DE1562278A1 - Saw tooth generator - Google Patents

Description

Saw teeth g e n e n e r a t o r The invention relates to a Sawtooth generator for devices for electrical communications and measuring technology, consisting from an amplifier circuit and an integrator whose capacitor is a electronic circuitry is connected in parallel, depending on the desired The amplitude of the sawtooth voltage is the required periodic charge reversal of the capacitor undertakes. Sawtooth voltages are not only used to solve numerous metrological problems Tasks, but also to a large extent for modulation purposes, in particular for the implementation the message content of a continuous signal into a pulse-modulated voltage needed. In addition to the desired high temporal constancy, this often results and linearity of the sawtooth voltage the requirement that the frequency without feedback to the amplitude, which is also preferably adjustable within wide limits to change. The invention is based on the object for a sawtooth generator of the type described in the introduction to specify a circuit that is as simple as possible Structure allows the frequency to be increased without affecting the amplitude of the sawtooth voltage change. Based on a 9pg generator for electrical communications equipment and measuring technology, consisting of one Amplifier circuit and a Integrator whose capacitor is connected in parallel to an electronic circuit arrangement which is the required depending on the desired amplitude of the sawtooth voltage performs periodic charge reversal of the capacitor, the object is according to the invention solved in that a, preferably low-resistance, output of the amplifier circuit via a return path containing an amplitude discriminator: coupling path with the control input of the switching arrangement is connected so that the switching arrangement @ at Response of the amplitude discriminator from the blocked to the conductive state passes over and that the amplitude discriminator has a breakover resistor with a low resistance and a high-resistance stable state, preferably a tunnel diode.

For devices for reporting or eliminating faults in communication systems is already (DBP 1 261 909) a switching arrangement consisting of an electronic switch has been proposed, which is controlled indirectly by a tilting arrangement. the Tilting arrangement here consists of a tilting resistance, which is the control input of the electronic switch lies in parallel.

The invention is based on the knowledge. that breakdown resistances, in particular their best-known representatives, the tunnel diode, -a jump current., which has a high temporal constancy and also depends on the Temperature practically does not change. Breakdown resistors thus make it possible in an advantageous manner Wow to precisely determine the amplitude of the output voltage of the generator. aside from that affect their fast switching properties , favorable to the Switching speed of the overall arrangement. the end.

In a preferred embodiment, the switching arrangement is realized by a switching transistor whose control input is connected in parallel. Here; the control variable of the parallel connection is selected the Kippvriderotand and the control input of the switching transistor @, _ he preferably one adjustable -drained, high-ohmic resistor supplied.

The ratios are particularly favorable when in the case of the invention Generator circuit based on the principle of running charging voltage with a transistor is used in emitter pole connection as an amplifier element, its control input the capacitor is parallel and its emitter is connected to the charging voltage realizing capacitor with the connection point of the charging resistor, preferably a diode., is connected.

For circuits that use a sawtooth voltage to be in the frame To win impulses that are shifted in time in a clock grid, there are often breakover resistances or tunnel diodes are used, in which at least one tilting resistor is already in lower quarter of the ascending plank of a sawtooth period from its state low resistance must jump into its high resistance state while jumping for the last tilt resistance just before the end of the sawtooth period is prescribed. In other words, with such circuits, the saw tooth voltage supplying clock generator have a very high amplitude, so that the first jumping Tilting resistance at the end of one. Period must carry a current that In the worst case scenario, it is about ten times greater than the jump current. These disadvantages can be avoided if use is made of a constant pre-atom, which is chosen somewhat lower than the jump current of the first breakdown resistor, i.e., when the sawtooth voltage is superimposed with an appropriately sized DC voltage will. In this case, a significantly lower sawtooth amplitude is required. However, in order for such a dimensioned circuit to work properly, the sawtooth must be used be superimposed in the area of his skirt flank, there the breakover resistances otherwise due to their 'hysteresis AM' end 'of a period do not jump back into their low-resistance starting position. . According to a further training a sawtooth generator that makes use of the principle of the concurrent hades voltage according to the invention thereby for generating a sawtooth with one of its rear flank superimposed needle pulse that in the collector lead of the amplifier: transistor a preferably adjustable resistor is inserted. . Using an exemplary embodiment, that is shown in the drawing should. the invention in more detail below explained.

Pigur shows a sawtooth generator making use of the principle of the accompanying charging voltage, in which the control input of the switching device according to the invention is connected to a low-impedance output of the Veratärkersehaltung via an Ampli7 i tudendi criminator implemented by a tunnel diode. The actual amplifier connection of the generator has a transistor Tr2 in an emitter pole connection, at the emitter resistor Re of which the desired sawtooth voltage S1 is taken off via the terminal A1. The collector connection of the transistor Tr2 is connected to the DC operating voltage -Ub via a potentiometer P, the controller tap of which emits a further sawtooth voltage output A2. The sawtooth voltage S2 occurring here is reversed in phase compared to the sawtooth voltage 51 at the output A1 and also has a negative needle pulse N in the region of the trailing edge of a sawtooth period. Cl of the integrator is connected in parallel to the input of the transistor Tr2. This capacitor is periodically charged by the DC operating voltage -Ub via the series circuit made up of the charging resistor R1 and the diode D, which is a coupling resistor. Between the emitter of the transistor Tr2 and the connection point between the R1 and the diode D there is provided the additional capacitor Cb "which realizes the accompanying charging voltage and ensures the high linearity of the sawtooth leading edge. The switching transistor Tr1 perceives the periodic charge reversal of the capacitor Cl, which with its emitter-collector path lies parallel to the charging capacitor 01. The control input of the switching transistor Tr1 is connected in parallel with the series circuit of the tunnel diode T and the resistor R3. The resistor R3 is part of a voltage divider consisting of the resistors R1, R2 and R3, through which the The parallel connection of the control input of the switching transistor Tr1 and the tunnel diode T is supplied with the control current from the emitter of the transistor Tr2 via an adjustable, relatively high-resistance resistor Rs. This shunt loads the output A1 of the sawtooth generator practically not, as the internal resistance is very low due to the emitter sequential circuit.

