RU2053518C1 - Spectrum analyzer - Google Patents

Abstract

FIELD: radio measurement technology. SUBSTANCE: spectrum analyzer has antenna 1, selector switch 2, attenuators 3.1, 3.2, filters 4.1, 4.2, mixers 5.1-5.4, intermediate-frequency amplifiers 6.1, 6.2, control units 7.1, 7.2, reference-frequency generator 20, band filters 9.1, 9.2, 9.3, local oscillator 8, intermediate-frequency generator 10, adjustable band amplifier 21, electronic switches 15.1-15.7, matching units 16.1-16.2, detector 17, videoamplifier 18, sweep generator 19, digital code shaper 22, OR gates 23.1-23.3, 24.4, 24.5, reversing counter 25, oscilloscope 26, horizontal-deflection amplifier 27, differentiating units 28.1, 28.2, trigger unit 29, decoder 30, cathode-ray tube 31, vertical-deflection amplifier 32, potentiometers 33.1, 33.2, and radio receiver 34 being analyzed. EFFECT: improved design. 2 dwg

Description

 The invention relates to radio-measuring equipment and can be used to observe the spectra of stationary signals and determine the sources of radio interference acting on the studied radio receiver on the side reception channels and as a result of intermodulation.

 In FIG. 1 is a structural diagram of a spectrum analyzer; in FIG. 2 diagrams explaining his work.

 The spectrum analyzer contains a measuring antenna 1, switch 2, the first and second attenuators 3.1 and 3.2, the first and second sweep filters 4.1 and 4.2, the first, second, third and fourth mixers 5.1, 5.2, 5.3 and 5.4, the first and second amplifiers 6.1 and 6.2 intermediate frequency, the first and second control units 7.1 and 7.2, made, for example, in the form of direct current amplifiers, local oscillator 8, first, second and third band-pass filters 9.1, 9.2 and 9.3, intermediate frequency generator 10, directional coupler 11, tunable local oscillator 12, adder 13, broadband amplifier 14, first, second, third and fourth, fifth, sixth and seventh electronic keys 15.1, 15.2, 15.3, 15.4, 15.5, 15.6, 15.7, made, for example, on thyristors, the first and second matching units 16.1 and 16.2, made, for example , in the form of high-frequency tees or splitters, detector 17, video amplifier 18, sweep generator 19, reference frequency signal generator 20, adjustable broadband amplifier 21, digital code driver 22, made, for example, as a constant voltage source with voltage taps, logical "0 "and" 1 ", first, second, tr It, fourth and fifth elements OR 23.1, 23.2, 23.3, 23.4 and 23.5, made, for example, on diodes with a common load, delay element 24, made, for example, in the form of a single tap delay line, a counter 25, a three-beam oscilloscope 26, an amplifier 27 horizontal deflection, the first and second differentiation blocks 28.1 and 28.2, made, for example, in the form of differentiating circuits, the start block 29, made, for example, in the form of a single pulse generator, a decoder 30, a cathode ray tube 31, a vertical deflection amplifier 32, first and Torah potentiometers 33.1 and 33.2 set the frequency. The investigated radio 34 is also shown.

 The spectrum analyzer operates as follows.

 At the initial moment, the radio receiving device, which includes a radio receiver 34, is operating normally. In the case of exposure to this radio receiver of radio interference sources, the radio receiver 34 is disconnected from its antenna and connected in accordance with the block diagram of FIG. 1.

The switch 2 is set to position 2, and the spectrum analyzer is tuned to a viewing mode in which the radio receiver 24 is affected by radio interference. In this case, the signal of the first intermediate frequency f _pch1 of the spectrum analyzer is received from the output of the generator 10, respectively, from the output of the generator 10 to the first and second inputs of the third mixer, and from the directional coupler 11, the signal f _{g of the} tunable local oscillator 12, the tuning range of which corresponds to the spectrum analyzer's viewing range. From the output of the third mixer 5.3, the signal amplified by broadband amplifier 14 through the first bandpass filter 9.1, tuned to the frequency f _{o of the} main receiving channel of the studied radio receiver 34, is fed through switch 2 and the first attenuator 3.1 to the input of the first sweep filter 4.1 of the spectrum analyzer.

Simultaneously, from the output of the broadband amplifier 14, the converted signals with a combination of frequencies f _o = f _g ± f _pc1 are fed to the information input of the first controlled key 15.1, and at the output of the fourth mixer 5.4, to the signal and heterodyne inputs of which are from the outputs of the reference frequency generator 20 and the third band filter 9.3 with a passband of (0.1-2) f _o signals X ₁ with a frequency f _o and a tunable signal X ₂ tunable in the frequency range of (0.1-2) f _o , a combination of frequencies [(0,1- 2) f _o ± f _o] which enters the adjustment shirokopo axle amplifier 21 with a band (0,1-0,9) f _o.

