DE2444250B2 - OSCILLATOR FOR GENERATING A RECTANGULAR PULSE TRAIN, WHOSE PULSE TRAIN FREQUENCY CAN BE CONTROLLED - Google Patents

Description

Output (P7) of the amplifier (V) and to an according to the invention is at the oscillator of the initially second circuit point (P4) with a second 5 ° named type of the output of the amplifier with constant potential each one opposite to a Schmitt trigger created in TTL technology Reverse polarity diode (Dl or Dl) connected is tied. its first threshold value and its second (Fig. 1, 2). Threshold value both have the same polarity and

5. Oscillator according to claim 1, characterized in that the output of the square-wave pulse characterizes the output of an operational sequence as an amplifier, the pulse edges of which are provided in the dependent wedge amplifier (V). from the first or second threshold value of the charging voltage

6. The oscillator according to claim 1, characterized in that the charging capacitor is generated. Unmarked, that the amplifier is a CMOS-In- the output of the Schmitt trigger with a verter is provided. Control input of the switching element connected.

60 The oscillator according to the invention stands out

due to low technical effort, because the

connected to the output of the amplifier

The invention relates to an oscillator for Schmitt trigger of a lower technical level a rectangular pulse train whose wall requires than the two comparators and the Pulse repetition frequency is controllable and the one integrator 65 second integrator in the above-mentioned known which in turn consists of an inverted oscillator. Since there are Schmitt triggers in TTL structures There is an amplifier whose output is wise, the oscillator according to the invention is without Charging capacitor with the inverting input of the additional technical effort in TTL design

realizable. Using the Schmitt trigger prevents unwanted oscillations on. because the Rückkopphingsweg vcm output of the Schmitt trigger for the electronically controllable switching element can be kept as short as possible, whereas with the known oscillator a relatively long feedback path from the output of the first comparator via the second integrator and via the second Comparator to the controllable switching element must be taken into account.

If a square-wave pulse train with a relatively low pulse train frequency is generated should, then it is appropriate to provide a field effect transistor as the switching element, the switching path connected on the one hand to the inverting input and on the other hand to the output of the amplifier and whose control input is connected to the output of the Schmitt trigger.

If a square-wave pulse train is to be generated, its pulse train frequency is relatively high is, then it is useful to provide a transistor as the switching element, its emitter-collector path is connected to the inverting input and to the output of the amplifier and its Basis of the generated rectangular pulse train is fed.

The following are exemplary embodiments of the invention on the basis of FIG. 1 to 3 described, with the same items shown in several figures are provided with the same reference numerals. It shows

Fig. 1 shows a first embodiment of a voltage-controlled Oscillator using a «field effect transistor,

F i g. 2 a second embodiment of a voltage controlled Oscillator using a switching transistor and

FIG. 3 shows signals that are generated during operation of the oscillators according to FIG. 1 and 2 occur.

The oscillator shown in Fig. 1 consists of the operational amplifier V, the capacitor C, the field effect transistor FT, the Schmitt trigger ST, the diodes Dl, D2 and the resistors R 1, R 2. The operational amplifier V has two inputs, from one with a minus sign and the other with a plus sign. The input marked with a minus sign or a plus sign is connected to the inverting or non-inverting channel of the operational amplifier V. The operational amplifier V forms an integrator with the capacitor C , the integration duration of which is set using the field effect transistor FT. In the following, the mode of operation of the in F i g. 1 illustrated oscillator based on the in F i g. 3 illustrated signals explained. The abscissa directions relate to the time t. The control voltage A shown in FIG. 3 is applied to the circuit points P1 and P2. In this exemplary embodiment, it is assumed that the control voltage, starting from an amount of 0 V at time Z _1, rises to an amount of -10 V at time i _5. The voltage B develops between the circuit points P7 and P8 and thus on the charging capacitor C , which increases from the point in time r and reaches a threshold value 51 at the point in time fo, which is + 1.7 V in this exemplary embodiment. From the time r _x to the time t ₂ , the Schmitt trigger ST emits the signal D with a voltage of +5 V. At the time t _z , the Schmitt trigger ST switches, so that the signal D drops to the value of 0 V during the duration d ₂ and the field effect transistor FT is controlled in such a way that it conducts the connection points P 7 and P 8 to one another and the Charging capacitor C is discharged. In the course of this discharge, the voltage B applied to the capacitor C is decreased from the point in time i ₂ until it reaches the second threshold value S 2 , which is set at +0.9 V in the present exemplary embodiment

is / _{3 is} reached, at which the Schmitt trigger switches again, so that the switching path of the field effect transistor FT blocks with the signal D equal to + 5 V and the capacitor C is recharged _{from time / s} to time / _4.

ao The maximum achievable pulse repetition frequency of the generated pulse train D emitted via the switching points P 3 and P 4 depends on the times d _t and d _3. Here, d _{t is} the integration time, which on the one hand is proportionally dependent on the voltage A abas and on the other hand on the product of the amount of the resistance R 1 and the capacitance of the capacitor C and on other data from the operational amplifier V. The time <f _ä is only determined by the internal resistance of the switching path of the field effect transistor FT . Since the internal resistance of this switching path of the field effect transistor FT is relatively large, the exemplary embodiment according to FIG. 1 is suitable. 1 mainly for generating a square-wave pulse train D relatively low pulse train frequency.

