DE1114534B - Pulse delay circuit - Google Patents

Description

The invention relates to signal delay circuits, especially those for generating a delay of easily variable duration.

In general, the invention features methods and apparatus for delaying signals Storing a certain magnetic flux in a core of magnetic material to the object, where the flow is a function of the desired delay time. The signals to be delayed reverse the direction of flow of only the magnetic flux stored in the core, and the signals become dependent on the time required for the reversal of the stored magnetic flux Period delayed.

In the preferred arrangement according to the invention, the delay time of the signals is electronically controlled. Certain types of cores made of magnetic material are particularly suitable for this Well.

The cores of the preferred type are made of a high remanence magnetic material and a approximately rectangular hysteresis curve produced. The preferred cores have multiple openings on, storing and adjusting a certain magnetic flux in around an opening tracks running around can easily be carried out electronically. By installing this Cores in the delay circuits can reduce the delay time in the range of storage capacity of the individual core for the magnetic flux can be changed.

Furthermore, a preferred circuit arrangement was designed so that the delay time the volt-microsecond integral of a setting signal is directly proportional.

Another advantage of the delay circuit built into the preferred embodiment Kernel with multiple openings consists in the fact that a single Eirastellsignal the storage and Use of a certain magnetic flux causes unlimited and that the size of the said stored magnetic flux can be precisely regulated by controlling the duration of the setting signal can.

The invention is based on a delay circuit whose delay effect on the Loss of hysteresis of a saturable magnetic core when changing from one flux state to one other is based.

It is characterized in that one or more Windings coupled to the core are excited and at least part of the core into one Pulse delay circuit

Applicant:

The National Cash Register Company,
Dayton, Ohio (V. St. A.)

Representative: Dr. A. Stappert, lawyer,
Düsseldorf, Feldstr. 80

Claimed priority:
V. St. v. America, July 22, 1959 (No. 828 910)

bring certain first flux state and that a signal delay winding an input pulse receives, by the rising edge of the core in a certain second flow state is brought, so that depending on the particular selected flow states the falling edge of the output pulse arising in the further winding mentioned a certain amount of time with respect to the leading edge of the input pulse is delayed.

For a better understanding of the invention, two exemplary embodiments are described with reference to the drawings described. It shows

Figure 1 is a circuit diagram of the first and preferred Embodiment of the invention,

FIG. 2 voltage curves of certain signals occurring in the circuit according to FIG. 1,

Fig. 3 is a circuit diagram of a portion of the circuit shown in Fig. 1 which allows the implementation of a delay illustrated.

4 a and 4 b hysteresis curves, as they result from the query of the large or small opening of a result in the preferred embodiment of Fig. 1 core shown with several openings,

Fig. 5 is a circuit diagram of a further embodiment according to the invention,

FIG. 6 voltage curves of signals which occur in the circuit according to FIG. 5,

FIG. 7 shows a hysteresis loop of a magnetic core used in the exemplary embodiment according to FIG.

The preferred circuit arrangement for delaying signals of FIG. 1 includes a one

109 707/175

Transfluxor forming core 12, which has several openings for storing certain magnetic fluxes to generate corresponding signal delays. In the circuits for storing the magnetic flux is a quenching circuit 14 through which a magnetizing force the core is applied to saturate it in each direction of flow, and an adjustment signal circuit 16, through which adjustment signals are applied to the core to determine the direction of this magnetic flux partially reverse and thereby store the desired magnetic flux in the core.

The signal to be delayed is fed to the input of a delay circuit 18 which is connected to the Core is inductively coupled. The signals at the output of this circuit are increased by the setting signals certain period delayed. A reset circuit 20 resets the core 12 and delivers a signal at the output of the signal delay circuit 18 to delay the falling edges of the just to achieve delayed signals.

The core 12 used in the circuit according to the invention stores the magnetic flux that is a function of the desired signal delay time.

The core 12 provides a reliable means of storing magnetic fluxes in a core within the storage capacity for the magnetic flux of cores. The stored in a core Magnetic flux can vary from zero to an amount as small as that around a small opening 30 Flow path 24, as indicated in dotted lines in Figures 1 and 3, is saturated. The maximal Storage capacity of the core 12 is determined by the maximum around the small opening 30 extending remanent magnetic flux is determined. The maximal Delay time, on the other hand, is limited to the time it takes for the flow to reverse on the Flow path 24 around the small opening 30 is required, in order to avoid the loss of signal parts, the duration does not exceed the time between signal level changes.

