DE1462739A1 - Circuit arrangement for controlling a time base breakover voltage generator - Google Patents

Description

Circuit arrangement for controlling a time base breakover voltage generator The invention relates to a circuit arrangement for generating individual recurring Sawtooth tilt oscillations, where the voltage rise and tilt point are temporally opposite one another and opposite one another third previous point in time are precisely determined.

It is used primarily to generate deflection voltage for cathode ray tubes in devices, through the distances from reflection points with the help of pulse transit times be measured.

In the case of such devices, the entire time interval between two successive transmission pulses as well as in the interest of a high time resolution from this, arbitrarily selectable time segments on the screen of the slectron beam tubes being represented.

For the representation of the subsections, circuits are known in which the pulse repetition frequency by dividing the frequency of a basic generator several times is obtained, so that between two successive transmission pulses one through the number of divider stages fixed number of oscillations of the basic generator fall The basic frequency, as well as the frequencies of each divider stage, are fed to a decoding matrix, at the output of which in a manner known per se Square-wave pulses can be selected by a toggle switch, each of which in its temporal position a certain, located between two transmission pulses Vibration of the:. : uttergenerators corresponds.

These square-wave pulses are used to trigger the tilting process (voltage rise point) exploited. In this way, the time interval between the transmission pulse and the beginning of the tilting process is precisely determined, provided the oscillation frequency of the Hutter generator is constant, for example by using an oscillating crystal and known exactly.

The end of the tipping process, i.e. the tipping point, is related to his temporal constancy in these postures of those used in the tilt generator Components (RC elements, tubes, semiconductors). It is sufficient in many applications due to the voltage, temperature and aging dependency of these components not set requirements, so that a follow-up is carried out before a measurement must be.

The invention avoids this disadvantage in that the decoding matrix two separate square-wave voltages are taken with a time interval, where the first the rise point and the second the tipping point of the time base saw tooth voltage certainly.

The time interval between the two signals is determined solely by the Frequency of the mentioned very constant mother generator is determined and can depending on one or more periods of the selected taps on the decoding matrix Frequency.

The frequency of the alternating voltage generated in the mother generator is set according to the desired time intervals taken from the decoding matrix Signals and can be selected in such a way that these powers of ten are used for transit time measurements common units of measurement (seconds) or that these are in powers of ten for the unit of measurement used (meters, miles) must be specified.

The breakover voltage is generated in a manner known per se with a circuit arrangement in which by changing the Sohaltzuotandes a bistable Multivibrator's rise and break point of the sawtooth voltage can be set.

For the representation of stepwise shiftable measuring S slides the pulse voltages for starting and stopping the time base tilt voltage over two Step switch of the decoding matrix according to the desired ZeitabetäBdec The first tap of the decoding matrix is the pulse voltage for synchronization taken from the transmission pulse.

In this way, the step switch can be used to set the time from the start of the transmission pulse until the beginning of the tilting process and until the end of the tilting process, so also the breakdown time itself, at intervals of one or more periods of the mother generator choose.

Line variation of the circuit arrangement relating to the invention is that the start character for the time base breakover voltage generator is a fixed tap of the decoding matrix is taken, the temporal in the second half period the lowest divided frequency, while the stop sign is used to select the tilting time is to be taken from a tap of the decoding matrix via a changeover switch, the time is behind the aforementioned fixed tap.

The synchronization character for the transmission pulse is also, by a switch selectable, taken from a tap of the decoding matrix, the temporal in front of the fixed tap and the time interval between the transmission pulse and Start of tipping as the shifting time.

To improve the time accuracy of the use of characters finir the Control of the breakover voltage generator and the transmission pulse are known per se Way, the respective square-wave voltages taken from the decoding matrix The pulse voltage generated in the basic generator is derived from the pulse voltage with a steeper The leading edge is brought into coincidence by means of corresponding AND gates. The draw of the aforementioned control characters occurs if they come from the decoding matrix Square pulse the pulse derived from the frequency of the basic generator with steeper Leading edge falls, d. ht, the trip point dcr. C tax code will directly from the basic generator, while via the decoding matrix the desired Period the generator is selected.

