DE3049286A1 - Contactless checking of pulse signals for breakdown detection - utilises inductive sensor with integration and rectifier circuits driving bistable with LED output indicator - Google Patents

Abstract

Signal pulses are applied to an inductive sensor (1) which provides an input signal to an ac amplifier (2). An integrator circuit (5) slows the leading edges of the pulses while a differentiator circuit (6), comprising an amplifier (9) and a transformer (10), produces a train of pulses of short duration at the same frequency as the output of the inductive sensor. A full wave rectifier (3) produces a series of unidirectional pulses which are amplified in an ac amplifier (14). The amplifier output passes via a capacitor (17) to a bistable (15). If the bistable input exceeds a threshold value the output changes state to illuminate an LED (18). The LED (18) is extinguished and the bistable reset by a reset signal at its second input (19).

Description

description

The invention relates to devices for the contactless control of electrical Pulse signals.

The present invention can be used for fault monitoring of electronic logic circuits are used.

The invention can be particularly advantageous for the detection of faults in electronic logic produced by the process of printed circuit boards Circuits are used.

Arises during the monitoring of electronic logic circuits the need for current or voltage pulses in the circuits without manufacture to control a galvanic contact with the circuit elements. These Necessity arises, for example, when the circuit is provided with a protective coating which must not be disturbed, as well as, if necessary, current pulses in the circuits of the circuit to be monitored without interrupting the specified Control circles. In such cases, contactless measuring devices are used Sensor elements are used which are sensitive to current and voltage changes in the Circles of the circuit to be monitored, changes in the electromagnetic Talk to Felds. The sensing element forms the specified changes in the electromagnet 's Belds into an electrical signal, the value of which depends on the amplitude of the electrical Impulse depends on the point of the circuit, near which the sensing element is located will. This electrical signal is fed to the input of the display part, the in a certain way on the Value of the input signal responds, thereby monitoring the electrical impulses in the circuits of the electronic Circuits without making galvanic contact with the circuit elements is made possible. A device with a Sensor element used, which is designed in the form of a capacitive converter, responsive to the electrical component of the electromagnetic field; to the Measurement of current pulses, measuring devices with a sensor element are used, which is designed in the form of an inductive converter and on the magnetic component of the electromagnetic field.

It is a device for the contactless control of electrical impulse signals known that a time-dependent change of the to be controlled by the electrical signal generated electromagnetic field responsive sensor element, one amplifier connected to the output of the sensing element and one to the output of the amplifier connected rectifier and a display part whose input is connected to the output of the rectifier, contains (s.

e.g. "Hewlett-Packard Journal", Vol. 28, No. 4, December 1976, p. 5, Fig. 5).

Do the electrical impulses in the circuit to be monitored have a relatively low frequency at which the pulse period of the pulses is the time constant of the sensor element significantly exceeds the amplitude of the signal at the output of the latter on the frequency and on the switching ratio of the pulses in does not depend on the circuit to be monitored and, if the edge steepness is sufficient of the specified impulses determined by their amplitude. If, however the pulses to be controlled have a relatively high frequency whose pulse period can be compared or compared to the time constant of the sensor element. is less than the specified time constant, the amplitude of the signal depends on The output of the sensor element depends on the frequency and the switching ratio of the one to be checked Impulses. This is due to the fact that the sensor element is not on the absolute Value of the field strength of the electromagnetic field, but rather on the changes in the indicated Fedlstarkks responds, so that the DC component of the signal in the monitored circuit does not affect the output signal of the sensor element exercises. Accordingly, in the case of a relatively high one, the device receives Frequency of the impulses in the circle to be monitored impulses, the tine same amplitude, but a different frequency and a different switching ratio, record as pulses with different amplitudes. This problem cannot get through Reducing the time constant of the sensing element can be solved because such Reduction leads to a decrease in its sensitivity. The well-known facility so cannot precisely control the electrical pulse signals in a wide range Ensure the range of change their frequency.

The invention is based on the object of a device for contactless To create control of electrical pulse signals, which is carried out so that without Reduction of the time constant of the sensor element an increase of the maximum Guaranteed frequency value of the signals to be controlled will, at which their frequency and their switching ratio have no influence on the results the control exercise to thereby the predetermined accuracy of the control in one to ensure a wide range of changes in the frequency of the signals to be controlled.

