DE1591881A1 - Circuit to indicate whether a pulse duration or frequency falls below or exceeds a certain value - Google Patents

Description

Circuit to indicate whether a pulse duration or frequency has a certain value exceeds or falls below.

The invention relates to a circuit for deciding whether a pulse duration to be tested, approximately the half-cycle duration of an alternating current quantity variable frequency or frequency to be measured, which is preferably given by an RC element The proper time of a time stage exceeds or falls below, with an "exceeding" through difference impulses that are present in a coincidence circuit are displayed, i.e. by pulses whose duration is the difference of the input pulse (duration un <1 proper time corresponds to. the first of these differential impulses could be used for this purpose, a relay or, for example, to convert a display device that is then self-contained in the new position holds until the self-holding circuit is interrupted by pressing a button will. In this way, however, there is only an automatic display when the input pulses exceed the critical duration (ice age of the time stage). According to the invention is therefore the resetting of the relay or the like. Not done by hand, but automatically, or alternatively by an impulse that occurs in another circuit when "falling below" occurs. Now the circuit or the relay or other device acts as a discriminator for exceeding or falling below the limit value given by the timer, where the latter. by changing the quantities that are decisive for the time constant, that is e.g. R and C, is variable.

If one uses one of those well-known 4rts as the time stage, in which the Return to the initial state if the input pulse duration exceeds the proper time regardless of this, always after the own time has expired, if the time falls below the own time Input pulse duration takes place simultaneously with the cessation of the input pulse, so in the latter case, i.e. if the value falls below ", the formation of differential pulses (for resetting the relay) of course not possible. In how the formation of the Invention, this problem is solved by the fact that the time stage with a Connection between output and input, i.e. provided with a feedback, the input (or one of the inputs forming an OR circuit) also at short input pulses always applied until the end of the proper time, so that a decrease in the time level at the end of the short pulse is avoided and thus now differential pulses can be produced even if the value falls below the limit (by means of a second Coincidence circuit) for resetting the relay or the like.

The fact that the time stage thanks to the feedback even with short Input pulses only decreases after the proper time has elapsed, but brings when the frequency of the input pulses exceeds twice the limit or, in general, if the next input pulse begins before the end of the proper time, the new difficulty with it that every two or more short input pulses a The (only) long input pulse is pretended to be that for re-enablement of the relay leads. It then arises not only in one but in both of them Formation of differential pulses in certain circuits (eoincidences zcircuits) Pulses and the relay is switched and reset in quick succession Avoiding the detriment to be feared for shorter impulses becomes the one responsible for it Feedback in a further embodiment of the invention immediately after the the first one that comes about through "falling below" and resets the relay Pulse release was canceled or interrupted, so that the short input pulses because of the decline that now takes place at the same time as its course the timer the relay or dg. are no longer able to move. The reclosing The feedback only occurs when it is long, i.e. when it exceeds the proper time of the timer Input pulses occur through which or through the first of which the relay or the like. is changed. Hence the (switched on) feedback for long input pulses is ineffective, its effectiveness is limited to "falling below" a Sufficient pulse to reset the relay to match.

The invention is explained in more detail at 4and of the drawing. Fig. 1 shows Circuit and symbol of a time stage known per se, as used in the invention for example can be used. Figs. 2 and 3 show the behavior of this Time stage with and without feedback. 4 and 5 show the interconnection the timing stage with an AND stage (B), an amplifier stage or

Storage level (C), which when "exceeded" by applying Differential pulses go into latching mode and then manually delete at L, and finally a device E to be fed from it (relay, display device, lamle or the like), as well as the functional diagram of this circuit. Figures 6 and 7 show an associated variant that also uses an inverse input signal which the AND level B is replaced by a NOR (neither-nor-) level B. The Fig. <¼ and Figures 9 and 10 and 11 respectively show the previous two similar but one fed back Circuit using time stage including function frames. Figs. 12 and 13 respectively. 14 and 15 show circuits according to the invention including a functional diagram in which within the meaning of the invention, the relay (E) or the like not only switched over when "exceeded", it is also automatically reset if the value falls below the limit, whereby the time step is fed back. Figures 16 and 17 are graphs showing the undesirable behavior of the circuits of Figures 12 and 14 at higher input frequencies. Furthermore, FIGS. 18, 19 and 20, 21 show circuits together with their functional diagrams which, in contrast to those according to FIGS. 12 and 14, even at high input frequencies (short, successive input pulses) work properly, and thanks to the fact that, according to the invention, the feedback of the timing stage is automatically interrupted after resetting. After all, they show 22, 23 and 24, 25 corresponding circuits together with a functional diagram in which no feedback is used, but the return of the timer to the initial state by a timer opposite the trailing edge of the input pulse by one to form effective differential pulse is delayed sufficiently.

