DE1952956A1 - Stroboscopic instantaneous value meter for periodic electrical signals - Google Patents

Description

STROBSCOPIC TORQUE METER FOR PERIO-DIC ELECTRIC SIGNALS The present invention relates to electrical measuring devices, in particular on a stroboscopic instantaneous value meter for periodic electrical signals, as he did for the investigation of stationary and transient processes in electronic Circuits for the automatic testing and control of - solid-state circuits and circuits with lumped elements for measuring the statistical if values from measuring and control devices (generators, oscilloscopes) and: automatic Recording of the dynamic characteristics of semiconductor devices for the purpose of later simulation and recalculating their ratio used on electronic calculating machines is, The stroboscopic measuring devices for instantaneous value measurement on periodic electrical Signals are in themselves for example in the form of stroboscopic telescopes known. With these measuring devices, the measuring signal is applied to one input of a gate circuit given whose other input is acted upon by the pulses of a gating generator will. The output pulses of the gate circuit are amplified in a pulse amplifier.

The gating generator is triggered by a comparison circuit, one input of which is assigned to a sawtooth generator, which at the moment is triggered where the eJ3signal arrives at the input of the gate circuit.

At the other input of the comparison circuit, the instantaneous value measurement A sawtooth control voltage is applied to the incoming signal in the oscilloscope, which causes a time shift of the gating pulses compared to the measuring signal. The gate circuit is also supplied with a bias voltage.

The output signal of the pulse amplifier becomes the vertical deflection of the electron beam in the cathode ray tube and for forming the analog Feedback voltage used. This voltage is used as a bias voltage at the gate circuit input and also as a measurement result on the input of an analog-digital converter given in order to obtain the instantaneous value of the signal voltage in numerical form. the The control voltage of the timing pulse shift serves as the horizontal deflection voltage for the electron beam in the cathode ray tube and is generated by the sawtooth generator generated. The digital instantaneous value of the time is obtained by counting from Impulses that arrive at the input of this generator.

The disadvantage of known measuring devices of the above-mentioned type lies in the impairment of the measurement results by many subjective factors, such as accuracy the readings on the screen of the cathode ray tube, and objective factors, like non-linearity of the vertical deflection of the metal electron beam tubes, the one Pulse amplifiers contain slow zero point drift in this pulse amplifier and with the touch-up generator, time shifting of touch-up pulses, linearity the sawtooth separating voltage for the keying pulse shift, own noises of the Measuring circuit (which is particularly important at lower levels and high rates of change of the measuring signal is of great importance).

In addition, there is known stroboscopic oscilloscope with digital display the analog-to-digital converter is not in the feedback branch, which provides the bias voltage for the Gate circuit leads 0 The gain factor of this branch, which must be 1, becomes set by hand. This results in a dependency of the measurement accuracy on the number of sampling points of the measurement signal and the temporal constancy of the gain factor the pulse amplifier and the other elements of the feedback.

The well-known stroboskoposzillographen do not allow the'selfactiv Measurement with high accuracy of several instantaneous values of a signal with simultaneous Implementation and display of the measurement results in digital form. So much for us exist, In addition, there is currently no known stroboscopic oscilloscope that directly couple with an electronic calculating machine and thereby a machine control of the measuring process can be realized.

It is the aim of the invention to provide a stroboscopic instantaneous value meter for periodic electrical signals with the disadvantages mentioned be avoided.

The invention is based on the object of a stroboscopic To develop instantaneous value meters for periodic electrical signals in which the Accuracy of measurement neither from subjective nor from objective factors, such as non-linearity and slow zero point migration in the pulse amplifier temporal inconsistency of the Data of the gating generator, non-linearity of the control voltage for the gating pulse shift, Setting accuracy and temporal inconsistency of the gain factor of the gate circuit feedback and own noises of the measuring circuit, is influenced and one is fully automatic can realize running measuring process.

Another object of the invention is to develop a stroboscopic one Instantaneous value meter for periodic electrical signals in which the measuring time is shorter than with known facilities of this type and the measurement results in digital Form printed via a printer or directly into an electronic calculating machine can be entered.