This object is achieved in that the device for contactless Control of electrical impulse signals that respond to the time-dependent change in the electromagnetic field generated by the electrical signal to be controlled responsive sensor element, one connected to the output of the sensor element Amplifier, a rectifier and a display part, the input of which connects to the output of the rectifier is connected, according to the invention additionally contains an inertia Member and containing a differentiating member connected in series with one another and switched between the output of the amplifier and the input of the rectifier are.

With a sufficiently low time constant of the differentiating Member allows the device according to the invention, the maximum frequency value of the pulse signals to be checked without reducing the time constant of the sensor element to enlarge, at which their frequency and their switching ratio do not affect exercise the results of the control, and thereby the specified accuracy of the Control over a wide range of changes in the frequencies of those to be controlled To ensure signals. The one connected in series with the differentiating term Inertia-affected link ensures compensation for the influence of the Edge duration the impulses to be controlled on the results of the control carried out by the low time constant of the differentiating element is caused.

To eliminate the errors that occur when using DC amplifiers arise as a result of the drift of the zero point, a display part should preferably be used responsive to the AC component of the input signal. In this case Expediently, two rectifiers are used in the device according to the invention used whose inputs with the output of the amplifier beyond the specified inertia Element and the specified differentiating element for generation at the output of a rectifier from Sigdie the signals of one polarity at the output of the inertia Member and the circle having the differentiating member are proportional, and for generating signals at the output of the other rectifier, which the signal transmitter different polarity at the output of the inertial member and the differentiating Member inclusive circle are proportional, related. The display part has two inputs, each connected to the outputs of the rectifier are, and is designed so that it is based on the alternating components of the signals to the outputs the rectifier responds.

If there is a display part that points to the interchangeable components which responds to input signals ensures the use of two separate rectifiers a higher maximum frequency value of the pulse signals to be controlled whose frequency and switching ratio have no influence on the results of the control exercises, and thereby a broader one Frequency range in which the specified accuracy of the control is guaranteed.

The invention is explained in more detail, for example, with the aid of the drawing. 1 shows the electrical circuit diagram of the device for contactless control electrical pulse signals in accordance with an embodiment of the invention; Fig. 2 shows the electrical circuit diagram of the device for contactless control of electrical Pulse signals in accordance with another embodiment of the invention; Figures 3 (a-g), 4 (a-g) and 5 (a-j) are timing charts showing the changes in the various Signals having frequencies to be controlled and the corresponding changes of the signals at various points in the circuits shown in FIGS demonstrate.

According to Fig. 1 contains the device for contactless Control electrical impulse signals in the form of a change in strength the magnetic component of the electromagnetic field responsive inductive Converter 1 executed sensor element, an alternating current amplifier 2, its input is connected to the output of the converter 1, a rectifier 3 and a display part 4, the input of which is connected to the output of the rectifier 3. The establishment also contains an inertial member 5 and a differentiating member 6 connected in series with each other and between the output of the amplifier 2 and the input of the rectifier 3 are switched on.

The inertial link 5 represents the C me integrating Rc chain represents a resistor 7 and a capacitor 8 contains. That differentiating element 6 contains an AC amplifier 9, the input of which is connected in parallel with the capacitor 8, and a differentiating transformer 10, which has a primary winding connected to the output of the amplifier 9 is, and has a secondary winding, the center tap with the common Point of the device circuit is in connection.

The rectifier 3 represents a two-pulse rectifier, the two Contains diodes 11 and 12, the anodes of which serve as inputs of the rectifier 3 and with the opposite derivatives of the secondary winding of the transformer 10 of the differentiating member 6 are connected. The interconnected cathodes the diodes 11 and 12 form the output of the rectifier 3 and stand via the resistor 13 with the common point of the device circuit in connection.

The display part 4 includes an AC amplifier 14, whose Input works as the input of the display part 4 and with the output of the rectifier 3 is connected, a trigger 15, one input 16 of which via a capacitor 17 is connected to the output of the amplifier 14, and a signaling Element that is connected to the output of the trigger 15 and in the form of a light emitting diode 18 is executed.

The trigger 15 has a second input 19, which is used to transmit Pulses is determined that ensure the cancellation of the trigger 15.