To explain the mode of operation of the subject matter of the invention, it is initially assumed that the tunnel diode T is in the low-resistance state. In this case, the voltage present at the input of the switching transistor Tr1 is not sufficient to unlock the switching transistor. The capacitor C1, at which there is initially no voltage, is consequently charged linearly via the charging resistor R1 because the capacitor Cb keeps the charging current constant. Because of the emitter follower circuit of the transistor Tr2, the voltage at the output A1 exactly follows the voltage at the capacitor C1. The capacitor voltage can rise to a relatively large amplitude because the diode D allows the voltage at the connection point between the charging resistor R1 and the diode D to rise above the DC operating voltage -Ub. The resistor Rs, which is connected on one side to the emitter of the transistor Tr2, forces a linear increase in the control current in the tunnel diode corresponding to the voltage increase due to its high resistance. This continues until the jump current is reached and the tunnel diode changes from its low-resistance to high-resistance state. In this instant, the voltage at the base of the switching transistor Tr't jumps from a low to a high value, which controls the switching transistor to full collector saturation. The now very low-resistance collector path of the switching transistor suddenly discharges the capacitor 01 and at the same time reduces the voltage at the emitter resistor Re to such an extent that the tunnel diode controlled by the resistor Rs jumps back into its low-resistance starting position and thus the switching transistor Tr1 as well , returns to its blocked starting position. The charging of the capacitor C1 can now begin again.

Since the jump current of the tunnel diode, as already mentioned, a has high constancy, so is the amplitude of the sawtooth voltage output very constant. Furthermore, since the repetition frequency of the sawtooth voltage, apart from the tunnel diode jump current, depends only on the charging resistance and the DC operating voltage, it is very constant, provided the DC operating voltage is stabilized and the capacitors and resistors have sufficiently good electrical properties.

The amplitude of the sawtooth output voltage can be easily adjusted by changing the resistor Rs, because the jump current determines the end of the charging of the capacitor C1: The repetition frequency is set in a manner known per se by varying the capacitance of the capacitor 01 has in an extremely advantageous manner no influence on the amplitude once set by means of the resistor Rs. As already explained elsewhere, this is due to the constancy of the jump current of the tunnel diode T.

The sawtooth voltage S2 at the output of A2 is different from the sawtooth voltage S1 at the output of A1 by the trailing edge of the sawtooth superimposed negative spike N. This spike arises from the fact that the capacitor Cb when discharging of capacitor 01 is briefly transferred to its output voltage and this charge reversal here the emitter resistor Re flows through. This current cannot be noticeable at output A1 because the voltage present here must have the same profile as the voltage at capacitor C1 due to the emitter follower circuit of the amplifier transistor, ie that the current flowing through the emitter-collector path when the charging current occurs for the capacitor Cb must be reduced at each instant by the instantaneous value of this charge reversal, which is expressed at output A2 in the form of the fault pulse.

A sawtooth generator designed according to the invention provided a sawtooth voltage of a maximum of 9 V SS, the magnitude of which was adjustable within wide limits and the frequency of which could be varied continuously at a constant amplitude in the range from 500 kHz to 10 IHz. The DC operating voltage was -Ub 18 V. The switching and amplifier elements used were AFY10 type transistors and a silicon diode PC100 is used as diode D. the : other data for the circuit result from the : following table: R1 = 1 K .a RS = 10 KS? P = 200 R2 = 015 Ksl R1 = 6 K. # -L 0b = Q, 1 / uF R3 = 5 s? Re ^ 200 A Q 1 = 1000 pp

Claims (4)

P a t e n t a n s p r ü c h e 1. Sawtooth generator for devices of the electrical communications and measurement technology, consisting of an amplifier circuit and an integrator, the capacitor of which is an electronic circuit arrangement is connected in parallel, which depends on the desired amplitude of the sawtooth voltage carries out the required periodic charge reversal of the capacitor, characterized in that that a, preferably low-resistance, output of the amplifier circuit via a a feedback path containing Amplituder_-discriminator with the control input the switching arrangement is connected so that the switching arrangement when the Amplitude discriminator passes from the blocked to the conductive state and that the amplitude discriminator has a breakover resistor with a low resistance and a high-resistance stable state, preferably a Twineldiode. 2. Sawtooth generator according to claim 1, characterized in that the switching arrangement is a switching transistor is, the control input of which is connected in parallel to the tilting resistor, and that this Parallel connection of the breakover resistor and the control input of the switching transistor the control variable via a preferably adjustable, high-resistance resistor is fed. 3. sawtooth generator according to claim 1, characterized by applying the principle of the concurrent charging voltage with a transistor in emitter follow-up circuit as an amplifier element, the input of which is the capacitor of the integrator element lies in parallel and its emitter via one, the concurrent one Charging voltage realizing another capacitor with the connection point of the charging resistor for the capacitor and a coupling resistor, preferably a diode, connected is. 4. sawtooth generator in particular according to claim 3, characterized in that for decoupling a sawtooth, .dem a needle pulse is superimposed in the region of its trailing edge, a preferably adjustable resistor is inserted into the collector lead of the amplifier transistor.