The task at hand is performed by a stroboscopic instantaneous value meter solved for periodic electrical signals, in which the measurement signal on the one Input of a circuit is given, the other input with the output pulses a gating generator is applied and at its output a pulse amplifier is switched on The gating generator is triggered by a comparison circuit, one input of which is connected to a sawtooth generator. According to the invention the instantaneous value meter is triggered synchronously with the sawtooth generator digital arithmetic unit, with two of these assigned and corresponding to the comparison circuit and code-voltage converters connected upstream of the gate circuit and a pulse amplifier Downstream and the digital processing unit upstream zero indicator added.

According to the invention, the digital arithmetic unit contains a parallel one Coincidence adder with two summation registers. At the first summand register a storage register for intermediate results, a storage register, are connected in parallel for ei3size mean values, a storage register for the compensation code of the current Time quantity, a storage register for the compensation code of the measuring voltage and a Storage register for the number of measurements. At the second summand register a measured value collecting register, another storage register for intermediate results, a shift register for the formation of the coded increases in the Compensation quantities and the input register connected.

The two storage registers are at the output of the coincidence adder for intermediate results, the memory register for the compensation code of the current Time size1 the storage register for the compensation code of the measurement voltage, the storage register for the number of measurements and the measured value collection register. It is beneficial to that Keßwertsammelregister via valves the storage register for measured variable mean values, the storage register for the compensation code of the current time quantity the code-voltage converter and the storage register, which is superordinate to the comparison circuit for the voltage compensation code, the code-voltage converter above the gate circuit assign.

The idea of the invention is illustrated below using a few exemplary embodiments explained in detail with reference to the accompanying drawings. Bs shows: Fig. 1 the stroboscopic instantaneous value meter according to the invention for periodic electrical Signals in a block diagram; 2 shows the structure of the digital arithmetic unit of the measuring device according to FIG. 1.

The stroboscopic instantaneous value meter periodic electrical Signal. contains a. Touch-up unit 1, a computing unit 2 with two code-voltage converters 3, 4 and a zero indicator 5. The touch-up unit 1 sits down from a gate circuit 6, a pulse amplifier 7, a gating generator 8, a Comparison circuit 9 and a sawtooth generator 10 together. An external control generator 11 ensures the synchronization of the touch-up unit 1 with the computing unit 2. The generator 11 also serves to trigger the object 12 to be tested.

The touch-up unit 1 has an output 17 and four inputs 13, 14, 15, 16 namely the input 13 for Synchronisadas tion pulses, the input 14 for Wseßsignal, the entrance. 15 for the control voltage of the time shift of On the strobe pulses and the input 16 for gate control voltage.

The digital processing unit 2 has an input 18 for synchronization pulses, an input 19 for the feedback signal and two outputs 20, 21.

The external control generator 11 has an output 22 for synchronization pulses and a main exit 23.

The input 13 of the touch-up unit 1, which is also the input of the sawtooth generator 10 is the synchronization output 22 of the external control generator 11 sugeordnot. The measurement signal is picked up at the output of the test object 12 and The gate circuit 6 is supplied via input 14. The input 15 for the delay The control voltage that is influenced by touch pulses is the code-voltage converter 4 and also serves as the input of the comparison circuit. Of the Control input 16 of the gate circuit is assigned to the ISode voltage converter 3 and serves as the bias input of the gate circuit. At output 17 of the touch-up unit, der.also the output of the pulse amplifier.? is, the zero indicator is 5. The The second input of the comparison circuit 9 is assigned to the sawtooth generator 10. At the output of the comparison circuit 9 is the gating generator 8, at its output the gate circuit 6 is connected to its input branch. At the exit of the The pulse amplifier 7 is the gate circuit.

The input 18 of the digital arithmetic unit 2 is the synchronization output 22 of the external control generator the 11 and with the input 19 for feedback signal assigned to zero indicator 5. At outputs 20, 21 of the arithmetic unit 2 are correspondingly the code-voltage converters 3, .4 with their inputs.

That is to be examined at the main output 23 of the external control generator 11 Object 12 connected.

2 shows the structure of the computing unit 2.