According to FIG. 2, the rectifier 3 is in the form of a half-wave rectifier running the facility another half-wave rectifier 20 contains. The rectifier 3 contains a diode 21, the anode of which is that of the rectifier 3 forms and with one of the derivatives of the secondary winding of the transformer 10 is connected, while the cathode forms the output of the rectifier 3 and through a resistor 22 to the common point of the device circuit communicates. The rectifier 20 includes a biode 23, the anode of which the The input of the rectifier 20 forms and with the other derivative of the secondary winding of the transformer 10 is connected, while the cathode is the output derivative of the Rectifier 20 forms and via a resistor 24 to the common point the device circuit is in communication. The display part 4 contains except the amplifier 14, the trigger 15 and the light-emitting diode 18 still have an AC amplifier 25, the input of which forms the second input of the display part 4, another trigger 26, the input 27 of which via the capacitor 28 to the output of the amplifier 25 is switched, and another signaling element that is connected to the output of the trigger 26 is connected and designed in the form of a light emitting diode 29. The trigger 26 has a second input 30 intended for the transmission of pulses representing the solution of the rriggers ensure, and that with the input 19 of the trigger 15 in connection stands. The inputs of the display part 4 are connected to the outputs of the rectifier 3 or 20 switched.

The effect of the circuits shown in FIGS. 1 and 2 is explained with the aid of FIGS. 3 (a-g), 4 (a-g) and 5 (a-j), the Diagrams of the monitored pulse signals having different frequencies and the corresponding changes in the signals at different points in the circuit demonstrate.

During the inspection, the device is arranged so that the Converter 1 (Fig. 1) is located near that point of the electronic circuit where the electrical signal is controlled. The one arising at this point electrical impulse evokes the occurrence of a corresponding signal at the output of the Converter 1.

In Fig. 3a is the change in the pulse signal under control shown with a relatively low frequency, at which the cycle duration of the pulses the time constant of the converter 1 (Fig. 1) significantly exceeds. In this case a sequence of alternating pulses is formed at the output of the converter 1, which has a shape shown in Fig. 3b. The amplitude of each of these pulses is the The amplitude of the pulses to be controlled is proportional and does not depend on them Frequency and its pulse-pause ratio.

The pulses formed at the output of the converter 1 (Fig. 1) are amplified in the amplifier 2 and reach the RC chain 7, 8 of the inertia Element 5, after the passage of which the edge duration of the impulses increases, as shown in Fig. 3c, the signal change at the output of the inertia Link 5 (Fig. 1) represents. Those formed at the exit of the member 5 subject to inertia Be impulses amplified by the amplifier 9 and arrive at the transformer 10, the parameters of which are chosen so that there is a differentiation the pulses arriving from the output of the amplifier 9 with a time constant guaranteed, which is significantly less than the time constant of the converter 1.

As a result, at the output of the differentiating element 6, i.e. between the derivatives of the secondary winding of the transformer 10, a series of short alternating ones Pulses are formed that have the same frequency as the pulses at the output of the converter 1 (Fig. 1), but have a significantly shorter duration than that in Fig. 3d is shown. The time constant of the inertia element 5 is chosen so that it exceeds the maximum possible edge duration of the pulses to be controlled, whereby the edge duration of the pulses at the output of the inertia element 5 practically does not depend on the edge duration of the pulses under control. Therefore, a change in the edge duration of the pulses to be controlled exercises, in spite of the small time constant of the differentiating element 6, practically no influence on the amplitude of the pulses at the output of the differentiating element U from the thus will be proportional to the amplitude of the pulses under control.

The alternating formed at the output of the differentiating element 6 Pulses pass from the secondary winding of the transformer 10 to the diodes 11 and 12 of the two-pulse rectifier 3, whereby the output of the rectifier 3 forms a sequence of homopolar pulses as shown in FIG. 3e. These pulses are amplified by the alternating current amplifier 14 (FIG. 1) and arrive on the Capacitor 17 to the input 16 of the trigger 15. At a sufficient width of the pass band of the amplifier 14 and a large one The capacitance of the capacitor 17 is proportional to the signal at the input 16 of the trigger 15 the signal at the output of rectifier 3, i.e. it will have a form that is in 3e is shown.

Exceeds the amplitude of the pulses at input 16 of the trigger 15 (Fig. 1) the response threshold of the trigger 15, the state of the changes Triggers 15, causing the light-emitting diode 18 to ignite. Since the amplitude the pulses at the output of the rectifier 3 analogous to the signal at the output of the differentiating Element 6 on the frequency and (pulse-pause ratio the switching ratio of the does not depend on the impulses to be controlled, the amplitude of the impulses also depends at the output 16 of the trigger 15, the same applies to the frequency and the switching ratio the impulses under control do not depend and are only determined by their amplitude and determines the transmission factor of the elements of the device circuit. Lurch a regulation of the gain factor of the amplifier 2, 9 or 14 can be a minimum, the response of the trigger 15 and the ignition of the light emitting diode 18 provoking Amplitude value of the pulses to be controlled can be set, whereby a Assessment of the amplitude of the impulses to be controlled and thus the lack of interference the corresponding circuits of the electronic circuit to be monitored will. To ensure better convenience in using the facility can instead of the trigger 15 several threshold circuits with different Response thresholds and instead of the light emitting diode 18 a digital indicator that shows the amplitude value which shows the pulses to be controlled in numerical form.