The application of the circuit arrangement according to the invention is intended below on two examples for a locating device for the detection of wave impedance deviations explained in electrical wiring.

In the drawings are the circuit arrangements according to the invention explained in two exemplary embodiments of a fault location device.

It shows: FIG. 1 a block diagram. FIG. 2 an oscillogram diagram to Fig. 1 Fig. 3 A block diagram Fig. 4 Bin oscillogram plan to Fig. 3 to the block diagram of FIG. 1 and the oscillogram diagram of FIG. 2 generates a freely oscillating one Oscillator (1) dease a high-frequency? / Echselvoltage (18) of high frequency constancy Frequency the shortest range of the time base deflection voltage to be generated (28) and the time intervals between the gradually selectable MeBabo sections are determined and which is then selected. In a stage (2) the generated alternating voltage is deformed into a square-wave pulse voltage (19). Control of the following four The bistable frequency divider (3t 4, 5, 6) co-kept in a cascade takes place from the negative Edge of the pulse voltage (19) from stage (2).

The output connections of the bistable frequency divider (3t 4, 5, 6) square-wave pulse voltages are different, divided from the mother frequency Frequencies (20, 21, 22, 23), taken in a known manner from a decoding matrix fed and brought into coincidence in this circuit arrangement in such a way that on square-wave pulse voltages (24, 25) can be taken from the output terminals. The extraction of the square-wave pulse voltages for the synchronization of the time base breakover voltage generator takes place via two switch levels (8 and 9) on their wipers rectangular pulse voltages (24 and 25) can be seen, their mutual temporal distance of the width of the Square-wave pulse voltage at the first bistable frequency divider or a multiple Time corresponds to this width, since the time shift of switch position to switch position of both switches from tap to tap on the decoding matrix, thus corresponds to the width of the rectangle at the first bistable frequency divider.

The rectangular pairings taken from switches 8 and 9 are shown in the AND-gates (10 and 11) brought into coincidence with pulse voltages that of the alternating voltage of the L: utter generator. Become this way for the synchronization of the time-based breakover voltage generator pulse voltages with steep, well-defined leading edge gained.

The time base breakover voltage generator (12) is divided so that by switching measures known per se include a linearized charging or discharging (28) of a Capacitor by which the orate sync signal (26) (start) is triggered.

When the second signal (27) (stop) arrives, the loading or Discharge process (28.) stopped and the voltage on the capacitor very quickly switched back to the original value. The time constant of the charge hold is adapted to the desired sawtooth time and determines the sawtooth amplitude. These Eigenart can be used to adjust the amplitude of the generated time base breakover voltage will. The orseugte Kippa voltage is fed to the Braunsohen pipe (13). For the Light scanning of the electron beam on Braun's tube (13) is ton of the sawtooth time a square-wave pulse voltage is diverted.

The pulse generator (15) is controlled from the first tap the decoding matrix (7). To improve the precise timing of the pulse voltage becomes the Reohteck pulse voltage taken from the Deoodier matrix in dom AND gate (14) with an alternating voltage derived from the alternating voltage generated in the basic generator (1) Impulse voltage with steep leading edge brewed in coincidences. The transmit pulse (29) reaches the line to be examined via the hybrid circuit (16) and becomes simultaneously brewed on the Braun tube (13) for display.

If there are reflection points in the conduit, a part will be the pulse energy is reflected and reaches the hybrid circuit (16), the transit time shifted accordingly, on the Braun tube for display.

The error distance is determined by reading the on the Decoding matrix (7) set delay of the use of the time deflection against the transmission pulse and duroh addition of the time from the beginning read on the Braun tube the light line to the base of the echo pulse.