The digital arithmetic unit is made up of a parallel one Coincidence adder with two summand registers 25, 26, one storage register 27 for intermediate results, a storage register 28 for b flow size mean values, a storage register 29 for the coded compensation quantity for the current time, a storage register 30 for the code of the compensation voltage, a storage register 31 for the number of the measurements, a collection register 32, another Storage register 33 for the intermediate results, a shift register 34 for formation of encoded increments of compensation sizes, a memory register 35 of the Code-voltage converter 4 and the input registers 36, 37, 38, 39.

The inputs of the coincidence adder 24 are the outputs of the Assigned summand register. At the input of the summand register 25 are parallel the outputs of the first storage register 27 for intermediate results, the storage register 28 for measured variable mean values, of storage register 29 for the coded compensation variable the current time, the memory register 30 for the code of the compensation voltage and the memory register 31 for the number of results.

At the input of the summand register 26 are parallel with their outputs the summing register 32, the second storage register 33 for intermediate results, the SchieberEgister 34 and the input registers 37, 38, 39.And the output of the Koinzi and denz adder 24 are the two storage registers 27 32 for intermediate results, the storage register 29 for the coded compensation variables of the current time, the storage register 30 for the voltage compensation code, the number of storage registers 31 for the measurements and the measured value collection register 32 connected with their inputs. The input of the storage register 28 is at the output of the last-mentioned register connected via a group of valves 40 for the measured variable mean values. Of the Output of the storage register 29 for the coded compensation quantities the current time is at the input of the memory register 35 of the code-voltage converter 4 connected. The input register 36 is at the input of the shift register 34.

The control unit of the digital processing unit 2 is not shown in FIG. 2 shown, since it plays a subordinate role for the idea of the invention. The control unit has the task of depending on the control impulses according to certain algorithms of the incoming information via the return input 19 of the digital computing unit 2 to create. The control unit is activated by the synchronization pulses arriving at input 18 triggered. The control signals are sent to the control inputs of the register valves (not shown) and cause the opening of the same and the jump of the dual encrypted Numbers between the registers and between the coincidence adder and the registers.

The stroboscopic instantaneous value meter for periodic electrical Signals has the following mode of action: The one generated by the external control generator 11 The synchronization pulse triggers the sawtooth generator 10 and the digital arithmetic unit 2 off. The main signal of the control generator 11, which is opposite to the synchronization pulse is delayed in time, arrives at the entrance of the examined object 12. The Reaction of object 12, i.e. the measurement signal, reaches the gate circuit via input 14 6th

The saw tooth generator 10 generates a linear changing Tension. This voltage is applied to one input of the comparison circuit during the second input of the same one generated by the code-voltage converter 4 Control voltage E1 is supplied for the pulse delay.

At the moment when the difference between the two tensions pale the response threshold of the circuit 9, this generates a coincidence pulse. This triggers the gating generator 8 with its flank. The output pulse of this The generator arrives at the input of the gate circuit 6. At the bias input 16 the gate circuit is the control voltage E2 generated by the code-voltage converter 3 created.

The gate circuit 6 generates from the three input signals, namely a mixture of the gating pulse voltage, the measuring signal voltage and the bias voltage or a modulated voltage signal that appears at the output of the gate circuit.

This signal has a steep leading edge and an extended trailing edge. The amplitude of the gate output signal is in the pulse amplifier 7 by required number increased.

The output signal of the pulse amplifier 7 reaches the input of the zero indicator 5. This represents a threshold value circuit that responds as soon as the signal amplitude at the amplifier output has reached a certain constant voltage level, which is considered to be the output zero level. The output zero level practically falls with the threshold value of the zero indicator 5 together. This tension value, which at Preset the circuit is set, one selects so, that a distance from the interference signal at the output of the pulse amplifier 7 is guaranteed will. Depending on <reached whether or not reached> the signal amplitude am Output of the pulse amplifier 7 the zero level, <> generates the zero indicator 5 an "over" or an "under" signal. The zero indicator thus sets the analogue Voltage signal of the pulse amplifier 7 into a discrete signal (with two values "Over" and under ") and fulfills the task of an analog-digital converter.