The time stage shown in Fig. 1, functioning in a known manner with the proper time tRC, which is dependent on Rx and CX, has three diode inputs a1, a2, a3 in OR circuit and an output A and an output à inverse to it.

An incoming signal via one of the diodes makes the other opposite the emitter negative base of transistor T1 positive. So this becomes conductive and the lowering of its collector potential caused by the resistor R3 is transmitted via the capacitor C to the base of the connected via the resistor R7 Transistor T2, so that it blocks and at A a positive output signal as well at T, the transistor fed via the resistor 10 becomes conductive T3 zero signal appears. Under the influence of the resistor 1? 3 resulting Voltage begins the capacitor Cx across the resistor Rx to charge. As a result, the transistor T2 becomes conductive again after the proper time tRC has elapsed and a zero signal appears again at A and because the transistor is blocked T3 positive signal. The transition of the transistor T2 into the conductive state is steeper and more perfect (tipping process) through the use of an additional base current via the diode D and the resistor R5.

The diagram in FIG. 2 shows that an input pulse arriving approximately at a2 any duration that exceeds the proper time (tE # tRC) at A an output pulse of the duration tRC, but that when the input pulse duration falls below the proper time (tE # tRC) the output pulse ends with the input pulse. The signal W is closed A inverse. However, if one connects, as can be seen from Fig. 3, the output A of the Time stage with one of its inputs, e.g. with a1 (feedbackX so generate both longer ones, e.g. arriving at a2, as well as short ones, e.g. B. a3 applied input pulses at A output pulses of duration tRc and at A the associated inverse pulses.

The circuits of FIGS. 4 and 6 operate without feedback.

According to FIGS. 4 and 5, the AND stage B brings the amplifier or memory Sp and thus the device E for responding when the input signal tE is longer than tRC and therefore the signals tE and A carried to the AND stage overlap.

According to FIGS. 6 and 7, the signals fed by the signals tE and A can be used AND level B with equal success by one of the opposite signals, viz an inverse input signal and the signal A applied Nor stage B replaced that generates pulses when neither one nor the other of these two signals pending.

The circuits according to FIGS. 8 and 10 operate with Rtlokoupling (Connection between A and e.g. a3). This makes it possible instead of the two previous circuits displayed exceeding "the" undershooting "to display. Without feedback this would not be possible, because with "falling below", such as the right halves of Figures 5 and 7 show, with no feedback, overlaps or distancing the various types of impulses due to the "falling below" almost simultaneous cessation of the input and output signals of the timing stage can come about.

In the context of the invention, however, it is now also possible to use the circuits 4 and 8 as well as 6 and 10 to the circuits according to FIG. 12 and 14, respectively combine in such a way that the provision of the "exceeded" responsive Facilities Sp or E takes place automatically if the value falls below the limit, so a reset by hand is not necessary. The feedback provided according to FIGS.?) And 10 is namely with an input pulse duration tE # tRC ineffective, so that by the feedback the processes shown in the left halves of FIGS. 5 and 7 are not changed will. However, corresponding to the right halves of Figures 9 and 11, when the value falls below the limit, the processes that begin and the impulses generated in this way are added to reset the facility converted by the first-mentioned operations used, as can also be seen from the lower right parts of FIGS.

The circuits according to FIGS. 12 and 14 only work then flawless if the input pulses are less than twice that due to tRc have given cut-off frequency or more generally expressed when on an input pulse not before the time tRC has elapsed, calculated from the start of this Tpulse the next input pulse begins. What if this condition is not met in 12 and 14, is shown in FIGS. 16 and 17, respectively each shown for two different input pulse trains. The input pulses are effective then on the one hand as impulses falling below the time tRC, on the other hand, deceive but also two or more of each them long, i.e. the duration tRC overriding impulses.

There are then successively from the two pulse outputs for higher and deeper FreauensmImDulse that cause the amplifier or memory stage Sp together with the device E is switched on and off intermittently.