A positive operating voltage of + 5 V is applied to the circuit point PS and to ground. The two oppositely polarized diodes D 1 and D 2 serve to protect the Schmitt trigger ST. A TTL gate with a known Schmitt trigger input circuit is provided as the Schmitt trigger ST.

F i g. 2 shows a further exemplary embodiment of a voltage-controlled oscillator in which the switching transistor TR is provided instead of a field effect transistor. The signal D from the output of the Schmitt trigger 57 ″ is reversed in polarity using the further Schmitt trigger STl, so that the result is the signal Ό , which is output on the one hand via the switching points P 3 and P 4 and on the other hand via the resistor R. 3 is fed back to the base of the transistor TR and the emitter-collector path of this transistor is _{blocked for the duration d x} and opened for the duration d _s and in this way the in

F i g. 3 signals BD Ό shown are generated. Since the internal resistance of the Schalmrceke of the transistor TA is smaller than the internal resistance of the holding path of the in F i g. The field effect transistor FT shown in FIG. 1, the oscillator according to FIG. 1 is suitable. 2 for generating pulse trains with a higher pulse train frequency.

Instead of the amplifier V , a CMOS inverter can also be provided, the output of which is connected to the point P 7 and the input of which is connected to the point P 8.

1 sheet of drawings

Claims (4)

1 2 _ ... the amplifier is connected Claims: integrator from an electronically controllable switching L oscillator for generating a rectangular element whose switching path is parallel to the charging con- migen pulse train whose hnpulsfoigefrequeoz capacitor is switched. The oscillator contains additional controllable and which contains an integrator, lent a resistor to which on the one hand a spa standing from an inverting amplifier, voltage for controlling the pulse repetition frequency is applied its output via a charging capacitor and the other with the inverting input the inverting channel of the amplifier is connected to the amplifier is bound, and consists of an electronic input according to Electronics magazine, July 5, 1971, controllable switching element, whose switching path io p. 59, known oscillator consists of a first is connected in parallel to the charging capacitor and integrator, from a second integrator, also from with a resistor at which, on the one hand, a first comparator and a second Voltage to control the pulse repetition frequency the same. The output of a first op- is applied and the other hand with the inverting * rationsversterkers or a second Operationsver channel of the amplifier is connected, thereby 15 amplifier via a first charging capacitor or via characterized in that the output (P 7) of a second charging capacitor with the inverting Amplifier (V) using an input of the first or second operation mode using TTL technology. Schmitt trigger (ST) is connected, stronger connected. Parallel to the first or second its first threshold value (S 1) and its second «charging capacitor is an electronically controllable one Threshold value (S 2) both have the same folarity as the first or second switching element. The outcome of the sit and the square-wave first operational amplifier via its output has an input shaped pulse train (D, ZJ) emits, the pulse of which is connected to the first comparator, and at one edge depending on the first or second second input of the first comparator is a first Threshold value (Sl or S 2) of the charging voltage (B) control voltage for controlling the pulse width of can be generated at the charging capacitor (C) and can be connected as rectangular pulses. The outcome of the the output of the Schmitt trigger (ST) with a second operational amplifier has an input Control input of the switching element (FT, TR) connected to the second comparator and to one is bound (Fig. 1 to 3). second input of this second comparator is one 2. Oscillator according to claim 1, characterized in that a second control voltage for controlling the duration of the indicates that a field 30 pulse gaps can be connected as a switching element. The output of the two-effect transistor (FT) is provided, the th comparator of which is connected to a control electrode of the switching path to the output (P 7) of the first controllable switching element. This kers and to the inverting channel (P 8) of the known oscillator requires because of the use amplifier (V) is connected and whose control input of the two comparators and the two integrators with the output of the Schmitt 35 requires a relatively large technical effort and has triggers ( ST) is connected (Fig. 1). the disadvantage that it cannot be used with TTL components. 3. Oscillator according to claim 1, characterized in that it can be generated. Another disadvantage of this known characterizes that the switching element is a switching oscillator that special precautionary transistor (TR) is provided, the emitter gene must be taken to avoid an unintentional collector path to the output (P 7) of the Ver 40 oscillations in the area of the first and the second amplifier (V) and connected to the inverting channel of the comparator, especially with low pulse train amplifier (V) and its frequencies of the generated rectangular pulse base electrode with the output of the Schmitt sequence to prevent. Triggers (ST) is connected (Fig. 2). The invention has for its object to be a 4. Oscillator according to claim 1, characterized in that the output (P 7) of the amplifier is characterized by a comparatively low technical amplifier (V) and a circuit point (P6) effort at the output (P 7) and which can be implemented using a first constant potential or on the TTL modules.