The output signal of the zero indicator 5 is from the control unit of the arithmetic unit 2 recorded and processed as a discrete signal with the values 1 and 6. Of the The value of this signal determines the operation which is carried out with the at the inputs of the Code-voltage converter 3, 4 pending coded variables from the arithmetic unit 2 is performed.

Let us denote the coded quantities at the input of the code-voltage converter 3, 4 or at the outputs 20, 21 of the digital computing unit 2 with the symbols x and t. These quantities are treated as follows.

One of the quantities x, t is considered to be an independent variable (das Argument) and is used for the time of execution of all operations with the second Size recorded. The other variable is used as a dependent variable (or as a function value of the chosen argument). bAit keeping the size t at the entrance of the code-voltage converter 4 is the position (or the delay time T) of the gating pulses opposite to the measurement signal clearly defined. The code t = 0 is given a delay time g = 0 assigned to the gating pulses compared to the beginning of the sampling of the measurement signal. At the input of the code-voltage converter 3, an initial code xo is set, the corresponds to an initial bias E20.

It is now assumed that the first signal at the output of the zero indicator have the value 1. This means that the initial value of the prespaxing at the moment the sampling is smaller than the instantaneous value of the signal voltage to be measured.

To improve the compensation of the measuring voltage by the bias becomes the coded initial value xO by adding an increment to the initial value 0 corrected.

This correction is made by the digital arithmetic unit 2.

guided. At the input of the code-voltage converter 3 appears a new code x1 = x0 + # 0 and at the output of the same a new bias voltage E21 = B20 + # E20, where E20 is the increase in preload after the first correction.

The increasing bias at the input of the Torschaltupg 6 causes a reduction in the signal amplitude at the output of the amplifier 7 upon repetition the signal mixing during the next cycle or the next time the measurement signal arrives via input 14. Is the pulse amplitude at the input of zero indicator 5 still above the zero level (the response wave) the value of the indicator output remains signal is still the same as before 1. Otherwise, the output ,, ang of the zero indicator 5 a signal. If the first is the case, another correction is made of the code xO by adding the coded increment with the initial value # O performed. The result is x2 = x1 + # 0 = x0 +2 This correction is made by the digital Computing unit 2 repeated during each period of the measurement signal until the Zero indicator 5 a reduction in the signal amplitude at the output of the pulse amplifier 7 reports below zero level by generating an O signal.

The signal value change at the output of the zero indicator 5 shows that that the instantaneous value of the measured signal voltage at the moment of scanning the preload E2k = E20 + k # E20 (k = 1, 2, 3 ....) is exceeded.

To further adjust the coded variable x through the preload To enable E2, a new coded increment is made by halving the original one Value # o calculated by arithmetic unit 2: # 1 = ## The new increment # 1 is now subtracted from the size xk.

It surrenders In each further adjustment cycle of the coded variable x, the increase is reduced again by halving and, depending on the signal value at the output of the zero indicator 5, is added to the code x and subtracted from it. Bs results The compensation of the code x by the corresponding.

Preload E2 is ended with the execution of the latter correction, where the coded increment ß m equals a 1 in the last position (# m = 000 ... 0001, m - the number of standard cycles of the adjustment process).

The above statements show that in the gate control the touch-up unit 1 of the proposed stroboscopic instantaneous value meter an automatic return is effective. This feedback is via gate circuit 6, pulse amplifier 7, zero indicator 5, digital arithmetic unit 2 and the code-voltage converter 3 closed on gate circuit 6.

The feedback causes the signal amplitude at the output of the pulse amplifier 7 strives for the assumed zero level (response threshold of the zero indicator 5), while the total increase in preload is the difference between the value to be measured Signal voltage at the moment of sampling and the initial value E20 of the bias voltage approaching.

To determine the instantaneous value of the measured signal voltage in any given point in time to allow s and the disruptive effect of slow To avoid zero point migration of the elements of the touch-up unit 1, sees the digital processing unit 2 underlying algorithm the alternating formation the codes x (o) and x (ti) for two values of the code t, namely for t = o and for t = ti, where ti is the default code. These codes correspond to the times T = o and 2 = Ti. The difference is y (ti) = = x (ti) - x (o) (i = 1, 2 .... is the serial number of the time interval) is calculated. This difference applies further on as an encrypted actual value of the signal voltage to be measured at the point in time. Ti. The The total increase # E2 (Ti) in the preload corresponding to the code Y (ti) is considered to be the instantaneous value the signal voltage to be measured in relation to the input reference voltage, which is the zero level applies and corresponds to the code x (o).