The circuit arrangement according to FIGS. 3 and 4 is a variation of the Sohalteanordnung according to the invention according to Fig. 1 and Fig. 2. The circuit arrangement is completely identical to the arrangement according to FIG. 1 up to the decoding matrix.

The arrangement of the oscillator (30), the stage 31 and the bistable Frequency divider (32, 33, 34 and 35) is identical to the circuit arrangement according to Fig. 1.

A variation consists in the arrangement of the decoding matrix. The synchronization character (54) for the triggering of the time base voltage generator is controlled by a fixed Tap (39) taken from the decoding matrix 36.

For switching back the time base voltage generator (43) a square-wave pulse voltage (55) via the switch (37) optionally from one of the Agriffe selected on the decoding matrix (36). The operating points of the switch 37 square-wave pulse voltages taken (55) are against the point of use the square-wave pulse voltage (54) us taken from tap 39 is the period duration or their multiples of the alternating voltage (48) generated in the basic generator (30). The saw tooth voltage (58) sucked in the time base breakover voltage generator (43) arises in the time set on switch 37. PUr the control of the transmit pulse generator (45) a Reohteok pulse voltage (59) is taken from the decoding matrix (36), their temporal position against the point of use of the time-lag voltage generator (59-58) by selecting a corresponding tap on the Deoodier matrix with the switch 38 can be moved in stages.

The at the tap 39 of the Deoodiermatrix and at the switches 37 and 38 square-wave voltages are drawn before the continuation to the controlling assemblies in the AND gates 40, 41 and 42 in a known manner with a derived from the positive voltage generated in the basic generator (30) Pulse voltage with steep leading edge (49) brought into coinsidence, whereby a Improvement of the timing accuracy achieved when the mentioned control character is used will.

Claims (5)

Claims: 1. Circuit arrangement for the control of a breakover voltage generator, in particular for generating the deflection voltage for the cathode ray tube in pulse devices, in the known manner by frequency division of a mother frequency and Decoding of the voltages of the individual divider stages, a decoding matrix over time impulses that can be displaced in relation to each other are taken in fixed steps for the purpose of exhaustion of the transmission pulse are also used for the tilting process, characterized in that both the rising point and the tipping point of the sawtooth voltage through one each Impulse from the decoding matrix with a mutual time interval that can be selected in steps triggered and thus determined by the frequency of the mother generator. 2. Circuit arrangement according to claim 1, characterized in that the transmission pulse triggered by the first pulse coming from the decoding matrix is, while the impulses determining the rise point and the tipping point are separated Switch selectable connections of the decoding matrix can be taken, so that both the time between the transmission pulse and the point of rise of the tilting process as well as the time span between the rise point and the tipping point in terms of the frequency levels derived from the mother generator can be selected by hand. 3. Circuit arrangement according to claim 1 and 2, characterized in that that the impulse determining the rise point of the tilting process has a fixed connection is taken from the decoding matrix, while the pulse voltage that triggers the transmission pulse is taken from a connection of the decoding matrix that can be selected by a switch, which is before the mentioned fixed connection, during which the tipping point is determined Pulse is taken from a connection also selectable by a switch, the laterally after the fixed connection mentioned. 4. Circuit arrangement according to claim 1, 2 and 3, characterized in that that to improve the timing accuracy when using the pulses for the s of Tilting process and the transmission pulse, the square-wave voltages taken from the decoding matrix in AND gates with pulse voltages derived from the prequing of the matter generator be brought into coinsidence with the steep leading edge. 5. Circuit arrangement according to claim 1, 2, 3 and 4 for the application in pulse reflection devices with which the reflection distance in electrical lines Roll can be measured at different running speeds, characterized that the frequency of the mother generator is set and adapted to the running speed of the measurement object is adapted so that the Hutter frequency for the control of the transmission pulse and the tilting process derived time segments powers of ten represent the unit of measurement (meters, miles) used for distance measurement.