DE1298143B - Monitoring device for periodically repeating electrical processes, in particular for pilot scanning devices in communication systems - Google Patents

Description

The invention relates to a monitoring device for periodically repetitive electrical processes, in particular for monitoring a device for the cyclical scanning of pilots in communication systems.

In the case of high-quality carrier frequency systems, the operating properties must be monitored of the system as well as a corresponding automatic control with the help of pilots indispensable. However, a good regulation presupposes that the dispatched pilot has a keeps the level as constant as possible, d. that is, it must turn to its accuracy are constantly checked with the help of their own pilot monitoring.

Each pilot can now have their own pilot monitoring on the transmitter side, d. H. thus its own pilot receiver, in which the corresponding pilot evaluates will assign. The effort is then particularly in large offices with a large number of pilots very high. Therefore, more and more, for a whole series, Provide a common pilot receiver and pilots with the same frequency to carry out a cyclical scan of the individual pilots to be checked. the cyclic scanning of the pilots can be done with the help of a shift register.

However, it is important for the operator to know whether a proper monitoring of the individual pilots takes place or whether possibly by an error, e.g. B. in the shift register, the monitoring is suppressed. For this Basically it is necessary to use the respective scanning device, in special cases For example, the shift register to also monitor its functionality. You can design the shift register so that it is at the end of each cycle emits an impulse. A corresponding monitoring circuit should then be set up in the event of a failure emit a corresponding alarm signal after a pulse.

However, there are many register units and the same for a long period of time a cycle period can last several minutes, monitoring circuits are required, which have a correspondingly long delay time for alarming, the longer the longer than is the time required for one cycle revolution.

Long delay times are generally the safest way to get through Capacitor charges can be realized via a high resistance. capacitor and resistance are usually components of an amplifier or flip-flop circuit, which constantly checks and evaluates the voltage on the capacitor. The achievable with it But times find an upper limit, especially in transistor circuits, because that the discharge current for safe control of the first transistor stage is not arbitrary small may be chosen. On the other hand, there must also be a guarantee that that the delay time is within a certain tolerance limit, d. H., that it is always guaranteed with certainty that the delay time is greater than is the time of the circulation cycle.

The object of the invention is therefore to provide a monitoring device for to create periodically repeating electrical processes in which the length of time for responding to the alarm if a periodic process fails with Safety is longer than the scanning device's cycle period.

The monitoring device is to solve this problem according to the Invention forms out in such a way that the input of a monostable multivibrator circuit is connected via a switch to a memory element whose memory state A functional criterion represents that its output is a delay element and an ohmic resistor's existing voltage divider is connected after and that parallel to this ohmic resistance an astable multivibrator, esp a blocking oscillator, whose output is connected to the switch as well as to a Relay is connected.

An electronic switch, preferably a silicon switch transistor. A condenser can be used as a storage element. Serve sator, and a thermistor can advantageously be used as a delay element. However, other delay elements, e.g. B. PTC thermistors and the like. For this Purpose to be used well.

These measures make it possible to achieve delay times that are orders of magnitude longer than the delay times that can be achieved with known arrangements and practically only through the self-discharge of the capacitor and the reverse current of the switching transistor are limited.

Another advantage is that the capacitor briefly a high, pulsed current can be withdrawn without affecting the charge of the Capacitor itself is changed significantly.

In a further embodiment of the invention, the monitoring circuit expediently train in such a way that the capacitor serving as a storage element, the A positive pulse-shaped voltage to be monitored is supplied via a diode, lies in the collector circuit of the silicon switching transistor.

As already stated above, the achievable length is the delay time essentially limited by leakage currents that occur. Such a leakage current is also the residual current flowing in the blocking state of the diode, as well as the residual current causes a discharge of the capacitor in the transistor.

To turn off the given by the residual current of the blocked diode The monitoring circuit arrangement can advantageously discharge the capacitor train in such a way that there is a diode in the base circuit of the silicon switching transistor and that in series with the collector-emitter path of the switching transistor as a storage element Serving capacitor is arranged, the one to be monitored negative periodic pulsed voltage is supplied.

Since in this embodiment the collector-base path of the switching transistor and the diode are in series with each other, the residual current flowing in the diode plays no longer matter.

To implement the respective, periodically repeating positive Voltage pulse into a negative voltage pulse can be used as a storage element Serving capacitor upstream amplifier stage advantageously use the has a series circuit on the output side, consisting of a capacitor with much larger capacity than the capacity of the storage element Capacitor and an ohmic resistor, and one pole of which acts as a storage element serving capacitor via a further ohmic resistor to the connection point of capacitor and ohmic resistance of the am Amplifier output lying series circuit is connected.

On the basis of the exemplary embodiments according to FIGS. 1 and 3 to 6 as well of the diagrams according to FIG. 2 the invention is explained in more detail.