Below is a more detailed explanation of how a multi-aperture Core, such as the at least two openings, namely a small opening 30 and a large one Core 12 having opening 32 can be used to store a magnetic flux, which can be queried by query windings guided through the small opening.

The first step in storing magnetic flux is to apply magnetization to the core in order to saturate it in a first flow direction.

In the preferred arrangement shown in FIG. 1, the core 12 can flow through a current on a through the large opening 32 guided and applied to an outer core part 36 winding, as by the arrows shown will initially be saturated. The cross-sectional area of the core part is preferably 36 equal to the sum of the cross-sectional areas of the core parts 38 and 40, which are also of the same size. the parameters mentioned have a better efficiency result, and the maximum storage of magnetic flux around the small opening is determined by the core dimensions.

A reversal of the initial magnetic flux around the large opening 32 created by an at Demagnetizing force applied to the core is created, stores in the web around the small Opening 30 of the core has a certain flow. In Fig. 3, the arrows 42 and 44 show the directions of the The course of the magnetic flux, which occurs as a result of the storage of a magnetic flux around the opening 30 surrounds the opening 32 directly.

Since the demagnetizing force causing the flux reversal tends to change the direction of the flux to reverse with the shorter magnetic path before reversing the flux with the longer path, the reversal of the initial magnetic flux begins immediately at the periphery of the opening 32 and extends radially further outwards, with the setting signal having a constantly increasing demagnetizing force generated. Once a magnetic flux is stored in the flux path around the small opening has been, this is applied by the superimposition of a on the outer core part and a winding going through the small opening and applied to the core part 38 Reversed magnetizing force. The stored magnetic flux is the flux in the orbit around the small opening; he is available for sensing by reversing the magnetic flux through on the Core part 38 applied windings available. The magnetic used to reverse this stored The time required to flow through the signal to be delayed is the delay time.

The above explanation of the operation of the delay circuit agrees with the Theory which states that the reversal of the direction of a magnetic flux on a annular line around the opening of a core required energy with the radial distance of the Flow line grows from the inner edge of the opening. There can also be a magnetic flux in opposite directions Directions saturate a nucleus in different areas at the same time while the whole nucleus is in is a state of partial saturation.

From this it is clear that after the initial saturation of the core 12 by a clockwise direction flowing magnetic flux as a result of an erase signal coupled to the erase winding 34 magnetic flux around the small opening 30 by applying an adjustment signal that has a constant Has voltage and an adjustable period of time to adjust the size of the stored magnetic River has to be saved. A state of partial saturation results in which the magnetic River flows simultaneously in opposite directions around the large opening.

3 shows the core 12 after the application of an adjustment signal. The one in the direction of arrows 42 and 44 Magnetic flux passing around the large opening 32 has thereby been reversed and forms the annular smaller lines of flux around the small opening 30. The one in annular lines of flux in the direction of the Arrows 42 and 44 around the small opening 30 is the magnetic flux stored in the core magnetic flux.

Fig. 3 shows the typical flow distribution. It goes without saying that the through a single setting signal generated flux distribution represents only a certain magnetic flux which is stored in the core 12, and that the stored magnetic Flow varies for different delay times. With a relatively short setting signal for

a short delay time, only a small demagnetizing force is applied and only a small one Part of the magnetic flux running around the large opening 32 is reversed, whereby only one low flow around the small opening 30 is stored. The flow size in the shorter lines is how mentioned, a function of the delay time. Furthermore, the reversal time of the stored magnetic Flux and the delay time are a function of the flux, the amplitude of the with the core coupled signal and the number of turns of the guided through the opening 30 and on the outer core part 38 applied windings.

In Fig. 4 a the magnetic flux and the magnetization are shown, which caused by repeated application of signals to a setting winding 46 stepwise transition from the saturation in a first direction corresponding remanence state 1 caused by a cancellation signal 54 to successive saturation show corresponding remanence states in the opposite direction. The states of partial saturation of the cores after each setting signal are shown by the remanence states 2 to 6. As a result of the repeated application of setting signals, the remanence state of the core changes gradually from remanence state 1 to remanence state 7 on a path indicated by the dashed line connecting remanence states 1 to 7. The different magnitudes of the stored magnetic flux in the flux lines 24, which run around the small opening 30, and the associated hysteresis curves, which correspond to the remanence states 1 to 7 of the core 12, are illustrated by the curves la to la in FIG. 4b. It turns out that the remanence state 4 of the core brings a maximum storage of magnetic flux around the small opening 30, the hysteresis curve 4a corresponding to the remanence state of the core 12.

