified Do not exceed signal distances.

The invention is based on the object of a circuit arrangement to create the direction-dependent movement control of such mechanical Processes are suitable, the movement of which by means of appropriate devices in electrical Signals is implemented. The circuit arrangement should be compared to the previously known Address circuit arrangements with a much shorter time delay.

In the circuit arrangement for checking the time interval electrical signals that are transmitted over two channels, in particular for Control of mechanical processes is used, their movements in electrical signals are implemented, the feed to be controlled takes place according to the invention electrical signals to the parallel-connected pulse inputs of a first and second bistable flip-flop.

The first bistable multivibrator is activated by the signals of channel I into the state »0« and through signals of channel II into the state »1« switched. The connection of the two control inputs of the second bistable multivibrator each with an output of the first bistable trigger stage causes that when changing the Signals from one channel to the other the first signal only the first bistable Flipper flips over and only the second signal enters the second bistable flip-flop State »1« switches.

An output of the second bistable multivibrator is connected to the control input connected to a third bistable multivibrator and prevents resetting of the third bistable flip-flop in the state "0" as long as the second bistable Flip-flop is in state »1«. The second output of the second bistable multivibrator is connected to the pulse input of the third bistable multivibrator. This will the third bistable multivibrator is switched to the "1" state when the second bistable Flip-flop switches from state »0« to state »1«.

The output of an astable or monostable multivibrator arrangement is connected to the pulse inputs of the second and third bistable multivibrator. These output pulses of the astable or monostable multivibrator switch the second bistable multivibrator in the state "0", the zero position of the third bistable flip-flop only takes place when a pulse input is received at its pulse input Pulse is applied and the second bistable multivibrator is already in the "0" state.

A signal is generated at an output of the third bistable multivibrator taken for triggering control functions. When using a monostable Flip-flop arrangement is its pulse input with the output of a generator, its Control input with the output of the second bistable multivibrator and its outputs each connected to a pulse input of the second and third bistable multivibrator. As a result, the monostable multivibrator arrangement is only then activated by a generator triggered when the first bistable multivibrator is in the "1" state. At the Tilting into the metastable state causes the monostable multivibrator to reset the second bistable flip-flop and the reset when tilting back into the idle state the third bistable multivibrator if the second monostable is at this point in time Flip-flop is already in the »0« state. For the realization of large temporal The monostable multivibrator arrangement can also consist of several monostable spacings There are tilting stages. Each monostable tilting stage releases when tilting back into the rest state the following flip-flop off.

The output of the first monostable multivibrator is connected to the pulse input the first bistable multivibrator and that of the last monostable multivibrator with the Pulse input of the second bistable multivibrator connected.

For special applications, the tipping times of the monostable or astable multivibrator arrangements can also be designed to be adjustable.

In order to reduce the time tolerances, the synchronous inputs can of the astable multivibrator arrangement can be connected to the input channels.

The circuit arrangement according to the invention enables the temporal To control the distance between electrical signals, the delay with which the Control signal is deleted and generated, compared to previously known circuits is many times smaller. The time intervals to which the Circuit responds, vary slightly. There are compared to the previously known circuit arrangements greater time intervals can be achieved.

The circuit arrangement can be used, for example, to control movement use of scales, which so far has mostly only been done mechanically, except A relatively high level of wear and tear also occurred.

When using the circuit arrangement according to the invention for movement control of the scales in dosing equipment will significantly reduce processing times achieved.

The invention is to be described in more detail below using an exemplary embodiment explained. In the drawing, F i g. 1 shows the basic circuit diagram of a circuit arrangement for checking the time interval between electrical signals, F i g. 2 the circuit diagram of the bistable flip-flops used, F i g. 3 the state diagram of the bistable multivibrators, F i g. 4 shows the circuit diagram of the monostable multivibrator arrangement used.

The in F i g. The bistable flip-flop shown in 2 flips into the state "0" if. there is a positive signal at pulse input 1 and the control input 2 has a potential of about 0 V. If there is a negative voltage at control input 2 more appropriate Size will be the one arriving at pulse input 1 positive signal from the following diode is not transmitted, and the bistable multivibrator does not tip over. Analogously, the bistable multivibrator switches to the "1" state if A positive signal arrives at pulse input 3 or 4 and control input 5 or 6 has a potential of about 0 V.

If the bistable multivibrator is in the "0" state, it is at the output 7 a negative voltage and a voltage of about 0 V at output 8.

The signals of the channels to be measured are sent to inputs 9 and 10 of the circuit arrangement of FIG. 1 led. From entrance 9 you get to the Pulse inputs 4 and from input 10 to pulse inputs 1 and 3 of the bistable Tilt levels 11 and 12.

It is assumed that the bistable flip-flops 11 and 12 in the Status »0«.

A positive signal arriving at input 9 flips the bistable Flip-flop 11 in the state "1". The bistable flip-flop 12 remains in the state "0", because its pulse input 4 is determined by the output 7 of the bistable multivibrator 11 on the control input 6 of the bistable flip-flop 12 guided negative voltage blocked is.

Only when a second signal arrives at input 9 is the control input 6 of the bistable multivibrator 12 at approximately 0 V, and this stage is toggled into the "1" state via the pulse input 4.

If the bistable flip-flop 11 is in the "1" state and the bistable Trigger stage 12 in the "0" state causes a positive arriving at input 10 Signal that the bistable multivibrator 11 is switched to the "0" state (via pulse input 1). The bistable multivibrator 12 remains in the "0" state because its pulse input 3 by the output 8 of the bistable multivibrator to the control input 5 of the bistable Trigger stage 12 led negative voltage is blocked.

Here, too, only a second one arrives at input 10 causes Signal that the bistable flip-flop 12 is switched to the "1" state.