The value of # E2 (Ti) is obtained by simply multiplying the code y (ti) with the value of the lowest digit of the code-voltage converter 3 is determined. The stroboscopic instantaneous value meter enables the periodic electrical signals Thus, in its first mode of operation, the measurement of a voltage value for a given Points in time or for a given delay of the keying impulses.

If the code x is now held at the input of the code-voltage converter 3, a certain voltage level is thus specified at the input of the gate circuit 6, to which the code y - x - x (o) of an actual value of the signal voltage to be measured is assigned . An initial code to = 0 is set at the input of the code-voltage converter 4. The first signal appearing at the output of the zero indicator 5 causes the addition of the encrypted initial increase fl to the code t0 t1 = t0 + # 0 = # 0 regardless of its value Signal value at the output of the zero indicator is the only control character. If the output signal of the zero indicator 5 retains its original value after the first adjustment operation with the code t, the respective operation is repeated each time the measurement signal arrives until the zero indicator changes the value of its output signal. The result is t2 = tl + + o = 2 tk = tk-1 + # 0 = k # 0, k = 1.2 The signal value change at the output of the zero indicator 5 is evidence of an overcompensation in which the value corresponds to the input voltage level specified at that time Time coordinate of the delay time Tk of the keying pulses, which corresponds to the code tk, is exceeded. To continue the compensation, the original coded increment # 0 is halved by the digital arithmetic unit. The new increment ß ° is deducted from the code tk. It surrenders In each subsequent calibration cycle, the increase is reduced by halving and, depending on the signal value at the output of the zero indicator 5, is added to or subtracted from the code t: The processing of the code t and the determination of the corresponding delay time T of the keying pulses are ended with the last correction in which the encrypted increment # m is equal to a 1 of the lowest digit (#m = 000 .... 001).

The above statements indicate that in the proposed stroboscopic Instantaneous value meter for periodic electrical signals an automatic feedback effective in the control of the pulse delay on the input of the Comparison circuit 9 of the touch-up unit 1 is fed back. This repatriation will from the comparison circuit 9, via gating generator 8, gate circuit 6, pulse amplifier 7, zero indicator 5, digital arithmetic unit 2, code-span- 'dre voltage converter 4 again led to comparison circuit.

The feedback causes the signal amplitude at the output of Pulse amplifier 7 the assumed zero level (the To stretches while si response threshold of the zero indicator 5) strives, during the delay time of the Auftastimpulse, the after running through the full adjustment cycle for the code t, the result is that of the specified Input voltage level approximates the corresponding value of the time coordinate. With this one Value of the time coordinate, the signal voltage reaches the preset level.

The delay time of the gating pulses is determined by simple multiplication of the code t (y) with the value of the lowest digit of the Sode-voltage converter 4 amazing.

In its second operating mode, the proposed one enables stroboscopic instantaneous value meter for periodic electrical signals the measurement the time coordinate at which the signal under investigation reaches the specified level.

In order to increase the measuring accuracy, namely to reduce the random errors when measuring the instantaneous value of the signal voltage examined, the codes x (o) and x (ti) are processed several times for the same code ti. The measured value is then given as the mean value y (ti) according to the relationship where N is the number of measurements.

The automatic measurement of several instantaneous values of the examined signal voltage in a time interval is carried out by successive temporal shifting of the keying pulses by adding the coded increment #t, to which Rode t is carried out by the digital arithmetic unit 2. Bs then results in ti + 1 = ti + # t The accuracy of the time coordinate measurement on the examined signal is increased by repeatedly calculating the code tj (y) while the code x remains the same. The measured value is the mean value according to the relationship Before starting the instantaneous value measurement on the examined signal, initial data are entered into the digital arithmetic unit 2 via the input registers 36, 37, 38, 39. When entering information by hand, the input registers can be made up of mechanical two-pole changeover switches (toggle switches).