In order to generate a stored magnetic flux of a certain magnitude in the core 12, is the demagnetizing force applied to the core by a signal with a certain constant voltage and certain duration (= voltsX microseconds) generated. This signal is sent to the adjustment winding 46 placed, which is passed through the large opening 32 and applied to the outer core part 36. The adjustment winding however, it can also be wound around the inner core part 40. The polarity of the setting signal and the direction of the winding are chosen so that a core initially saturated by an erase pulse by reversing the direction of flow in it and, in particular, by reversing that near the large opening 32 running magnetic flux is demagnetized by a certain amount, wherein the radial distance of the reverse flux lines from the orifice 32 is with duration of the setting signal grows.

The signals to be delayed are applied to the core through a signal delay winding 48 which is passed through the small opening 30 and applied to the outer core part 38. The signals are sweeping the direction of the one running around the small opening 30 stored magnetic flux and are delayed during the reversal time.

From the foregoing it is clear that by appropriate choice of the supply voltages and number of turns of the windings around the core directly in accordance with the delay time the duration of a setting signal can be brought. To ensure that the signal windings 48 and the setting winding 46 received a constant supply voltage, the supply circuit was arranged in such a way that that it limits the supply voltage so that the core 12 by the time duration of the setting signal certain flow is brought into a state of partial saturation.

In the signal delay circuit 18, the initial changes in the waveforms, i. H. whose rising edges, which are applied to the input, in the output by setting the in the shorter lines of flux around the opening 30 delayed stored magnetic flux. During the delay time the signal energy is consumed by reversing the stored magnetic flux. Since the signal energy does not return to the output of the delay circuit, the Circuit arrangement additionally precautions are taken to avoid the downward changes, d. H. the Falling edges of the waveforms to delay.

The reset circuit 20 was used to reset the flow direction of the stored flow in the core as well as to support the delay of the falling edges of the signal foranas in the signal delay output circuit intended. The reset circuit includes a winding 50 applied to the core part 38 of the small opening 30. This is connected to a supply voltage source via a current limiting resistor 52 and via a diode 84 connected to a limiting voltage source. As a result of this limitation, there is only one magnetizing force generated, which is just sufficient to the stored magnetic flux around the opening 30 reset around. The level of the magnetizing force generated by the reset circuit is too low to disturb the magnetic flux in the flux path around the large opening 32. Thus, the Reset circuit 20 returns the core around the small opening 30 to the state shown in FIG. 3, to prepare the delay of subsequent waveforms.

The circuit arrangement for the signal delay enables the initial erasure, ie the saturation of the core 12, by applying an erase signal 54 to the input terminal 56 of the erase circuit. The erase signal is applied to erase winding 34, the other end of which is connected to ground 58. A cancellation signal of suitable polarity, as indicated in Fig. 1, initially saturates the core in the opposite direction.

A setting signal 60 is applied to the input terminal 62 of the circuit 16 to store a magnetic flux in the core by applying a demagnetizing force to the core and thereby put the core in a state of partial saturation, preferably in a remanence state between points 1 and 4 on the vertical axis of the Φ-φ curve, as shown in Fig. 4 a. The adjuster is applied from the input terminal 62 to the base of a transistor 64 through an RC parallel circuit 66 containing a positive bias source 68. The transistor 64 is preferably a pnp transistor, the emitter of which is connected to ground and the collector of which is connected to one end of the setting winding 46. That

the other end of the aforementioned initial winding Via a current limiting resistor 72 to the supply voltage -50 V, which is fed via a diode 70 a certain size, e.g. B. -4 V, is limited.

In the signal delay circuit 18 there is an AC parallel circuit 76 at an input terminal 74 for applying an input signal from the form 78 to the base of a transistor 80 in which it is preferably a pnp transistor. The collector of transistor 80 is the input signal onto the delay winding 48, reducing the rising edges of the signal during reversal of the stored magnetic flux passing around the small opening 30 can be delayed. the Signal delay winding 48 is passed through the small opening 30 and onto the outer core portion 38 upset. The other end is connected to voltage sources that are both connected to the signal delay circuit and are connected to the reset circuit. The one supplied to the signal delay circuit Voltage is limited by a diode 81.

