SU1272271A1 - Digital spectrum analyzer - Google Patents

Abstract

This invention relates to electrical measuring technology. The aim of the invention is to expand the frequency band of the analyzed signals without degrading the accuracy of the analysis. For this, a third memory block is additionally inserted into the digital spectrum analyzer. The drawing shows a voltage converter 1 in the number of pulses, diffractive dividers 2 and 3 frequencies, digital quadrature harmonic oscillator 4, indicators 5 and 6, memory blocks 7, 8 and 9, reversible counters 10 and II, control block 12, adder 13. The introduction of block 9 and the connection of elements shown in the drawing made it possible, within the limits of a given element base speed, to increase the analysis accuracy without reducing the upper frequency range limit, and also to increase the upper limit of the frequency band (L band a. uemyh signals without sacrificing accuracy of the analysis. 2 yl. to lN3 w

Description

The invention relates to electrical measuring technology, and can be used in radio engineering, acoustics and communication technology. The aim of the invention is to expand the frequency band of the studied signals without degrading the analysis accuracy. FIG. 1 shows a functional diagram of a digital spectrum analyzer; FIG. 2 shows timing diagrams for the operation of the spectrum analyzer. The device consists of converting voltage 1 into the number of pulses of digital-controlled dividers 2 and 3 frequencies, digital generator 4 quadrature harmonic oscillations, indicators 5 and 6, memory blocks 7-9, reversible counters 10 and 1i, control unit 12 The accumulator 13, the t-bit outputs of the generator 4 are connected to the setting g-bit inputs of the digital controlled dividers 2 and 3 frequencies, the outputs of which are connected to the information inputs of the reversible counters 10 and 11, respectively, and the frequency inputs of the dividers are connected to each other and at The output of the voltage converter 1 is the number of pulses. The outputs of counters 10 and 11 are connected to the inputs of blocks 7 and 8 of memory, the outputs of which, in turn, are connected to indicators 5 and 6, respectively. The first input of control unit 12 is connected to the input of the voltage converter 1 in the number of pulses, the second and third inputs to the sign outputs of the generator 4, and the fourth input is the synchronizing input of the analyzer. The first output of the control unit 12 is connected to the combined control of the inputs of the memory blocks 7 8, the third input of the memory block 9 and the second input of the adder 13, the second output with the second input of the memory block 9, the third output with the reverse connectors of the reversible counters 10 and 11, and the fourth and fifth outputs - with the inputs of the control of the counting direction of the reversible counters 10 and 11, respectively. The output of the memory block 9 is connected via the adder 13 to the first input of the memory block 9 and to the address input of the generator 4. The third input of the adder 13 is the control input of the analyzer. The operation of the device is based on the implementation of the Fourier transform of the analyzed signal by means of analog-digital technology. The device works as follows. The analyzed signal S (t) is converted by the converter 1 into bursts of pulses. The number of pulses in the bursts is proportional to the discrete values of the signal under study at successive instants of time t ;. The obtained samples of the studied signal S (t, -), presented in the form of the number of pulses, are fed to the first inputs of digitizable dividers 2 and 3 frequencies. The installation inputs of these dividers from oscillator 4 receive codes for counting quadrature harmonic oscillations at successive times sin KcDtj and cos Kcjt, (where K is the number of the measured harmonic). At the output of each digital-divisible divider, new bursts of pulses are formed, the number of pulses in which N (tj) and NjCt;) for each time t, - with an accuracy of a constant multiplier equal to the product of the number of input pulses and input code: N, (t ;) - S (t;) sin Kwt; ; one . (t, -) UGP- S (t;) cos Kwt;,. where m is the number of bits of the digitally controlled frequency divider. Reversible counters 10 and 11, the counting direction of which is determined by the control unit 12 depending on the signs of the signal under study and the generated reference voltages, perform the algebraic summation of the pulse bursts from the outputs of dividers 2 and 3. The reference voltages generated by the generator 4 are applied to the second and the third inputs of the control unit, and the signal under study arrives at the first input. The control signals of the reversible counters 10 and 11 are taken from the fourth and fifth outputs of the control unit, respectively. At the end of the period of the studied signal S (t), codes of the spectral coefficients of the analyzed signal are formed at the outputs of the counters. -2 - „- 21S (t;) sinKwt ;; a (t,) cos Kcot; After that, a short pulse of the control unit, taken from the first output, records the contents of the counters 10 and II in the blocks 7 and 8 of the memory. The memory impulse unit 9 and the adder 13 are reset with the same impulse. After this, the delayed impulse taken from the third output of the control unit, the counters 10 and II are zeroed. The delay is necessary so that before the counters are reset, the information from their outputs is rewritten into memory blocks. At the same time, the delay should not be significant, so as not to introduce an error in the measurement of spectral coefficients. After zeroing the counters, the process of determining the spectral coefficients is repeated. A sync signal with a frequency equal to the first harmonic frequency of the analyzed signal is supplied to the fourth input of the control unit 12. Most of the objects under study (for example, in vibrometry) have such a clock signal. Otherwise, it can be selected from the signal itself by known methods, for example, using controlled filters. ; The formation of the reference oscillations by generator 4 occurs as follows. The code from the output of the adder 13 arrives at the address input of the generator 4. The code from the output of memory block 9 arrives at one input of this adder, and the code of the analyzed harmonic number goes to another input. In memory block 9, a code is output from the output of the adder 13 when the next clock pulse arrives from the second output of the control unit. Thus, if the initial states of memory block 9 and adder 13 are zero, then the output code of the adder consistently increases from zero to complete filling of the adder, and the increment step is equal to the measured harmonic number code. Generator 4: quadratic oscillations is a permanent memory (ROM) whose address inputs receive the output code of the adder 13, and the output codes of the quadrature harmonic oscillation reads. The number of the reference is specified by the address code (output code of the adder 13). The process of forming the reference sinusoidal oscillations of 3-fold frequencies is illustrated by the timing diagrams in Fig.2. Cosine oscillations are formed in a similar way. The abscissa axis shows the codes at the address inputs of the generator 4. From figure 2 it can be seen that during the formation of the reference oscillation of the lowest frequency (1st harmonic) the step of the address code is 1, during the formation of the 2nd harmonic it is 2, during the formation 3 th harmonic equals 3, etc. The address code step is understood here as the difference between the numbers of adjacent samples. Thus, the step of the address code coincides with the number of the measured windmill. Due to this circumstance, a simple digital control of the frequency of the reference oscillations is possible, providing measurement of the harmonics of certain multiplicities of the signal under study. To measure the K-th harmonic, it is enough to send the code of the number K to the third input of the sugmator 13. At the end of the period of the signal under study, when the codes of the spectral coefficients a and b, are formed, memory unit 9 and adder 13 are impulse from the first output of the control unit . In the proposed device, in contrast to the known number of discrete samples in one period of the reference oscillation, with a multiple change in its frequency, it does not remain constant, and decreases in proportion to the number of the measured harmonic. Therefore, the frequency of the clock pulses taken from the second output of the control unit does not change when measuring harmonics of different multiplicities, which is accompanied by the formation of a reference KNB with frequencies of the same multiplicities. This circumstance makes it possible to increase the number of samples of the reference oscillation of the lowest frequency to the maximum value possible with a given element base speed. Since in this case the number of samples is large enough, the methodological error in measuring the 1st harmonic is small. - When measuring all subsequent 1 and 1 harmonics, the methodical error remains unchanged and equals the measurement of the 1st harmonic,