When measuring the instantaneous value of voltage (first operating mode of the instantaneous value meter for periodic electrical signals) the encrypted Initial value of the increment # 0, at input register 37 the initial code xO of the voltage, the code of the time variable t at the input register 38 and the encrypted code at the input register 39 Increment # t of the time size set. The one set on the input register code t determines the time coordinate of the signal value to be measured (or the delay time of the gating pulses) if the instantaneous value of the signal voltage is only at one point in time is to be measured. However, several instantaneous values of the signal voltage are to be measured the time interval in which the measurement is carried out becomes with the code t, and with the time interval between the code #t set at the input register 39 the successive measured values or the time delay of the successive Pre-set pulses against each other. The number of readings to be repeated (the number of averaged measured values) is at the input register of the control unit is set, which is not shown in FIG.

The remaining registers of the digital arithmetic unit are activated by pressing the corresponding key (not shown) is set to zero (deleted).

The constant value for periodic electrical signals is triggered by the synchronization pulse of the external control generator 11. The measurement begins with a general preparation cycle, during which the output data set at the input registers is transported from the digital processing unit into the operative storage register. The encoded initial value x0 of the voltage is transferred from the input register 37 to the registers 27, 33 for intermediate results. This operation is carried out by adding the code X0, which is transferred from the binary input register 37 to the summand register 26, with the encrypted zero, which is stored in the other summand register 25, and then transferring the result from the coincidence adder 24 in the storage registers 27, 33 for Intermediate results. The content of the input register 38 (the code t) is only transferred to the storage register 29 for the compensation code time variables in the B6lle if the instantaneous value of the voltage is to be measured only for a predetermined point in time. This information transport also takes place via coincidence adder 24.

After the general preparation cycle comes the first cycle of Operations whose task is to prepare for the determination of the coded zero level x (o) is. During this cycle the code x0 is obtained from the second storage register for intermediate results 33 via coincidence adder 24 into the storage register 30 for the voltage compensation code. The coded initial increment # 0 is transferred directly from the input register 36 to the shift register 34.

After the completion of this preparation cycle, a series begins of standard adjustment cycles during which the coded zero level is adjusted. In each adjustment cycle, the content of the memory register 30 contains the compensation code the voltage is stored, the content of the shift register 34 is added or of deducted from this. The contents of the shift register will each ilal towards shifted to the lower digits when the output signal of Zero indicator 5 changes its value to the opposite one. The addition will by transferring the contents of the registers 30, 34 accordingly into the summand registers 25, 26 executed in the directo code. The subtraction is done in the same Way, but the content of the shift register 34 in the summand register 26 .im inverse Code is transmitted.

The results of the operations come from the coincidence adder 24 again into the storage register 30 for the compensation code of the voltage. the The series of standard adjustment cycles ends when the contents of the shift register 34 becomes zero.

After the end of the adjustment cycles, the first final cycle takes place triggered, during which the calculated Kodas de x (o) via coincidence adder is transferred to the second storage register 33 for intermediate results. This Register is set to zero beforehand.

After the completion of the first final cycle of the adjustment process for the zero level x (o) follows the second preparation cycle, the task of which is the Preparation for determining the code x (ti) is. During this cycle the encoded initial value of the increment A O again from the input register 36 into the Shift register 34 transferred. The time size code is taken from the memory register 29 for the compensation code of the time variable directly into the memory register 35 of the code-voltage converter 4 transmitted. The content of the first storage register for intermediate results, the following is entered via coincidences: -lddierelement 24 in the memory register 30 dsn compensation code surrendered to the tension. After execution The series of standard calibration cycles begins during the second preparation cycle which the code x (ti) is determined, with each standard cycle carried out in the same way becomes, as when determining the code x (o).

The series of standard adjustment cycles ends with the second final cycle. The calculated code xcti)) is stored in the first memory register via the coincidence adder 24 27 for S. wipe results transferred. Then the coded real voltage value becomes y (ti) by subtracting the encoded zero level x (0) from the code x (ti) certainly.