The resetting of the trigger 15 to the initial state and the deletion the light-emitting diode 18 takes place by transmitting a pulse to the input 19 of trigger 15.

The transmission of the reset or delete pulses can be done manually or take place automatically with the help of a special generator (not shown), which generates the extinguishing pulses at set time intervals.

When the circuit shown in FIG. 2 is used the change in voltage between the derivatives of the secondary winding of the transformer 10 of the differentiating member 6 in the same way as in that shown in FIG Circuit, i.e. in accordance with Fig.3d.

At the outputs of half-wave rectifiers 3 and 20 (Fig. 2) in the process, sequences of homopolar impulses are formed which are shifted from one another by 1800 and have a frequency that is half the frequency of the output of the in the rectifier shown in Fig. 1 is formed pulses. The changes of the signals at the inputs of the rectifiers 3 (Fig. 2) and 20 are shown in Figs. 3f and 3g, respectively. In this case, signals are sent to input 16 of trigger 15 which change according to FIG. 3f, and to the input 27 of the trigger 26 get signals, the change of which proceeds according to FIG. 3g. The amplitude of the signals at the inputs 16 and 27 of the triggers 15 (Fig. 2) and 26 depends same if of the frequency and the switching ratio of the to controlling impulses. Exceeds the amplitude of the controlled If the pulse exceeds the set threshold, it speaks depending on the direction of change of the pulse signal to be controlled the trigger 15 or 26 and it is the LED 18 or 29 lit. The resetting of triggers 15 and 26 in the The initial state occurs when a clear pulse is sent to its inputs 19 and 30 as described above.

The use of the AC amplifiers 14 and 25 in the 1 and 2 shown in the circuit instead of the DC amplifier it, the drift of the zero point at the outputs of these amplifiers as well as the resulting caused changes in the signals at the inputs 16 and 27 of the trigger 15 and to exclude 26, thereby increasing the accuracy of the control.

If the pulses to be controlled have a frequency at which their pulse period with the time constant of the Urn! '<iiiii' :; J (Fig. 1) comparable or less than this, but the time constant of the differentiating term 6 substantially exceeds, the device operates as follows.

The pulse signal to be controlled, the change of which is shown in Fig. 4a, the formation of an alternate pulse signal causes the output of the converter 1 (Fig.1) shows that due to the relatively large time constant of the converter 1 has a shape that is shown in Figure 4b. The amplitude of the Pulses at the output of the converter 1 (Fig. 1) is not only through in this case the amplitude of the pulses to be controlled, but also by the time constant of the converter determined and depends on the frequency and the switching ratio of the pulses under control, so that the amplitude of the pulses at the output of the converter 1 with the increase in the frequency of the pulses to be controlled drops while the switching ratio of the pulses to be controlled changes to an increase in the amplitude of the pulses with the one sign and to leads to a reduction in the amplitude of the pulses with the opposite sign. the Amplitude of the formed at the output of the inertial member 5 and in the The pulses shown in Fig. 4c are similar in frequency and duty cycle the impulses to be controlled. But because of the low value of the time constant of the differentiating element 6 (Fig. 1) becomes the amplitude of the voltage pulses on the secondary winding of the transformer 10 in this case determined by the value, around which the pulse signal at the output of the converter 1 changes when the to controlling signals changes and that of the frequency and the switching ratio does not depend on the impulses under control. So the amplitude depends on the Pulses at the output of the differentiating element 6 in this case also from does not depend on the frequency and the switching ratio of the pulses to be controlled, and the change in the signal at the output of the differentiating element 6 occurs analogous to its change in the case of a low frequency of the one under control Impulses in accordance with how that was described above and how that is shown in Fig. 4d.

The amplitudes of the pulses at input 16 of trigger 15 in the 1 and at the inputs 16 and 27 of the trigger 15 and 26 in the circuit shown in Fig. 2 are similarly dependent on frequency and the switching ratio of the pulses to be controlled does not decrease, whereby a good accuracy of control is guaranteed.