This means that incoming 9 and 10 alternate Signals the bistable multivibrator 11 oscillates between the state "0" and "1", while the bistable multivibrator 12 remains in the "0" state.

If the signals only arrive at input 9, each signal causes the bistable flip-flop 12 to flip over to the "1" state if it and the bistable flip-flop 11 are in the "0" state when the signal arrives. The astable multivibrator arrangement 13 emits continuously positive pulses via the output 14, the time interval between which is tA. These pulses are sent to the pulse inputs 1 of the bistable multivibrators 12 and 15, so that these multivibrators are in the "0" state as long as no signals are received at the inputs 9 and 10. If the bistable multivibrator 15 is in the “0” state, the circuit arrangement emits a negative voltage via the output 16. As soon as the bistable multivibrator 12 switches to the "1" state due to signals arriving at the input 9 or 10, the bistable multivibrator 15 receives a positive voltage jump at the output 7 of the bistable multivibrator 12 on the pulse input 4 and also switches to the "1" state. A voltage of approximately 0 V appears at the output 16. The next positive pulse arriving from the astable multivibrator arrangement 13 switches the bistable multivibrator 12 to the "0" state via the pulse input 1. The bistable multivibrator 15 remains in the "1" state, since its pulse input 1 is still blocked via control input 2.

The bistable flip-flop 12 is when the next one arrives the pulse emitted by the astable multivibrator arrangement 13 is still in the "0" state, this also toggles the bistable flip-flop 15 to the "0" state.

If the signals arriving at input 9 or 10 are at a distance of <tA, a voltage of approximately 0 V is present at output 16.

If the distance between the signals is > tA, there is a negative voltage at output 16, which can sometimes drop to about 0 V for a short time.

F i g. 3 shows an overview of how the switching states of the bistable multivibrators change with different activation via inputs 9 and 10 .

If the signals arriving at input 9_ or 10 have a time interval that is only slightly below tA, the circuit arrangement responds to two or more input signals. This depends on the time interval between the positive signals present at input 9 or 10 and the potential pulses emitted by the astable multivibrator arrangement 13 via output 14. A smaller tolerance with regard to the response of the circuit arrangement is obtained by sending the signals from the inputs 9 and 10 to the astable multivibrator arrangement 13 for synchronization. A clear response after two input signals is possible if, instead of the astable multivibrator arrangement 13, a monostable multivibrator arrangement according to FIG. 4 is used with the tipping time tA. The inputs and outputs of the monostable multivibrator arrangement are connected as follows: On the pulse input 17, positive pulses with a spacing << tA are given from an additional generator. The control input 18 is connected to the output 7 of the bistable multivibrator 12. The output 19 is routed to the pulse input 1 of the bistable multivibrator 12 and the output 20 to the pulse input 1 of the bistable multivibrator 15. The diode gate of the monostable multivibrator arrangement is open when the bistable multivibrator 12 is in position "1". The monostable multivibrator arrangement switches the bistable multivibrator 12 into the "0" state when it is tilted into the metastable state, while the bistable multivibrator 15 receives the pulse required for resetting when the monostable multivibrator array is tilted back into the idle state. In this case, the bistable flip-flop 15 is only reset if the bistable flip-flop 12 is in the “0” state at this point in time. For the circuit arrangement, monostable flip-flop arrangements with a large ratio of flip-over time to dead time should be used.

If the circuit arrangements according to FIG. 1 for relatively large ones respond at time intervals, so the monostable multivibrator arrangement can find several monostable flip-flops use. Each monostable controls Tilt stage when tilting back to the following, and the bistable Trigger stage 12 receives a positive pulse on input 1; if the last monostable The chain tilts back.

Partly there is a variation in the temporal pulse spacing of the input signals, on which the circuit arrangement responds, is required. lies can be realized by changing the tilt time of the astable or monostable trigger stage.

Claims (5)

Claims: 1. Circuit arrangement for controlling the time interval between electrical signals of two channels, in particular for controlling mechanical processes whose movements are converted into electrical signals, characterized in that the electrical signals to be controlled from two separate channels (9, 10) each to the parallel-connected linpulse inputs of a first (4, 1) and second (4, 3) bistable multivibrator (11, 12), the two control inputs (5, 6) of the second bistable multivibrator (12) each finite one of the two outputs (8, 7) the second bistable multivibrator (11), one output (8) of the second bistable multivibrator (12) with the control input (2) of a third bistable multivibrator (15), the other output (7) of the second bistable multivibrator (12) with the pulse input (4) of the third bistable flip-flop (15) and the output (14) of an astable or moon-stable flip-flop arrangement (13) with the pulse inputs (l.) of the second (12) and third en bistable flip-flop (15) are connected and an output (7) of the third bistable flip-flop (15) is finitely connected to your control input of a downstream circuit arrangement. 2. Circuit arrangement according to claim 1, characterized characterized in that when using a monostable multivibrator arrangement Pulse input with the output of a generator, the control input with an output (7, 8) of the second bistable flip-flop (12,) is connected. 3. Circuit arrangement according to claim 2, characterized in that the monostable multivibrator arrangement consists of several monostable multivibrators, the output of each monostable Flip-flop with the input of the following and the output of the first and last monostable multivibrator with the pulse inputs (1) of the second and third bistable Tilting stage (12, 15) is connected. 4. Circuit arrangement according to claim 1, characterized characterized in that the tilt times of the astable (13) or the monostable multivibrator arrangements are adjustable. 5. Circuit arrangement according to Artspruch 1 and 4, characterized in that the inputs (9, 10) are additionally connected to synchronization inputs of the astable multivibrator arrangements (13). Documents considered: German Auslegeschrift No. 1168 952.