For this purpose, the content of the memory register 27 is written to the direct code in the Addend register 25 and the content of register 33 are inverse code in the addend register 26 passed. The result of the operation comes from the coincidence adder 24 for temporary storage in register 30. The next operation exists in the collection of values. The content becomes the content of the collective register 32 of the register 30 is added taking into account the sign and the sum is sent back from the coincidence adder 24 into the collection register 32. The measured values are then counted by increasing the content of register 31 by 1 will. For this purpose, the encrypted number of measurements is entered in register 31 in the summed register he 25 is transferred and a 1 is stored in the lowest digit of the summand register 26. The result comes from the coincidence adder 24 again into register 31 and into the control unit.

In the control unit, the encrypted number of measured values is compared with the am Input register set code N of the specified number of measured values to be averaged compared in places.

if the two codes match, the control unit generates a start signal for the general graduation cycle. But it is the specified number of measured values has not yet been reached, the next series of adjustment cycles for the Code x (o) and x (ti) triggered.

During the general closure cycle, the encoded one becomes the real one Average value Y (ti) of the measured signal voltage calculated. This task is accomplished by the content of the collecting register 32 in the storage register 28 for mean values with a simultaneous shift by the amount corresponding to the specified number N of measured values Number n transferred from number of digits n. For this purpose, the number N is chosen equal to 2n. Of the Code transport with simultaneous shifting by n places takes place via valves 40, which are opened by control signals.

The measurement results are in the form of dual encoded numbers ti and yl (ti) are output from registers 28, 29.

These values can be printed out via a printer, directly into a electronic calculating machine entered or in the control register of an additional Code-voltage converter stored and in the form of a diagram on two-coordinate recorder be registered.

The general closing cycle ends with the comparison of the time interval, in which the Iivesauagen were carried out, with the specified time interval, after which possibly the time coordinate of the next value to be measured of the signal under investigation is calculated. The time interval is checked by subtracting the specified Code t, from the code ti of the current time. For this purpose, the content is that of the memory register 29 for the compensation code of the time variable in the direct code in the summand register 25 and the contents of the input register 38 in the inverse code in the summand register 26 transferred. The sign code of the result comes from the coincidence adder into the control unit, which generates a signal to interrupt the measurement? if the Time difference is positive. But if the sign of the time difference is negative, so the control unit continues the measuring process. In this case it will be the next time coordinate calculated by adding the coded excess #t to the code ti.

For this purpose, the content of the storage register 29 is used for the compensation code the time variable in the summand register 25 and the content of the input register 39 transferred to the summand register 26. After all operations of the general The final cycle has been carried out, the next series of standard calibration cycles begins, in which the instantaneous values of the measured signal voltage are measured.

When measuring time coordinates with the proposed instantaneous value meter (Become a second operating mode of the food processor at input register 36 the coded initial value & O of the increment, at register 37 the code y for the Actual value of the input voltage level and the encrypted tone at registers 38, 39 Zeros set. The number N of measurements to be repeated (the number N of the averaged Measured values) is set in encrypted form at the input register of the control unit.

The instantaneous value meter for periodic electrical signals is provided by the Synchronization pulse of the external control generator 11 triggered. The measurement begins with the general preparation cycle, during which the set output data be transported from the digital processing unit 2 into the operative register. This cycle is carried out in the same way as in the first operating mode, which is described above.

The general preparation cycle is followed by a series of standard adjustment cycles for calculating the coded zero level .x (o), which is carried out in the same way as in the first operating mode of the instantaneous value meter.

After determining the code X (0), the second preparation cycle begins, whose task is the preparation for the determination of the code t (y). During this The coded increment ß o from the input register 36 into the shift register becomes one cycle 34 transported. The given encoded real value y of the voltage level is added to the code x (o) of the zero level. The content of the first Storage register 27 for intermediate results in the summand register 25 and the content of the second Storage register 33 for intermediate results is transferred to the summand register 26. The result of the addition comes from the Loincidence adder 24 in the memory register 30 for the voltage compensation code.

After the second preparation cycle, the series of standard adjustment cycles begins for calculating the code t (y).

During each alignment cycle the contents of the memory become the register 29 for the compensation code of the time variable, the contents of the shift register 34 are added or subtracted from it.