To remedy this evil and such a discriminator for you To create arbitrarily large input frequency range, one can according to the invention a of the circuits of FIGS. 13 and 20, which correspond to the circuits of FIG. 12 and 14 correspond, in which, however, the feedback, which is the cause for every (correct or undesired) response at tE # tRC is automatic switches off after "falling below" and only switches on again after exceeding. For this purpose, in the circuit according to FIG. 18, the feedback path A, a3 an AND stage B3 and in the circuit according to FIG. 20 in the feedback path A, a3 a Nor stage B3 inserted. These stages are still connected to output C (Fig. 18) or C (Fig. 20) of the amplifier or

Storage Sp connected. In both cases it is achieved that the feedback, namely the signal loading of the input (e.g. a3) of the Time stage depending on its output, only exists as long as the facility E is fed (A and C in Fig. 18 simultaneously give a positive signal; neither A 5 more in Fig. 20. give a positive signal when A gives a positive signal) i.e. that the feedback is interrupted when the device Sp or E is reset. The feedback is only used to generate short, resetting the devices Sp and E effecting pulses, the duration of which is denoted by tJ2 in FIGS. 19 and 21 and by the switching times of the timer (including B3 or B3), amplifier or storage stage Sp and Nor stage (B2 in Fig. 1> 3) or And stage (B2 in Fig. 20Y is determined.

In the supply examples described above, a Response also when "falling below" (tE # tRC) by a Feedback achieved that the immediate decrease in the output signal of the timer when stopping of the input pulse and thus allows the formation of differential pulses. However, it can also be done in other ways, e.g. using built-in delay elements or by choosing another (known per se) timer circuit, such as the shown in the Austrian patent specification 244 432, this immediate decrease of the time step prevented or avoided and thus enables the formation of differential pulses even if the value falls below the limit will. As-o it must be ensured that the time stage is not at the same time jumps back with the input signal, but a certain short time later, which is so large that it is sufficient, one pulse is more sufficient via a coincidence stage Duration for further processing e.g. ß. in a memory or relay. For example, for this purpose, as shown in FIGS. 22 and 24 is to connect an RC element in front of the input of the timer, which only works in one direction is effective as a delay, but in the other direction by bridging of the resistor with a diode Fig. 22) or by connecting a diode (Fig. 24) becomes ineffective as a time delay. The resistance of the RC element can be z, B. also consist of the resistors R1 and R2 of the timing stage shown in FIG.

The effect of the upstream RC element is shown in the diagrams 23 and 25 and is that the input signal at the inputs the time stage disappears after a delay.

This means for signals whose duration is greater than the proper time tRC is, no change in function. For input signals whose duration is shorter than Time is tRC, the time stage receives an input signal that is longer by the time tv simulated, so that difference pulses of this duration tv arise, which again to the Resetting the facility Spbzw. E serve. Otherwise the circuits correspond according to FIGS. 22 and 24 the circuits according to FIGS. o and 20, respectively.

At this point it should be mentioned that all the circuits shown can still be varied in that one other than those shown Coincidence circuits are used, e.g. an AND stage instead of a Nor stage or vice versa, if you apply the inverse input signals at the same time.

In the illustrated embodiments, a relay (E) or The like. when "exceeded" (tE tRc) switched on and when "undershot" (tE # tRC) switched off. Circuits with the opposite mode of operation could of course also be used be used.

The invention is not only for the detection of a pulse duration or frequency, such as a slip frequency, but of course also for speed and speed monitoring, E.g. also applicable to vehicles or also to regulations according to the two-point principle.

Claims (5)

PATENT CLAIMS 1. Circuit to decide whether to test a Impulse, about the half-cycle duration of an alternating current variable frequency to be measured, the proper time preferably given by an RC element Exceeds or falls below the time level, whereby an "overrun" by for example in one Coincidence circuit resulting difference impulses is displayed, doh. through impulses, the duration of which corresponds to the difference between the input pulse duration and the proper time, thereby ekennzeicinet that a relay or the like. By the occurrence of these differential pulses arrives in a certain position and automatically reset by a pulse. ar, which occurs in a marginal electric circuit when it is "undershot". .2. Circuit according to Claim 1, characterized in that a time stage known type; is used that if the input pulses are shorter than the proper time are, usually practically concurrent with the quitting of each Input pulse returns to the initial state, but that this time stage is provided with a connection between output and input (feedback), the causes the timer, even with short input pulses, only after the The proper time returns to the initial state, so that differential pulses even if the value falls below the limit can be produced, for example, in a second coincidence circuit that is used for resetting of the relay or the like. Lead if it was switched. 3. Circuit-according to claim 2, characterized in that the feedback, to avoid the pretending of a time that exceeds the proper time of the time stage Impulse by two or more short impulses, after the first one that falls below the proper time, to Rtickstteilung the relay or the like. Suitable pulse interrupted and only again with one that exceeds the proper time, changes the relay or the like Pulse is switched on. 9. A circuit according to claim 3, characterized in that in the feedback path a coincidence circuit (And or Nor stage) is inserted, which is to be reset by the Device (Sp or E) is controlled. 5. Circuit nsch claim 1, characterized in that the at "Undershooting" the pulse to be formed comes about by the fact that the timer is over an intermediate element, e.g. an RC element, simulates a somewhat longer input pulse will. L e r s e i t e