When tuning in the range (0.1-1) f _{o of the} frequency f _{1 of the} signal X ₂ at the output of the adjustable broadband amplifier 21, a signal X ₃ with a smoothly changing in the range (0.9-0.1) f _{o of the} frequency f ₂ = f ₀ -f ₁ , and when tuning the signal X ₂ in the frequency range (1-2) f _o at the output of the adjustable broadband amplifier 21, a signal X _{3 is formed} with a frequency f _{2 that} varies smoothly in the range (0.1-0.9) f _o = f ₁ -f ₀ , which is fed to the information input of the third control key 15.3.

The triggering element 29 produces a single pulse U ₁ , which is supplied through the second OR 23.2 element to the installation input of the reverse counter 25, translating it to its initial state, and through the first OR 23.1 element and the delay element 24 the same pulse U ₁ , but delayed for a while, necessary to install the reversible counter 25 in the initial state, is fed to its clock input.

The output of the reversible counter 25 in binary code generates the value of the number "1", which is pre-stored in the generator 22 of the digital code. In this case, a voltage log is generated at the second output of the decoder 30. "1", which is fed to the first input of the third element OR 23.3. The output of the third element OR 23.3 also generates a voltage log. "1", which is fed to the control inputs of the third, fourth and seventh managed keys 15.3, 15.4 and 15.7. At the outputs of the third and seventh controlled keys 15.3 and 15.7, signals X ₃ and X ₂ are formed, respectively, which, through the second matching unit 16.2, are input to the studied radio receiver 34.

As a result of the formation of the intermodulation component f ₁ + f ₂ = f ₀ / (f ₁ -f ₂ = f _o ) at the output of the studied radio receiver 34, an intermediate frequency signal f _{pc is} generated, which through the first matching unit 16.1 is fed to the detector 17. From the output of the detector 17 the detected signal after amplification by the video amplifier 18 through the open fourth controlled key 15.4 is fed to the first information input of the three-beam oscilloscope 26. In this case, the frequency dependence is dynamically displayed on the screen of the three-beam oscilloscope 26 with the first beam the first range of the studied radio 34 by intermodulation in the frequency range (0.1-1.9) f _o .

At the moment of the end of the front of the first sawtooth pulse U ₂ (Fig. 2a) of the sweep generator 19, its slice is differentiated by the first differentiation unit 28.1 and, in the form of a pulse U ₃ (Fig. 2b), is fed to the summing input of the reversible counter 25. The reversible counter 25 is also activated bit outputs in binary code is formed by the value of the number "2", which generates at the third output of the decoder 30 voltage U ₄ (Fig. 2B) log. "1". From the third output of the decoder 30 voltage U ₄ log. "1" goes to the first input of the fourth element OR 23.4, the output of which also generates a voltage log. "1", and separates the first and fifth driven keys 15.1 and 15.5 In this case the output of the first controllable switch 15.1 via tunable band spectrum analyzer review second sweep filter 4.2 and the second block 16.2 match signal with frequency f _c applied to the input of the test radio 34 . As a result of coincidence tunable Raman signal and the main reception channels investigated radio 34 on its output line channel formed intermediate frequency f _IF, which via a first matching block 16.1 of blunt the detector 17, where after the detection through the video amplifier 18 and open the fifth controllable switch 15.5 are supplied to the second data input of a three-beam oscilloscope 26. In this case, on the oscilloscope screen 26 displayed second beam amplitude-frequency characteristic of the radio receiver 34 of the test.

At the moment of the end of the front of the second pulse of the sawtooth voltage U ₂ (Fig. 2a) of the sweep generator 19, its slice is differentiated by the first differentiation unit 28.1 and, in the form of a second pulse U ₃ (Fig. 2b), is fed to the summing input of the reverse counter 25. The reverse counter 25 is activated, and on its bit outputs in binary code the number "3" is formed, which generates a voltage U ₄ log at the fourth output of the decoder 30. "1" entering the first input of the fifth element OR 23.5. The output of the fifth element OR 23.5 also generates a voltage log. "1", which opens the second and sixth managed keys 15.2 and 15.6. If the frequency of the difference signal f _c = f _g −f _{pc1 coincides} with the passband of the main receive channel of the studied radio receiver 34 at the output of the second bandpass filter 9.2 with a passband identical to the passband of the studied radio receiver 34, a signal of the second intermediate frequency f _pc2 of the spectrum analyzer is formed, which via a second electronic switch 15.2 and the first matching block 16.1 is supplied to the input of detector 17. The output of detector 17, video amplifier 18, the amplified signal of the second intermediate frequency f _pch2 through sixth councils The key 15.6 is fed to the third information input of the three-beam oscilloscope 26, and through the open sixth controlled key 15.6 and the vertical deflection amplifier to the plates of the vertical deflection of the cathode ray tube 31. In this case, the amplitude-frequency characteristic of the first one is displayed on the screens of the cathode ray tube and oscilloscope 26 band-pass filter 9.1.