The contents of the slide register are changed each time the signal value is changed at the output of the zero indicator 5 shifted in the direction of the lower digits. The addition and subtraction of the codes t and A takes place in the coincidence adder 24. The resulting sum or difference is stored in the storage register 29 for Compensation code of the time variable, from which it is stored in the memory register of the code-voltage converter 4 is passed. The series of. Adjustment cycles for t (y) ends when in the shift register 34 the groove code appears.

When the series of standard adjustment cycles has ended, the second final cycle. The measurement results are collected during this cycle namely, the content of register 29 is added to the content of register 32 and the result is saved back in the collection register. Then the number becomes calculated from the measurements carried out and with the given number N compared. This operation is carried out in the same way as in the first operating mode of the instantaneous value meter. Is the calculated number of correct Measurements correspond to the specified number N, the control unit conducts the general Closing cycle. But if the number of measurements performed is less than that given number N, the control unit triggers a start signal for the next series of calibration cycles for the codes x (o) and t (y).

During the general closure cycle, the code t (y) becomes the mean value the time coordinate is calculated by placing the contents of the collecting register 32 in the storage register 28 for mean values with a simultaneous shift of n digits depending on the number of the measurements N is transported, the number N = 2n being chosen. The information transport with simultaneous shifting takes place via valves 40, which are controlled by control signals be opened.

The measurement results are taken from register 28 as mean value t (y) output with dual encryption. The specified Rode is transferred to the input register 37 taken. These codes can be printed out on a printer or directly into a electronic calculating machine can be entered.

The advantages of the proposed measuring device are mainly " that the measurement results, which occur in digital form, are not influenced by subjective factors nor from objective factors, such as non-linearity of the pulse amplifier, slow Zero point migration of the pulse amplifier and the chamfering generator, Delay Time the gating pulses are not influenced. The collection and the averaging of measured values also enables random errors to be largely reduced. About that In addition, the two operating modes of the measuring device enable the measurement of signal values at high speed. The use of a digital processing unit for control the touch-up unit and the conversion of the measured values into digital form enables full automation the eating process and the direct coupling of the measuring device with an electronic one Adding machine.

Claims (2)

P A T E N T A N S P R Ü C H E: 1. Stroboscopic instantaneous meter for periodic electrical Signals, with a gate circuit, at one input of which the measurement signal is applied is and at the other input a Auftastgenerator-lies, and with one of the Gate circuit downstream pulse amplifier, the gating generator from the output signal a comparison circuit is triggered, at one input of which a saw tooth generator lies, g e k e n n n z e i c h n e t by synchronously with the sawtooth generator (10) triggered digital processing unit (2) and two of these downstream code-voltage converters (3, 4), one of which is the comparison circuit (9) and the other is the gate circuit (6) is connected upstream, and by a pulse amplifier (7) connected downstream Zero indicator (5), which is connected upstream of the arithmetic unit 2. 2. Stroboscopic instantaneous meter for periodic electrical Signals according to Claim 1, d a d u r c h g e -k e n n n z e i c h n e t that the digital Recheneindeit (2) a parallel coincidence adder (2v) with two summand registers (25, 26), in which the first summand register (25) has a storage register (27) for intermediate results, a storage register (28) for measured variable mean values, a storage register (29) for compensation code of the time quantity, a storage register (30) for voltage compensation code and (34) a storage register for the number of measurements in a parallel connection, while on the second Summand register (34) a collective register (32), another storage register (33) for intermediate results, a shift register (34) for the formation of coded increments of the co-compensation variables and length registers (36, 37, 38 and 39) are connected oind, the output of the coincidence adder (24) to the inputs of the memory register (27, 33) for intermediate results and the inputs of the memory register (29) for the compensation code for the time quantity, the memory register (30) for the compensation code the voltage, the storage register (31) and the measured value collecting register (34) connected is, while the collecting register (32) via valves (40) the storage register (28) for M-measured variable mean values, the storage register the (29) for the compensation code current time variable the memory register (35) of the - the comparison circuit (9) superordinate Code-voltage converter (4) and the storage register (30) for the compensation code the voltage of the gate circuit (6) superordinate code-voltage converter (3) is connected downstream are.