In Fig. 1 shows a block diagram for a better overview. A positive voltage pulse, which is emitted by a shift register after the end of each circulation cycle and charges the capacitor C, is fed via the diode D to the capacitor C used as a storage element. The capacitor C is gradually discharged through the ohmic resistor R until the next pulse. The capacitor C is connected via the switch T and the series resistor Rv to a monostable multivibrator K, which is terminated on the output side with a voltage divider consisting of the thermistor H and the ohmic resistor Rq. The blocking oscillator S, from whose output a connection to the switch T is established, is located parallel to the resistor Rq. In addition, the relay A is connected downstream of the blocking oscillator.

The mode of operation of this circuit arrangement is as follows: The monostable multivibrator K is controlled by the current i. If the current ! Exceeds the threshold value 1o, even for a very short time Ti (g), the flip-flop is put into the astable state, which lasts for the time TA (e.g. 10 sec), with the output voltage UmK der Flip-flop is zero. The circuit then flips back into the stable state in which the output voltage UmK has the full value.

The blocking oscillator S is put into operation by the voltage Us as soon as it has exceeded the threshold value Uso. It periodically emits very narrow pulses Ui with the width Ti (#ts) at the output. As the voltage Us increases, the pulse sequence becomes faster and faster, until finally, when U9 = Usa is high, the pulse pauses disappear and Ui changes to a direct voltage, which causes the alarm relay A to respond. With Us = Usa the blocking oscillator is "blocked".

Using the timing diagrams according to FIG. 2 we will go into a little more detail about the functionality. A pulse of the pulse train to be monitored of the period TR with the voltage U (Fig. 2a) charges the capacitor C via the diode D. The capacitor is constantly discharged through the high resistance R, as the course of the voltage Uc (FIG. 2b) shows. Switch T is closed. The capacitor voltage drives a current i> i via resistor Rv into the monostable multivibrator K and puts it into the astable state with the output voltage UmK = 0 (FIGS. 2c and 2d). This means that the voltage Us at the input of the blocking oscillator is also zero (FIG. 2e), the blocking oscillator is out of operation, the pulse voltage Ui = 0 (FIG. 2f) and the switch T is opened again.

This state remains until after the time TA the flip-flop switches back to the stable state by itself, whereby UMK jumps to the full value. A little later, the control voltage U, s, delayed by the voltage divider with the thermistor H and the resistor Rq by the time TH , has reached the threshold value Uso, which causes the blocking oscillator to emit the key pulse Ui. This closes the switch T; A current i flows which, if it is greater than i, puts the flip-flop back into the astable state, so that the voltages UMK and Us disappear again and the blocking oscillator is put out of operation. This is followed by the period with TA again. During the delay time Ta (approx. 100 ms) caused by the thermistor, the capacitor responsible for the TA time must be fully charged again in the flip-flop circuit.

The process described so far is repeated continuously as long as the capacitor C with its voltage Uc is able to deliver a current pulse i> i when T is closed.

At the end of the period TA -I- TH there is always only one key pulse Ui, which closes the switch T and thus simultaneously causes the current pulse i, because with i the blocking oscillator is also canceled at the same time via the flip-flop. When dimensioning the blocking oscillator, it is important that a started key pulse Ui can still develop fully, even if the control voltage Us disappears immediately after the creation of the key pulse, thus putting the blocking oscillator out of operation. Otherwise, the chain connection of switch T, flip-flop K and blocking oscillator S represents an amplifier circuit with extremely negative feedback via the key pulse line, and the digital character of the entire arrangement is lost.

If the capacitor C is no longer recharged by U-pulses (see Sect. F i g. 2 at the end of the time axes), its voltage Uc after time Tv (approx two time constants C - R) dropped so far that the pulse current i <1o does not is more able to put the flip-flop K in the astable state. It finally remains in a stable state, the UM% voltage remains permanently present, the voltage Us rises to higher values according to the thermistor heating time, and the blocking oscillator emits probe pulses Ui in ever faster succession, which the Discharge capacitor C quickly and completely. If Us has reached the value Usa, it is Blocking oscillator "clogged", the probe pulses Ui have changed to a direct voltage, which causes the alarm relay A to respond (Fig. 2g). So it is alarmed if, after the time Tv has elapsed, the U-pulse, which is due in itself, has not occurred.

F i g. 3 shows a detailed current flow, the switch T being replaced by a high blocking silicon switching transistor is realized. The collector-emitter path this transistor serves as a switching path, controlled by the base, which the Ui pulses of the blocking oscillator S are fed.

As shown in FIGS. 1 and 3, the upper layer of the condenser is visible C is recharged by a positive voltage pulse U. The unsafe residual current the diode D also discharges the capacitor C. This disadvantage can be avoided Avoid if you remove the lower coating of the capacitor, which was previously on the Ua line C charges with a correspondingly negative voltage pulse - U.