The collector of a transistor 86 is connected to the output of the signal delay circuit and the Output terminal 88 coupled. The emitter of transistor 86, which is preferably is a pnp transistor, is connected to ground 94, so that the output circuit during the time in which the stored magnetic flux is reset, is connected to earth. As a result, the output circuit is during the negative part 90 of the reset signal F ^ via this transistor 86 with Connected to earth.

Between the falling edge of the input signal 78 and the rising edge of the negative part 90 of the Reset signal can be a very short period of time. To get over transistor 86 during this short Maintaining a connection to ground is the base of transistor 86 via a period of time Capacitor 92 connected to a conductor that connects the collector of transistor 80 to the signal delay winding 48 connects. The capacitor 92 has a short response time and receives a negative one Charge that reaches the base of transistor 86, making it conductive and the output of the Signal delay circuit connects to ground 94. The output signal therefore does not follow the falling edge of the input signal during the short period between the falling edge of the input signal and the rising edge of the negative part. 90 of the reset signal. The transistor 86 remains conductive as long as until the negative part 90 of the reset signal shows the conductivity in transistor 86 and thereby maintaining the connection of the output circuit to ground.

An erase signal 54, which is applied to the core 12 of the circuit of FIG. 1 via an erase winding 34, saturates it around the large opening 32 in a clockwise direction in lines of flux indicated by the arrows 26, 27 and 28. A setting signal 60 is now applied to the core via the setting signal winding 46, the size and duration of which (== volts ν microseconds) corresponds to the desired delay time. The reversal of the direction of flow of the magnetic flux in the flux lines around the large opening is achieved via the setting signal winding, whereby the core is preferably brought into a remanence state between 1 and 4, as shown by the curve in FIG. 4 a. With the reversal of the direction of flow in the flow lines around the large opening, as shown by arrows 26 and 42 in FIG. 3, the flow in the inner core portion 40 between openings 30 and 32, as indicated at 44, is also reversed. The reversal of the magnetic flux in the inner core part 40 results in a magnetic flux around the small opening 30, which can now be viewed in isolation until it is necessary to store a different amount of magnetic flux around the small opening to thereby differentiate To achieve delay times. The magnetic flux available around the small opening 30 to reverse the winding 48 and 50 or other interrogation windings only passed through the small opening 30 or other small openings in a core having more than two openings is the magnetic flux stored in the core. The reversal of the stored magnetic flux in the flux lines around the small opening produces a hysteresis curves of the 1 b shown in Fig. 4 α to la.

Signal 78 (V _m ) to be delayed is applied to input terminals 74 for delay. The changes in the level of the signal, ie their rising and falling edges, are separated by periods of time which are at least equal to and preferably greater than the delay time, thereby preventing part of the signal from being lost. On the negative leading edge of signal V _1n , transistor 80 conducts and the clamping voltage -4 V is applied directly to winding 48. The current through the signal delay winding 48 is delayed during the period of time during which the stored magnetic flux in the flux lines 24 around the small opening is reversed. After reversing the stored magnetic flux, resistor 96 acts as a current limiter and the signal output voltage rises from -4 volts of the limiting voltage level across conductive transistor 80 to ground potential. Thus, as shown in FIG. 2, the rising edge of the waveform F ₀ is delayed by the period of the delay set in the delay circuit.

While the input signal V _{1n is} still negative, the current in the signal delay winding 48 compensates for the current through the reset winding 50 on the core portion 38. In the preferred arrangement, there are approximately twice as many ampere-turns on the signal winding 48 as below for the duration of the input signal normal conditions are generated in the reset winding 50. During the duration of the input signal, the ampere turns generated by the signal delay winding prevent the restoration of the stored magnetic flux which remains switched in the core part around the small opening.

When the falling edge 98 appears, the transistor 80 blocks and one appears on the winding 48 negative peak, which reaches the base of the transistor 86 via the capacitor 92, makes it conductive and the other way for the supply current to earth in the output of the signal delay circuit closes.

