DE2423061C2 - Circuit arrangement for delaying and increasing the edge of pulses for integrated circuits - Google Patents

Description

Circuit arrangements for delaying and increasing the edge of pulses are already known (see e.g. DT-AS '1 58 557; Siemens semiconductor switching examples 1969, pp. 1-8 to 131). Such formwork arrangements can be more or less complex. The delay is usually brought about by a resistor-capacitor element on the input side, during the slope is effected by an amplifier on the output side which is provided with positive feedback. This Positive feedback can be brought about with different switching elements, whereby corresponding Result in advantages or disadvantages.

A delay circuit is also already known at which the delay element is inserted between the two stages of a two-stage amplifier. This Time-of-flight circuit is constructed in such a way that it has a particularly high accuracy of the delay time has (see DT-OS 17 62 290). The circuit technology provided for this has, among other things, the consequence that the same connection of the capacitor belonging to the resistor-capacitor element at the same time under the Influence of the signal voltage and the positive feedback voltage is. This is one of the reasons that entails there have that in this known delay circuit, the advantages of the invention specified below do not are achievable.

The invention now shows a way in which, in a novel way, for positive feedback

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60 serving circuit elements are connected to the resistor-capacitor element. This results in advantages for the dimensioning of these switching elements compared to the known technology. These advantages facilitate the use of the circuit arrangement according to the invention for integrated circuits. All of this will be shown in detail in the explanation of the circuit arrangement according to the invention.

The invention is therefore based on a circuit arrangement for delay and for edge steepening from impulses, in which the delay through an input-side resistor-capacitor element and the edge steepening is brought about by an amplifier on the output side with positive feedback. The inventive Schahordnung is suitable for integrated circuits. It is characterized by that the one connected to the control terminal of the amplifier and to the resistor-capacitor element belonging capacitor with its other connection to the tap of one for positive feedback Serving voltage divider is connected, the ends of which to the output terminals of the amplifier are connected. The voltage divider is expediently made up of two ohmic resistors built up. It can easily be achieved that the resistance values of the voltage divider are so small. that they can be implemented in integrated circuits. Further appropriate training of the The circuit arrangement according to the invention will be explained using exemplary embodiments.

The invention is explained in more detail below with reference to a few figures. In the

Figs. 1 and 2 are examples of circuit arrangements for delay and edge steepness of pulses shown in which the positive feedback in a Way is brought about, which has disadvantages which are to be avoided by the invention. In the

Fig.3 and 4 are embodiments for the circuit arrangement according to the invention is shown.

The circuit arrangements shown in FIGS. 1 and 2 with input-side resistor-capacitor elements and output-side amplifiers with positive feedback operate in a manner known per se. By actuating the normally open contact s, such a circuit arrangement is supplied with a pulse which is passed on via the output terminal A with a delay with steep edges. The delay is brought about by the cooperation of the resistors RX, R2 and the capacitor C. In the circuit arrangement according to FIG. 1, the edge steepening is achieved by the cooperation of the capacitor CK and in the circuit arrangement according to FIG. 2 brought about by the cooperation of the resistance RK. Both circuit elements are used for positive feedback. The resistors R3 serve to decouple between the resistor-capacitor-Glicd used in each case and the further circuit elements connected to it in the circuit arrangements.

The positive feedback capacitor CK used in the circuit arrangement according to FIG. 1 has the disadvantage that it is less favorable as a capacitor than a resistor, and it also has the disadvantage, particularly in the case of integrated circuits, that it is worse to implement than a resistor there. In the circuit arrangement according to FIG. 2 the positive feedback is brought about by the resistor RK. However, this resistance must be relatively large compared to the resistors R2 and R3 , so that the positive feedback

does not cause the amplifier to become inherently stable. ie remains in a certain operating state regardless of the supplied pulse. It turns out that, for example, in the case of circuit arrangements that are constructed using C-Mos technology, the resistance RK must be approximately five to ten times as large as the series circuit made up of the resistors Rl and /? 3. This has the consequence that either the resistance value of the resistor RK has to be relatively large. for example 1 to 2 MOhm, or that the resistance values of the resistors R2 and R3 have to be relatively low. In both cases there are certain disadvantages. As is well known, it encounters z. B. in integrated circuits, difficulties in providing resistors that have relatively high resistance values i $. Avoid this and give the resistors R2 and R3 small resistance values. the result is that the capacitor C then has to have a relatively large capacitance in order to achieve a predetermined time constant. However, large capacities are always expensive and can only be implemented with difficulty, if at all, even with integrated circuits. Overall, the result is that the positive feedback can also be achieved in the circuit arrangement according to FIG. 2 difficulties connectedness i $ the is. which are to be avoided. These difficulties are in the exemplary embodiments of the circuit arrangement according to the invention according to FIGS. J and 4 avoided.

In both circuit arrangements according to FIGS. 1.2 and 3, the amplifier contains the two stages / 1 and 12. Each stage brings about a phase shift of 180 "so that in-phase output voltages occur behind the amplifier with the input voltages and the positive feedback occurs A resistor and a capacitor is brought about in the manner shown. It is known that components in integrated circuit technology are available for such stages. They can be used for the circuit arrangement according to the invention.