The changes in the signals at input 16 of trigger 15 in FIG. 1 and at inputs 16 and 27 of triggers 15 and 26 in FIG the circuit shown in Fig. 2 are analogous to their changes in the case of a low frequency of the signal to be controlled and are shown in FIGS. 4f and 4g.

If the impulses to be controlled have an even higher frequency, in which their cycle duration not only exceeds the time constant of converter 1 (Fig. 1), but is also comparable with the time constant of the differentiating element 6, the change of the signals at the outputs of the converter 1 and the inertia occurs Link 5 analogous to its change in the previous case, like the one above with the notes on Figs. 4b and 4c. The changes to the controlled Pulse signal, the signal at the output of the converter 1 (Fig. 1) and the signal at Output of the inertia element 5 in the case of one with the time constant of differentiating member 6 comparable cycle duration of the pulses to be controlled are shown in FIGS. 5a and 5b and 5c, respectively. However, because the time intervals during which the voltages at the outputs of the differentiating element 6 and of the rectifier 3 in the circuit shown in Figure 1 are equal to zero, in in this case are small or absent at all, as in the Fig.5d or 5e, arrive at the input 16 of the trigger 15 (FIG. 1) from the output of the AC amplifier 14 alternating pulses whose amplitudes depend on the Frequency and the switching ratio depend heavily, as shown in Fig. 5f is. The response of the trigger 15 and the light-emitting diode 18 shown in FIG. 1 The circuit depends to the same degree on the frequency and aem switching ratio from, consequently the guaranteed by the circuit shown in FIG Control accuracy is very low.

At the same frequency as the pulse signals to be controlled the signals at the outputs of the sinusoidal rectifiers 3 and 20 in the in Fig. 2 represent a sequence of homopolar pulses that are subdivided by certain time intervals, the duration of which is the duration of the impulses itself cannot fall below, as shown in FIGS. 5g and 5h. As a result depends on the amplitude of the pulses at inputs 16 and 27 of triggers 15 and 26 in the circuit shown in FIG. 2, relatively little of the frequency and on the switching ratio of the pulses to be controlled, as shown in FIGS. 5i and 5j can be seen in which the changes in the signals at the inputs 16 and 27 of the triggers 15 and 26 are shown. The circuit shown in FIG so in this case ensures an accuracy of control that is essential exceeds the accuracy achieved by the circuit shown in FIG is guaranteed.

It glows; one that instead of the integral RC chain also others Circuits of the passive or active type are used can be which have a transfer function of the inertial member e.g. a aperiodic amplifier.

Instead of the differentiating transformer 10, other circuits are used which have a transfer function of the differentiating term, e.g. a differentiating RC chain or a differentiating amplifier. Instead of of the inductive converter 1, a capacitive converter can be used, which is based on the electrical component of the electromagnetic field responds. Instead of the trigger 15 and 26 other devices can also be used which provide an output signal that is proportional to the amplitude of the input pulses, e.g. a double peak detector. The rectifiers 3 and 20 in the circuit shown in FIG. 2 can so be designed so that the pulses at their outputs have an opposite polarity will have. In this case one of the amplifiers 14 or 25 can guarantee the same polarity of the pulses at the inputs 16 and 27 of the triggers 15 and 26 have an additional inventory level.

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Claims (1)

DEVICE FOR CONTACTLESS CONTROL OF ELECTRIC PULSE SIGNALS PATENT CLAIMS: Device for contactless control of electrical impulse signals with one on the time-dependent change of the electrical to be controlled Signal generated electromagnetic field responsive sensor element, a the output of the Fühlerelemets switched amplifier, a rectifier and a Display part, the input of which is connected to the output of the rectifier, thereby characterized in that it also has an inertia element (5) and a differentiating element Member (6) which are connected in series with each other and between the output of the amplifier (2) and the input of the rectifier (3) are switched on. 2, device according to claim 1, characterized in that they have two Contains rectifiers (3, 20) whose inputs are connected to the output of the amplifier (2) about the träghertsbehaftete Link (5) and that in series with it switched differentiating element (6) for generation at the output of one rectifier (3) of signals corresponding to the signals of one polarity at the output of the inertial Term (5) and the circle containing the differentiating term (6) are proportional, and for generating at the output of the other rectifier (20) signals which the Signals of the other polarity at the output of the inertial member (5) and the differentiating term (6) are proportional to the inclusive circle stand, and the display part (4) has two outputs that connect to the outputs of the rectifier (3 or 20) are connected, and is designed so that it is on the Wake-up components the signals at the outputs of the rectifiers (3, 20) responds.