SU1128181A1 - Method of converting voltages with time scale transformation - Google Patents

Abstract

A METHOD FOR TRANSFORMING TEMPORARY TRANSFORMATION OF TEMPORAL SCALE, consisting of. generating strobe pulses synchronized with the voltage to be converted, strobe the summed voltage, memorizing .. instantaneous anacheny of the summed voltages at the time points of strobe, characterized in that, in order to increase the accuracy of converting complex-shaped stresses, N spaced apart the reference pulses of a given duration and synchronized with the gating pulses, summarize each of these reference pulses with the voltage to be converted, change amplitudes of the reference pulse as long as the instantaneous value § summed voltage at time gating W are equal to zero, and it is judged on the converted voltage.

Description

The invention relates to electrical measuring technology and can be used in measuring high frequency voltages.  There is a known method for transforming a voltage with a transformation of a time scale, consisting in the formation of gating pulses, synchronized with a transformable voltage, the gating of the transformed voltage by these; memory pulses of instantaneous values at the time of sampling of the high-frequency voltage and of the low-frequency voltage envelope.  PII the high-frequency voltage spectrum is transformed into a region of -LOW frequencies l J.  The disadvantage of this method is the large error in the spectrum conversion, the possibility of detecting the diode characteristics of the mixer, the nonlinearity of the diode characteristics, the instability, the duration of the strobimne pulses, as well as their amplitudes.  In addition, the temperature per error is directly included in the result of the conversion.  The closest to the proposed method is a transformation with a transform of a time scale, concluded in the formation of gated pulses, which is synchronized with a transformed voltage, and formed.  the reference level of the pitch, the frequency. and a form coinciding with a low voltage generated by voltage and synchronized with it, its summation with the voltage being transformed, and strobe the summed voltage for. remembering the instantaneous values of the alternating voltage at the time of strobing and, at the same time, enveloping the transformed low frequency V total voltage, changing the amplitude and phase of the reference voltage relative to the converted low frequency voltage, until the instantaneous values of the summed voltage equal to zero, while the zero values of the summed voltage are equal to zero, while the instantaneous values of the summed voltage are equal to zero, the instantaneous values of the summed voltage, equal to zero, will not be equal to zero. at time gates C 2. 3  The disadvantage of this method is that it is very difficult to convert a high-frequency stress of a complex form, since it is necessary to form a low-frequency reference voltage, which coincides in shape with the high-frequency voltage to be converted.  To convert high-frequency voltages by a known method, it is necessary either to know the shape of the voltage being converted, which is not always possible, or to Transform the high-frequency spectrum of the voltage being converted into a low frequency region by a stroboscopic converter.  Further, at a low frequency, it is not very difficult to form a reference voltage that coincides in shape with the transformed high frequency spectrum in the low frequency range.  However, this sharply reduces the accuracy of the conversion, as well as in the result of the conversion. there will be an error in the transformation of the high-frequency spectrum of the voltage being transformed into the low-frequency region, t. e.  the error of the stroboscopic converter.  The purpose of the invention is to increase the accuracy of conversion of complex shaped stresses.  The goal is achieved by the fact that, according to the method of transforming for-voltage with the transformation of the time scale. Taba, consisting in the formation of gating pulses, synchronously. Converted voltage, gating the summed voltage, storing instantaneous values of the summed voltages at the time of gating, form N time-separated reference pulses of a given duration and synchronized with the gating pulses, summing each of these reference pulses with the transformed voltage. , the amplitudes of the reference pulses are changed until -, - noica.  the instantaneous values of the summed voltage at the time points of gating will not be zero, and the voltage to be transformed is judged by them.  FIG.  I presents timing diagrams explaining the essence of the method; in fig.  2 is a block diagram, a device implementing the method; in fig.  3 is a diagram of a synchronization unit.  . The method is carried out as follows.  For the transformation of the high-frequency spectrum into the low-frequency region 3, strobe pulses of short duration are formed.  