In order to delay the falling edge of the output signal F _n by the entire delay time, the reset circuit takes over the control of the transmission. After the transistor 80 after termination

9 10

of the input signal is no longer conductive, the outer core part 38 connected to the reset circuit containing the output of the winding 50 in the output of a signal delay circuit 130 generates a magnetic force to the. In the preferred arrangement of the circuit shown in FIG. 5, the stored magnetic flux in the flux appears to be the leading edge of the line around the small opening 30 to reset. During 5 setting signal 124 simultaneously with the falling edge rend the time in which the stored magnetic of the input signal. As shown in Fig. 6, the flux is reset, the end of the reset winding connected to the voltage falling edge to the normal level of the input source is negative for the signal in the output circuit by superimposing one of the limiting voltage of the inverted setting signal pulse V _R on the magnitude . The delayed for resetting the output signal V _{0 by the io.} The signal V _R is applied to the stored magnetic output of the signal delay circuit running through a small opening due to the flow required is equal to the time, a diode 132 and a conductor 135 connected to the input signal in the signal delay transistor 128,
output circuit, ie during the reversal time of the signal delay circuit 130 contains a stored magnetic flux that has been delayed. 15 Signal delay winding 134, which runs through the OfE-After the voltage running around the small opening has been passed and magnetic flux has been reset around part of the core, the return 102 runs. The signal to be delayed is returned to the control signal at the ground level by grounding via the delay winding via an input terminal coil 38, and transistor 86 is again blocked at 136 and one with a bias voltage source. The output of the signal delay circuit 138 connected to terminal 140 is thereby separated from ground and the output is applied. The input circuit outputs the signals output signal returns to the limit voltage level the base of the transistor 142, the emitter of which is (-4 V) back. The pulse widths of the input and earth and its collector with one end of the Ver output signals of the delay circuit are connected in the delay winding. The other end is essentially the same, and the output signal is opposite the delay winding is at a voltage above the input signal by the desired time source, which has been delayed by a diode 144 and a current duration. limiting resistor 146 to a certain span. In Fig. 5 another embodiment is shown, voltage, e.g. B. -4 V, is limited. The output circuit of a signal delay circuit 100 contains a diode 148, the delayed output conventional output terminal 150 made of magnetic material with an- 3 ° signals V ₀ from the delay winding to an approximately rectangular hysteresis loop. The diodes 132 and annular core 102 includes. The core 102 is magnetically coupled with 148 via a summation resistor 154 to each of a plurality of operating circuits by means of their negative voltage supplying terminal 152 connection-corresponding windings. the, whereby parts of the to one of the two diodes get an erasure circuit 104 contains an output signal given by an opening to the output terminal 108 and applied to the core. For example, the delayed winding 106. One end of the quenching winding is signal level above the limit voltage connected to the input terminal 110 of the quenching circuit promising the rising edge of the output signal V ₀ , to which the quenching signals running to earth 114 are passed through the diode 132. A can be placed over the limit V _c . The quenching circuit saturates the 4 ° voltage lying signal level, when the core 102 is passed through the diode 148 flowing in the direction of the arrow 112, to reduce the drop in magnetic flux. of the output signal V ₀ during the duration of the In FIG. 7, the hysteresis loop of a signal V _{R is} to be delayed. The signal V _R has a duration suitable for the circuit of FIG. 5, which corresponds to that of the setting signal 124,
shown. During the erase process, the erase signal 45 switches. The mode of action is as follows: First, as a result of the application of a magnetizing force H, the core 102 is in a saturated state through a core connected to the erase winding 106 in an erase signal V _{c given by the reference numeral 116 in FIG. 7} displayed saturation level. After that brought. The flux runs in the direction of arrow 112. If the erase pulse falls, the core returns to a magnetic remanence. A setting signal then returns to the magnetic state indicated at point 118 in FIG. 7. around. As a result, the core enters a state. A setting circuit 121 is partially saturated with the core 102, ie in a remanence state, through a winding 122 which is passed through the opening 108 and, for example, at point φ% on the perpendicular part of the core. th axis is indicated where the part 160 of the couples through. The circuit arrangement for storing 55 the curve indicated by the dotted line resembles the perpendicular magnetic flux in the core 102 that intersects the axis. The magne-fig stored in the core. 1 circuit shown schematically for storing magnetic flux is equal to the Flußdifferenz the magnetic flux in the core 12. An adjustment see certain Remanenzzustände, ie the ter in Fig. 7 at 118 duration is an AEC member 120 to one with and _Φ κ indicated flow difference,
The input terminals connected to the base of the transistor 128. The signals V _1n to be delayed are applied after terminal 126. Via the transistor 128, other runs on the transistor 142, whereby the signal via the setting winding 122, whereby the delay winding 134 magnetizes all of the magnetic flux stored in the core, is applied to the core. The magnetization generated by each signal from the duration of the setting signal and the feed switches the core in which is dependent on the voltage of the setting circuit. The saturation supply voltage of the setting winding 122 indicated at 116 in the curve of FIG. 7 is returned by state. During the time in which the core a diode 129 to a certain voltage, e.g. B. 102 is returned to the saturation state, -4 V, limited. the rising edges of the signals are preferred

delayed by the same time it took to adjust the core. During the remaining duration of the input signal, transistor 142 remains conductive and the output signal level remains constant.