As can be seen from FIG. 3, the capacitor C belonging to the resistor-capacitor element is connected with one connection to the control connection of the amplifier / 1- / 2 and with its other connection to the tap of the voltage divider from the resistors used for positive feedback RK2 and RKi connected. The ends of this voltage divider are connected to the output connections A and ground of the amplifier / 1- / 2. Because the positive feedback is effected with the aid of a voltage divider in the circuit arrangement according to FIG. 3, the degree of positive feedback can be reduced not only by increasing the resistance of the resistor RK2 , but also by reducing the resistance of the resistor RKi . All other things being equal, the use of a resistor RKi with a sufficiently small resistance value can prevent the amplifier from becoming inherently stable due to excessive positive feedback and thus impeding the transmission of pulses. This means that the resistance value of the resistor RK2 is less than the resistance value of the resistor RK in the circuit arrangement ingenious. Fig. 2 can be. Furthermore, the use of the tension cable means that it is not necessary. Give resistor R2 a particularly small resistance value 711. Since the time constant of the resistor-capacitor element, which is decisive for the delay, depends on the product of the resistance value in question and the capacitance of the capacitor C, and the greater the product, the greater it is. It also emerges here that, under otherwise identical circumstances, the capacitor C has a smaller capacitance due to a higher resistance value of the resistor Λ2 and is therefore cheaper than usual or is easier to implement than usual. With a capacitor of a given capacitance, a considerably larger time constant and thus a considerably larger delay time can be achieved than with the circuit arrangement according to FIG. 2.

It is particularly useful to build the voltage divider from two ohmic resistors. It turns out that the part RKi of the voltage divider RKi-RKZ inserted into the charge-discharge circuit of the resistor-capacitor element Ri-R2-C can have a resistance value that is small compared to the resistance values of the resistor-capacitor element R \ -R2-C \\\. The period of time required for charging the capacitor C is therefore advantageously practically not influenced by the aforementioned voltage divider.

The mode of operation of the circuit arrangement shown in FIG. 3 is briefly described below. When the working contact s is not activated, i.e. open. the capacitor C to be charged, a voltage corresponding to the operating voltage -UB reduced by the resistance occurring at the RKi voltage drop LJRKi. A voltage -UA is present at the output terminal Λ of the circuit arrangement. which essentially corresponds to the operating voltage -UB. If the working contact \ is activated, i.e. closed, the capacitor C. If the amplifier / 1- / 2 has a control threshold, it is only reversed after a delay period, which is determined by this control threshold and the time constant of the resistor-capacitor- Limb is determined. Through this delay period, input interference voltages that z. B. caused by bruises of the working contact s , intercepted advantageously. Has de ^r capacitor C so far discharged, that the control threshold of the amplifier is exceeded, then the output terminal A is grounded. The voltage drop URKi across the resistor RKi disappears, as a result of which the voltage present at the input of the Vet amplifier changes via the capacitor C , increasing in the sense of the discharge of this capacitor. This supports the reversal of the amplifier, which results in a steepening of the leading edge of the pulse delivered to output terminal A.

If the normally open contact s is opened again, the capacitor C is charged again, namely via a current path that flows from ground via the parallel connection of the resistors RKi and RK2 to one connection of this capacitor and via the series connection of the resistors R 'and R2 ' .um leads to another connection of this capacitor. When the control threshold of the amplifier is reached, it is replaced in its initial / usiand \, with the voltage - UB appearing again at the output terminal Λ. Is then the voltage drop UKi occurs again at the resistor RKi . which supports the change in the voltage at the input of the amplifier while the capacitor is charging (! ")

Amplifier supports, which in the end results in a steepening of the trailing edge of the pulse delivered to output terminal A. It can therefore be seen that the intended positive feedback is effective via the voltage divider RK2, RK \. The degree of positive feedback can be set to a suitable degree by appropriately dimensioning the associated resistors RK \ and RK2.

The two stages of the amplifier / 1- / 2 can also be formed in discrete circuit technology by two galvanically coupled transistor stages connected in a chain. An example of a resulting circuit arrangement is shown in FIG. The transistor 71 and the resistor /? 4 belong to the stage / 1. The transistor stage is coupled to the transistor 72 and the resistors Rb and Rl via the resistor /? 5. These two transistor stages are constructed individually using conventional technology and can obviously perform the functions of the amplifier / I- / 2 of the FIG. To ensure that the amplifier formed by it has a favorable response threshold, the threshold value diode (Zener diode) G is inserted as a voltage threshold between the resistor-capacitor element R \ -R7 C and the amplifier. The threshold value diode G has a similar effect here

ίο known circuits (see e.g. DT-AS 12 06961). Appropriately, such a threshold value diode is chosen that the control threshold between one Third and two thirds of the operating voltage -UB is. The circuit arrangement shown in Figure 4 otherwise largely corresponds to that shown in FIG. 3 and therefore also has the same Way of working like this.

1 sheet of drawings

Claims (4)

• i patent claims: 1. Circuit arrangement for delaying and increasing the edge of pulses, in which the delay is effected by an input-side resistor-capacitor element and the edge increase is effected by an output-side amplifier with positive feedback, for integrated circuits, characterized in that the one having a connection to the control terminal of the amplifier (/ 1, 12 or 71, 72) and the resistor-capacitor element (Al, R2, Q belonging capacitor (C) connected with its other terminal to the tap of a voltage divider (RK2, RKi) serving for positive feedback whose ends are connected to the output connections of the amplifier (/ 1, / 2 or ΤΪ. 72). 2. A circuit arrangement according to claim 1, characterized in that the voltage divider consists of two to ohmic resistors (RK2, RKi) and that in the charge-discharge circuit of the resistor-capacitor element (Ri, R2, Q inserted part (RKi ) of the voltage divider (RKi, RK2) has a resistance value h & t that is small compared to the resistance values of the resistor-capacitor element (Rl, R2, Q). 3. Circuit arrangement according to claim 1 or 2, characterized in that the amplifier from two galvanically coupled transistor stages (71, 72) connected in a chain 4. Circuit arrangement according to one of the preceding Claims, characterized in that between the resistor-capacitor element and the amplifier (/ 1, / 2 or 7 \, 72) a threshold value diode (G,) is inserted as a stress wave