SU1099289A1 - Device for measuring polynominal coefficients of non-linear four-terminal network transfer function - Google Patents

Abstract

A device for measuring the polynomial coefficients of the transfer function of a non-linear four-terminal, containing a generator of a multi-tone signal, an output connected to the first input terminal of the device, and a spectrum analyzer, in order to reduce the measurement time, connected to this unit is connected. an attenuator, an addition and switching unit, and a phase distortion compensation unit; the input of the latter is connected to the second input terminal of the device and to the input of the amplifier — limit l, and the output with the second input of the addition and switching unit, the output of which is connected to the spectrum analyzer. (Ls

Description

The invention relates to a measurement technique and can be used to measure the polynomial coefficients of a transfer function of a nonlinear quadrupole. A device is known for measuring the coefficients of the polynomial of the transfer function of a nonlinear quadrupole, which contains a multi-tone generator, a spectrum analyzer. The polynomial coefficients are measured by the measured values of the harmonic or combination components of the signal arising due to the non-linearity of the amplitude characteristic of the quadrupole. A single-tone, two-tone, three-tone, four-tone or fluctuation noise lj is used as a test signal. One disadvantage of the device is that with an increase in the number of test tones, measurements of individual Raman components using a spectrum analyzer cannot be performed due to the final resolution of the instrument. In addition, due to the considerable duration of the measurements, the accuracy of the measurements due to the departure of the parameters of the monitored quadrupole test signal and measuring instruments decreases, so the time required for measuring one component of the signal with the C4-16 spectrum analyzer is 30 seconds. It takes 405 hours to measure all the components of the ninth order inclusive with the help of the known. The aim of the invention is to reduce the measurement time of the combination components when determining the polynomial coefficients of the transfer function of a nonlinear quadripole. The goal is achieved by the fact that a device for measuring the polynomial coefficients of the transfer function of a nonlinear quadrupole generator, containing a multi-tone signal generator, an output connected to the first input terminal of the device and a spectrum analyzer, are connected in series to an amplifier-suppressor, attenuator, switching and switching unit, and a unit compensation of phase distortion, while the latter is connected to the input. the second input terminal of the device and the input of the amplifier of the limiter, and the output to the second input of the addition and switching unit, the output of which is connected to the spectrum analyzer. FIG. 1 shows a functional diagram of an apparatus for measuring the coefficients of the polynomial of the transfer function of a nonlinear quadrupole; in fig. 2 - timing diagrams explaining the principle of operation of the device. A device for measuring the polynomial coefficients of the transfer function of a nonlinear quadrupole contains a multi-tone signal generator 1, a nonlinear quadrupole 2, a spectrum analyzer 3, a reference signal unit 4, a limiter amplifier 5, an attenuator 6, a phase distortion unit 7, a phase distortion compensation unit 8, and input terminals 9 and 10. The device operates as follows. From the multi-tone generator 1 (Fig. 1), a two-tone signal arrives at the input of the four-port network being investigated. Its frequencies co, cOj are chosen in such a way that their difference I / CO, - C0, j /, is much less than any of the frequencies of the components, i.e. Condition 9 "O),, Q is satisfied. In this case, the components with the frequencies CO, and Co2 are grouped together with the combination components of odd orders of the form ±, ± n, and. The instantaneous value of any of the combinational components is determined by the formula, jCOS (± n (x) | ± n20j) t} (1) From the output of the tested quadrupole, a two-tone signal is fed to the input of block 4 of the reference signal. In block 4 of the reference signal, the components of the spectrum at the output of the non-linear quadrupole are compared with the spectrum of the reference signal, representing a two-tone signal limited in amplitude. As a result of the comparison, the + or - sign is defined before Uy in formula (1). It is known that for a signal limited in amplitude, the sign in front of the modulus of the combinational component UK is determined by the order of the combination + n ,. The + sign corresponds to the fractional ratio values, the values of the reference signal components of 1,5,9,13 orders of the reference signal are +, and the components of the reference signal 3, 7,11,15 times the signs are -, as shown in FIG. 2a .. For the case under consideration, the + sign in the formula (1) corresponds to the synphasic nature of the combinational components at the output of the nonlinear quadrupole and the corresponding components of 1,5,9,13 orders of the reference signal, and the sign - corresponds to the antiphase of the same components. 