The output signal level of the signal delay circuit is prevented from falling at the time of the falling edge of the input signal, and the falling edge is delayed at the output by the signal V _K , the rising edge of which coincides with the falling edge of the input signal V _1n . As shown, the falling edge of the output signal is delayed by the same amount of time that the rising edge was delayed, provided that the number of turns of windings 134 and 122 are equal, thereby reducing the time between the rising and falling edges of the input signals. and output signals remain approximately constant.

An input signal can be delayed by a time that can be changed by a setting signal, wherein the delay time varies between zero and the duration of the signal to be delayed.

On the basis of the aforementioned teaching on technical action, there are various modifications of the invention possible, which are obvious to the relevant person skilled in the art, without him of goes beyond the spirit and scope of the invention. For example, a core can be replaced by a Permanent magnets or another device can be set, which is able to apply a certain magnetizing force to the core in order to this by storing any flow on it. The circuit arrangement can also do the same to delete the core can be modified or omitted entirely by others Means can be provided for saturating the core by applying a magnetizing force to it to generate a magnetic flux that saturates the core in a certain direction. The saturation the core can be followed by setting or storing, in which case the core is subjected to a demagnetizing angular force by suitable means is supplied to reverse the direction of flow of magnetic flux in the core. Also the size of the in the preferred embodiment according to FIG. 1 or in the further Embodiment of FIG. 5 used core can according to the desired delay time of the signals corresponding to the magnetic flux stored in the core at saturation are different to get voted. Furthermore, by changing the circuit parameters, i. h, the ampere-turns of the windings, the delay time with respect to the magnetic flux stored in a core to be changed. So z. B. the turns of the windings and the limiting voltage in the Signal delay circuits can be set to set the delay time for a given stored change magnetic flux in the core.

Claims (5)

Godfather to claims: 60 1. Delay circuit whose retarding effect is based on the hysteresis loss of a saturable magnetic core when changing over from one flow condition to another, data carried in that one or more coupled with the core windings (34, 46) are excited and at least a portion of the core in bring a certain first flux state and that a signal delay winding (48) receives an input pulse, the rising edge of which brings the core into a certain second flux state, so that depending on the certain selected flux states, the falling edge of the output pulse (F ₀ ) is delayed by a certain period of time with respect to the rising edge of the input pulse {V _{! N} ). 2. Delay circuit according to claim 1, characterized in that one in one with the called part of the core coupled reset winding (SO) current flowing after the drop of the input pulse the said core part or core again in the first state of the magnetic River brings. 3. Delay circuit according to claim 1 and 2, characterized in that the signal delay winding (48) and the reset winding (50) via a transistor switch (86) are interconnected so that as a result of during the resetting of said core part or core voltage occurring in the reset winding is the duration of the output pulse the circuit by the current flowing through the transistor switch to ground (94) for one Is extended, which is equal to the time during which the rising edge of the Input pulse decays. 4. Delay circuit according to claim 1, 2 and 3, characterized in that the core is a transfluxor (12) in which the input and reset windings pass through an opening (30) are performed, and that for switching the transfluxor into the selected first state Initial pulse is applied to a winding (34) guided through a second opening (32), the brings the transfluxor into saturation, and a pulse to switch the magnetic Material around the first opening (30) in the first state of another through the second opening (32) guided winding is supplied. 5. Delay circuit according to claim 1 and 2, characterized in that the core is a toroidal core (102) , that a pulse on a first winding the core in a first saturation state and a pulse on a second winding the core from this state in said brings the first state and that said second winding also serves as a reset winding and is connected to the output of the signal delay winding so that when a pulse is applied to the reset winding synchronously with the fall of a pulse fed to the signal delay winding, the toroidal core from the saturation state into said first state is brought and the output pulse is extended by the reset pulse for a period of time which is equal to the period of time during which the rising edge of the input pulse to be delayed decays. 1 sheet of drawings © 109 707/175 9.61