A circuit of this type is shown in FIG. 4 shown; the diode Dl lies in the base circuit of the transistor T, i. H. so, it is in series with from the charging current! L through which the collector-base path of the switching transistor flows, while the diode D according to FIG. 3 and the transistor T according to FIG. 3 both parallel to Capacitor Co lie. In this circuit arrangement, the additional one is omitted Discharge possibility over the diode, reducing the delay time can be increased even further with this arrangement.

With which circuit the after the circuit according to F i g. 4 required negative pulse - U can be derived from the positive with simultaneous current amplification by a transistor, shows the arrangement according to FIG. 5. Assuming that the capacitor CL is fully charged (transistor T, blocked during pulse pauses), then at the junction of the capacitor and the ohmic resistor R1 is the potential - UB, which is normally zero. If a positive pulse is now applied to the base of the transistor T, the amplifier stage and this makes it conductive, this pulse during the pulse duration causes the coating of the capacitor CL on the UB to be pushed down to a negative potential equal to the battery voltage. The coating of the storage capacitor C connected to this resistor is brought to the same potential via the resistor R2, while the coating connected to the collector of the transistor T does not fall significantly below the potential - UB because of the diode Dl in the base circuit of the transistor T. When the input pulse + U disappears, the potential on the plate of the capacitor CL connected to the negative pole rises again to the original value - UB, normally to zero potential. The storage capacitor C also participates in the same increase in potential, so that as a result the coating of the capacitor C facing the collector of the transistor T again assumes a positive potential.

If one uses circuit arrangements according to FIGS. 4 or 5, so only remain as causes for an irregular discharge of the capacitor C nor the residual current of the switching transistor T and the leakage current; of the capacitor themselves. Both cause an uncertainty in the achievable delay time Tv, which is the greater, the more these two currents compared to the regular discharge current matter. The latter also includes the key pulse current i, its time integral if dimensioned appropriately, it is orders of magnitude smaller than that of the regular discharge current via the resistor R. (pulse-pause ratio 5z # - 10-1).

The mean value of the pulse current over time is in many cases be even smaller than the leakage and residual currents. Capacitor C and resistor R predominantly determine the delay time Tv alone.

The actual charge test process is practically so powerless that as it cannot be better achieved even with high-impedance special tubes.

F i g. 6 shows a circuit arrangement which is practically in use. Via the amplifier stage with the transistor T, the capacitor CL is charged with negative pulses via the resistor R1. The capacitor C receives its charge as described above, the switching transistor T samples this charge and forwards the information to the monostable multivibrator K, which in turn forwards the information to the blocking oscillator S via the thermistor H and the resistor Rq. The blocking oscillator stage itself then acts in turn on the alarm relay A and the switching transistor T , in whose base circuit the diode Dl is arranged.

Claims (7)

Claims: 1. Monitoring device for periodically repeating electrical processes, in particular for monitoring a device for the cyclical scanning of pilots in communication systems, characterized in that the input of a monostable multivibrator (K) via a switch (T) with a memory element (C) is connected, the memory state of which represents a functional criterion that its output is followed by a voltage divider consisting of a delay element (H) and an ohmic resistor (Rq) and that an astable multivibrator, in particular a blocking oscillator (S), is parallel to this ohmic resistor (Rq) whose output is connected to both the switch (T) and a relay (A) (Figs. 1, 3 and 6). 2. Monitoring device according to Claim 1, characterized in that the switch is an electronic switch (T), preferably a silicon switching transistor (FIGS. 3 to 6). 3. Monitoring device according to one of claims 1 and 2, characterized in that the storage element is a capacitor (C) (Figs. 1 and 3 to 6). 4. Monitoring device according to one of the preceding claims, characterized in that the delay element (H) is an NTC thermistor (Figs. 1, 3 and 6). 5. Monitoring device according to the Claims 2 and 3, characterized in that serving as a storage element Capacitor (C) to which, via a diode (D), a positive pulse-shaped signal to be monitored Voltage is supplied, lies in the collector circuit of the silicon switching transistor (T) (Fig. 3). 6. Monitoring device according to claims 2 and 3, characterized in that that in the base circuit of the silicon switching transistor (T) there is a diode (Dl) and that in series with the collector-emitter path of the switching transistor as a storage element Serving capacitor (C) is arranged, to which a negative periodic to be monitored pulsed voltage is supplied (F i g. 4 to 6). 7. Monitoring device according to claim 6, characterized in that the negative pulse-shaped voltage is generated from a positive by means of a capacitor (C) serving as a storage element upstream amplifier stage (T,), the output side is a series circuit of a capacitor (CL) with a much larger Capacitance as the capacitance of the capacitor serving as the storage element (C) and an ohmic resistor (R1), and that one pole of the capacitor (C) serving as the storage element has a further ohmic resistor (R2) with the connection point of the capacitor (CL) and the ohmic resistor (R1) of the series circuit located at the amplifier output is connected (FIG. 5).