3,7,11,15 orders, the + sign corresponds to the antiphase components at the output of the nonlinear quadrupole and the reference signal, and the sign corresponds to the synphase character of the same components. In block 4 of the reference signal, the signal is fed to the input of the amplifier of the limiter 5 and to the input of the block 8 of the compensation of phase distortions. Amplifier-limiter 5 forms a reference signal, which is necessary for comparing the individual combinational components (Fig. 2). Due to the fact that the amplitude of the combination components at the output of the amplifier limiter is much larger than the same components at the output of the four pole circuit 2 under study, an attenuator 6 is switched on to reduce their overall level. The addition and switching unit 7 provides the necessary switchings when measuring nonlinear distortions of scientific research institutes. The first input of the addition and switching unit 7 receives a reference signal, and the second input receives a signal from the output of the quadrupole 2 through the phase distortion compensation unit. To compensate for the phase distortions occurring in the limiting amplifier 5 and the attenuator 6, the phase distortion compensation unit 8 is used The unit 7 for adding and switching the signal is fed to the input of the 89 Lysator 3 of the spectrum. The signal spectrum at the input of the addition and switching unit 7, taking into account the component signs, is shown in FIG. 2b, and the spectrum picture on the screen of the spectrum analyzer 3 in FIG. 2g. The measurement of the levels and signs of the combinational components of the signal is performed as follows. The addition and switching unit 7 is switched in such a way that a signal from the phase distortion compensation unit 8 only arrives at the input of the spectrum analyzer 3. Using a spectrum analyzer 3, the levels of the combinational components of the signal are observed and noted. Further, the addition and switching unit 7 turns off the signal from the output of phase distortion compensation unit 8 and connects the signal from the output of attenuator 6. Using the spectrum analyzer 3 and adjusting the attenuator 6, set the combinational component of the limited signal equal to the level of the corresponding component when connected to the unit 7 add and switch only the signal from the phase distortion compensation unit 8. Further, the addition and switching unit 7 carries out the addition of signals from the outputs of the attenuators 6 and the phase distortion compensation unit 8. Using a spectrum analyzer 3, a change in the level of the corresponding combinational component of the signal is observed. If the total level of the corresponding combinational component is less than when a signal is received only from block 8, compensation of phase distortions, then the sign of the corresponding combinational component is opposite to the sign of the combinational component of the limited signal, and if the level is higher, then the signs are the same. Thus, the signs of the components, 3, 5, 9 ... S, are sequentially determined. The determination of the levels and signs of combinational components with a multi-tone signal is performed similarly. Unit 4 of the reference signal can be made as a separate unit or included in the spectrum analyzer 3. In case the reference signal block 4 is included in the spectrum analyzer 3, phase comparison is performed at the intermediate frequency of the spectrum analyzer 3, which greatly simplifies the tuning and measurement process. . The device determines not only the levels of the combinational components, but also the signs of these components. Their values are used to calculate the coefficients of the polynomial, the transfer function of the quadrupole of the form yyh +. . ., where X is the input signal; S is the highest degree of approximating polynomial. According to the known formulas a .--- ;: and. (I. 1 a.) (3) a,, ..., ei.ag) 2n ,, n Е П W, 7-- m. (n ,. Virv W Uj. - the levels are combined, -, and, rational components, the spectrum at the output of the quasilinear device under study; S is the highest degree of approximating polynomial; N is the order of the combination; m is an index that takes values 1,2,3 ... S; combinations. For the case in question, the equalities / n, / p, E., E2 are determined - the levels of the components of the two-way test signal, blunt to the input of the studied zilinear device

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Claims (1)

DEVICE FOR MEASURING THE POLYNOMIC COEFFICIENTS OF THE TRANSMISSION FUNCTION OF THE NONLINEAR FOUR-HOLE, containing a multi-tone signal generator, output connected to the first input terminal of the device, and a spectrum analyzer, characterized in that , the addition and switching unit, and the phase distortion compensation unit, while the input of the latter is connected to the second input terminal of the device and to the input of the limiter amplifier, and move - to a second input of addition and switching unit, whose output is connected to the spectrum analyzer. Vui f u □ o>