N reference pulses are formed, for example, of a circularly shaped form, separated in time, equal to the period Tr.  following the strobe pulses, and with a frequency following equal to or a multiple of the converted voltage.  Moreover, the frequency of the converted voltage fg, strobe pulses f.  and the converted low-frequency j, p must be synchronized and connected by the ratio of aux.  where fi is the number of periods of Tg of the high-frequency voltage that falls within the period TC following the phase. .  pulses; Sum each formed.  the reference pulses are voltage convertible.  The summed voltage is gated by the generated pulses of short duration.  At the times of gating, instantaneous values of the summed voltage are memorized.  Changing the amplitudes of the reference pulses until those nopj until the instantaneous values of the summed voltage at the time of gating are equal to zero / zero, and the converted voltage is judged from them.  In the diagram (FIG.  lot) shows the converted high-frequency J voltage.  The dotted line shows the envelope of the low-frequency voltage, which would have been obtained by gating the transformed strobe voltage with a repetition period Tj.  (FIG.  1 b).  FIG.  Figure 1 shows N reference pulses, for example, of rectangular shape, spaced in time, equal to the period T of strobe pulses.  In addition, the period T of each of the N reference pulses is equal to the period Tn of the converted low-frequency voltage or is a multiple of it with repeated gating into one point. The duration t of the reference pulse.  equals 4trt 4 t.  Formed reference pulses of amplitude and.  summed with the instantaneous values of the converted high-frequency voltage fax -.      .  one ,. . . N  The summed voltage (Jj is gated with pulses of short duration (strobe pulses), and they are synchronized with the frequency of the voltage being converted. and generated onopfaix pulses and correspond to the relation (1).  At the time of strobing, the instantaneous value of the converted high-frequency voltage is compared with the amplitude U.  The n-ro of the reference pulse and, if they are unequal, p is measured and remembered; the effective voltage 4U (Fig.  1 E).  Next, the amplitude N of the N-ο pulse is varied until this difference voltage of the LO is zero, and this is repeated for each N-I remaining-with reference pulses. Each of the amplitudes.  and, the generated N-ro reference pulse carries information about the instantaneous value of the transformed voltage Ugj (and their envelope repeats the shape of the transformed voltage (Fig.  1 g).  The error in converting a high-frequency voltage of a complex form into a low-frequency voltage can reach tenths of a percent and consists of the error in compensating for instantaneous values of the voltage being transformed. nor the amplitudes of the generated reference pulses separated in time and at the time points of gating, however, the error accuracy is insignificant and is determined by the sensitivity of the null gorgan, as well as from the depth determined by the number of samples of instantaneous values taken in the period of the voltage being converted; To reduce this error, it is necessary to increase the number of samples.  A device for implementing the proposed method comprises a source 1 of a reference constant voltage, N controlled attenuators 2, N keys 3, an adder 4, a stroboscopic converter 5, a zero organ 6, a filter 7, a synchronization unit 8, and the output source 1 of a reference voltage wiring is connected to the inputs of controlled attenuators 2, the output of which cadcog is connected via key 3 for each of the channels, respectively, c. NM low-frequency input of the adder 4, the input of the entire device 51 is connected to the high-frequency input of the adder 4 and the input of the synchronization unit 8, the output of the adder 4 is connected via a stroboscopic converter 5 to the input of the zero signal 6, and through the filter 7 to the output of the entire device, N - the outputs of the synchronization unit 8 are connected respectively to the N inputs of the keys 3, and the output of the strobe pulses of the synchronization unit 8 is connected to the second input of the stroboscopic converter 5.  .  The synchronization unit 8 includes a mixer 9, a phase detector 10, a reference generator P, a tunable generator 12, a gate generator 13, a gate pulse amplifier 14, a differentiating chain 15, a counter 16, a decoder 17, N elements AND-OR 18, an element AND-NOT 19, delay line 20, strobe pulse generator 21, single-pole 1, N + 1) -position switch 22 and the input of synchronization unit 8 is connected via mixer 9 to the input of phase detector 10, the second input connected to generator 11, and output connected via tunable generator Op 12 and generator 13, a strobe pulse to the other input of the mixer 9, later r-th output is also connected through usilitelogranichitel 14 and differentsirun) boiling J chain 5 to the entry. Set to zero the SchmBMIC US 16, the counting input of which is connected to the output of the generator 12, and the outputs of the counter 16.  