Claims (1)

Claim A digital spectrum analyzer containing a control unit and a voltage to pulse converter connected to the input, as well as two digitally controlled frequency dividers, two reversible counters, two memory blocks, two indicators and a digital quadrature harmonic oscillation generator, the first and second t-bit outputs of which are connected with the first m-bit inputs of digitally controlled frequency dividers, the second inputs of which are interconnected and with the output of the voltage converter to the number of pulses, and the output with the first inputs of ersivnyh counters, the outputs of which are connected to the inputs in6 cators through corresponding memory blocks, the second inputs of which are connected to the first output of the control unit, and the third and fourth outputs Dig ₅ rovogo generator quadrature harmonic oscillations coupled to the second and third inputs of the control unit, the third output is connected with second inputs of reversible counters, 10, and the fourth and fifth outputs of the control unit with third inputs of the corresponding reversible counters, characterized in that, in order to expand the band 5 that of the analyzed signals without compromising the accuracy of the analysis, a third memory block is inserted into it, the output of which is connected through the adder to the first input of this memory block and to the input 20 of the digital generator of quadrature harmonic oscillations, the second input of the third memory block connected to the second output of the control unit, the combined second input of the adder and the third input of the third memory block are connected to the first output of the control unit, and the third input of the adder is the control input of the spectrum analyzer.