connected to the decoder 17, S outputs of the decoder 17 are connected, through the elements AND-OR 18 to the outputs of block 8. synchronization, which are in turn connected via an AND-HE element 19, link: 20 delay pho; gater 21 strobe pulses to the output of the gating pulses of the Output C of the synchronization unit 8.  . In addition, the second inputs of the AND-OR elements 18 are connected via the N poles of the switch 22 to the housing, and the third inputs of the AND-OR elements 18 are connected to each other and connected to the housing through (N + l polus).  switch 22.  In addition, for isolating circuits at high frequency at the inputs of switch 3, capacitors 23 are connected relative to the housing, and for disconnection at low frequency at the high-frequency input of adder 4 — inductance 24 (L).    On the concept of a possible implementation (FIG.  2) the output of the adder 4 is connected to its low-frequency inputs through a 25- (P, -) resistor, and a high-frequency ac - via the first additional resistor 26 (, it is connected to the jcopny с through the second additional resistor 27 (K, c); Block 8; works as follows.  .  The input high-frequency signal of complex shape and with the frequency fg followed to the input of the synchronization unit 8.  In block 8 of synchronization, pulses are formed to control the keys 3 with the frequency of the transformed voltage following, shifted relative to each other in time equal to the period of time following the gate of the strobe pulses, as well as pulses of short duration (strobe pulses) with the frequency of f. Moreover, the frequencies gjj, „p are synchronized and meet condition (1).  In order to form these pulses, the phase locked loop of the PLL was used in synchronization 8, which contains mixer 9, phase detector 10, reference oscillator 11, tunable oscillator 12, and strobe pulses shaper 13 and which transforms the high frequency spectrum into the low frequency region, for example, p 2. 0 kHz  The conversion of the high-frequency signal (-dts occurs in the mixer 9.  Short strobe pulses that control the operation of the mixer 9 are produced by the gate stator 13 pulse impulses.  The frequency of the gating pulses is set by the generator 12, tunable by voltage from the code of the phase detector 10, which multiplies the signal, of the intermediate frequency fpp by the signal from the reference generator 11.  The generated low-frequency signal of the intermediate frequency fnp is removed from the output of the mixer 9 and amplified in the amplifier-limiter 14, then it goes to the differentiating chain 15.  From the output of the differentiating chain 15, pulses of short duration 0, the ISS and the frequency of the pulse are removed.  . 7  equal to „p.  These pulses come to the input of the installation. to zero MA counter 16.  When these impulses arrive, counter 16 is set to zero.  Pulses with a tracking frequency of fc, with f of the order of 1 MHz, are fed to the counting input of counter 16, and the tunable oscillator 12 is removed from the output.  Upon receipt of these pulses, the counter 16 summarizes them.  When a differentiated short pulse is received, the G6 counter is set to zero, t. e. - synchronous filling of the time equal to 1M takes place: the period of the trrr following is differentiated. impulses period T.  / strobe following.  This allows sampling of an Nth pulse of duration TC with the frequency of the sequence fnp per synchronized with. frequency fg, (. transform my voltage.  Such a sampling is performed by the decoder 17.  With each of its N-th bus, the impulse is removed. Tr and with a repetition rate, fnp, and the impulse taken from its N + 1 bus is shifted relatively. N-th tires at time equal to TC, t. e.  control pulses are formed, spaced apart along the TC and at the frequency of the next.  fnp. -; To ensure multiple gating at one point, these pulses are sent to the elements of the IL 18; This mode is carried out by a single-pole (N + 1) -position switch 22, and its output to the terminal is connected to the housing.  For example, in FIG.  3, the switch 22 is in position. Therefore, the resolution of the pulse output with the following frequency and the duration T is given only according to the first output of the synchronization unit 8.  When the position of the switch 22 in one of its N-x gender. The resolution is given for comparing the instantaneous value of the voltage to be converted and the amplitude of the generated reference pulse.  If a . the switch 22 is in the N + 1 position, fo is given, the resolution of the pulse output with the following frequency f, p- and duration T (.  consecutively for each of the N outputs of the synchronization tree 8.  In this position, switch 22 is given permission. to pick up the information.  .   The generated control pulses, removed from the output of the AND-OR 18 element, are sent through the AND-HE element 19 and the delay line 20 to the gate pulse generator 21.  On . The output of the former 21 produces short gating pulses with a duration of 100-200 NS and with a frequency of following. fnp.  These pulses are fed to the output of the gating pulses of the Output Cc of the synchronization unit 8.  / Thus, the synchronization unit 8 forms the strobe pulses synchronized with the voltage being converted, and forms N time-separated control pulses of a certain duration and synchronized with the gating pulses.   V.  . .  ; -.  . . .  ; .  A device that implements a method for transforming stresses with a time-scale transformation works as follows.  Constant voltage taken from source I of the reference voltage,.  The jta inputs of the controlled attributes arrive.  nuators 2.  Kazvdym of. they can change the value of the constant voltage.  This constant voltage enters key 3.  Further, the control pulses are spaced apart.  time and remove the d output of the synchronization block 8, the keys 3 commute.  At the exit ; these keys, t.  .  At each low-frequency input of the adder 4, N different: time-dependent reference pulses of a certain duration are formed, synchronized with the gating pulses and the voltage to be converted.  Moreover, the time shift is equal to the period of following the strobe impulses Tj, or is a multiple of it. with multiple gating.  The pulse duration can be t, T, and the frequency is equal to fnp. .   In the adder 4, each of these reference pulses is summed with the converted high-frequency voltage, with the switch 22 being in one of its N-X positions, arriving at its high-frequency input.  B, if Rt, RQI, the transmission coefficients for high-frequency and low-frequency signals will be the same.  The summed voltage is fed to the input of the stroboscopic transducer 5, where it is gated with short duration pulses.  AT . The timing time is not instantaneous compared. the value of the converted high-frequency stress with the amplitude U N-ro of the reference-ofo pulse.  In the case of their HejpaBeHCfBa, they remember the instantaneous value of the summed up voltage, t. e.  assign and remember the difference voltage U. J.  The inequality of the instantaneous value of the converted high-frequency voltage with the amplitude N-ro of the supporting pulse is judged by the null-organ 6.  The amplitude of O is then changed.  M-th pulse attenuator 2 as long as it is ra: voltage voltage DC - is not equal to zero, t. e.  null-organ 6 will indicate zero This suggests that the amplitude (J.  The Nth reference pulse is equal to the instantaneous value of the high frequency voltage to be transformed at the time of gating.  Permission to form an N-ro onojpHoro pulse in this case is given by switch 22, which is located in its N position.  And to form the N-1 remaining reference pulses, the switch 22 is sequentially switched to the N-1 position.  110 The pulses thus generated carry information about the instantaneous value of the ave. voltage generated.  Information is removed from the output of the filter 7, which does not pass the converted high-frequency voltage, and the switch 22 is in the N + 1 position.  The frequency of the generated reference pulses is equal to f, the repetition period of them is equal to fpp, and the amplitudes of the generated pulses carry information about the instantaneous values of the converted high-frequency voltage.  Thus, the device implements the method. provides the transformation of the high-frequency spectrum of the voltage being converted into a low frequency region.  The proposed method allows to transform a high-frequency voltage of a complex form into a low-frequency one.  The conversion accuracy is high because. the compensation of instantaneous values of the high-frequency voltage with the amplitudes of the generated reference pulses separated in time at the time points of gating occurs.  The error in the conversion of a high-frequency voltage of a complex form is mainly determined by the number of samples of instantaneous values in the period of the voltage being converted and can reach ten percent of percent.

blo / (synronization / and 8

vbM C1

fig.Z

Claims (1)

METHOD OF TRANSFORMING VOLTAGE WITH TRANSFORMATION OF TIME SCALE, which consists in generating gating pulses synchronized with the converted voltage, gating the summed voltage, remembering the instantaneous values of the summed voltages at the gating time, with the aim of increasing the shape, which differs in that spaced in time reference pulses of a given duration and synchronized with the strobe pulses, with mmiruyut each of these supporting pulses convertible voltage, the reference pulse amplitude change as long as the instantaneous value of summed voltage at timings of strobe will not be equal to zero, and judged on the converted voltage thereon. Neck 00 Eb