At the end of the front of the third sawtooth pulse of the sweep generator 19, its slice is differentiated by the first differentiation block 28.1 and, in the form of a third pulse U ₃ (Fig. 2b), is fed to the summing input of the reverse counter 25. The reverse counter 25 is triggered, and at its bit outputs in binary code the value of the number "4" is formed, which causes a voltage U ₄ log at the fifth output of the decoder 30. "1", which is fed to the second input of the third element OR 23.3. At the output of the third element OR 23.3, a voltage log is formed again. "1", which again opens the third, fourth and seventh managed keys 15.3, 15.4 and 15.7. In this case, again on the screen of the three-beam oscilloscope 26, the first beam highlights the frequency dependence of the dynamic range of the studied radio receiver 34 by intermodulation.

 Thus, the corresponding signals are connected in series to the first, second and third information inputs of the three-beam oscilloscope 26 and to the plates of the vertical deflection of the cathode ray tube 31.

At the moment of the end of the eighth pulse U _{2 of the} sawtooth voltage, the slice of the pulse U ₄ from the tenth output of the decoder 30 is differentiated by the second differentiation block 28.2 and, in the form of a pulse U ₅ (Fig. 2d), is supplied through the second OR 23.2 element to the OR 23.1 installation element and the delay element 24 , arrives at the synchronizing input of the reverse counter 25. First, the reverse counter 25 is set to the initial state, and then the value of the number "1" is again formed at its bit outputs, which sets the voltage at the output of the decoder 30 again ix U ₄ log. “1” and the process of highlighting on the screen of a three-beam oscilloscope 26 the characteristic curves of the first band-pass filter 9.1, the amplitude-frequency characteristics of the studied radio receiver 34 and its frequency, the dependences of the dynamic range on intermodulation are repeated.

 By changing the gain of the adjustable broadband amplifier 21, the output signal levels are aligned at the outputs of the broadband amplifiers 14 and 21, and using the first attenuator 3.1 and the third beam control of the three-beam oscilloscope 26, the transmission coefficients of the linear paths of the spectrum analyzer and the studied radio receiver 34 are identified, which consists in the formation of equal deviations on the screen of a three-beam oscilloscope of 26 vertices of the amplitude-frequency characteristic of the first the band-pass filter 9.1 and the amplitude-frequency characteristics of the main reception channel of the studied radio 34. Then, the switch 2 is set to 1 and the panorama of the electromagnetic environment is displayed on the screen of the cathode ray tube, and the frequency dependence of the dynamic range of the studied radio 34 on intermodulation is formed on the screen of the three-beam oscilloscope 26 (Fig. 2d.1), its amplitude-frequency characteristic (Fig. 2e) and a panorama of the electromagnetic environment in the area of the radio receiver.

If panorama signals fall into the passband of the combined reception channels and exceed their levels, then such signals should be considered radio interference to the radio receiver. In the absence of such signals, radio interference should be determined from the number of signals that exceed the level of the frequency dependence of the dynamic range of the radio receiver 34 (Fig. 2d.3) by intermodulation, and whose algebraic sums of frequencies are (f ₁ ± f ₂ ), (2f ₁ -f ₂ ), (2f ₂ -f ₁ ) fall into the passband of the reception channels of the studied radio 34.

Claims (1)

 A SPECTRUM ANALYZER containing a measuring antenna, the output of which is connected to the first moving contact of the switch, a first bandpass filter, the output of which is connected to the second moving contact of the switch, the first attenuator, the first sweep filter, the first mixer, the first intermediate frequency amplifier, connected in series with the fixed contact of the switch , a second mixer, a second intermediate frequency amplifier and a second band-pass filter, connected in series to the signal generator of the first intermediate hour spectrum analyzer tunes, third mixer, broadband amplifier and first controlled key, serially connected sweep generator, second attenuator, adder, second control unit, tunable local oscillator and directional coupler, serially connected detector and video amplifier, vertical deflection amplifier, the outputs of which are connected to vertical plates deviations of the cathode ray tube, a three-beam oscilloscope, the control inputs of which are connected to the combined outputs of the amplifier horizontal sweep and plates of horizontal deflection of the cathode ray tube, while the movable contact of the first potentiometer of the frequency setting is connected to the local oscillator output, the second sweep filter, the input and output of which are connected respectively to the output of the first controlled key and the second input of the first matching unit, the control input of the first a sweep filter connected to the output of the first control unit and to the control input of the second sweep filter, the heterodyne input of the first mixer is connected to the first output of the second coupler, the heterodyne input of the second mixer is connected to the local oscillator output, the heterodyne input of the third mixer is connected to the second output of the directional coupler, the output of the broadband amplifier is connected to the input of the first bandpass filter, the second output of the scan generator is connected to the inputs of the first differentiation unit and horizontal amplifier, the second input the adder is connected to the movable contact of the second frequency setting potentiometer, and the second output of the second control unit is connected to the input of the first control unit, characterized in that a third band-pass filter is inserted into it, a second controlled key and a second matching unit are connected in series, a reference frequency signal generator is connected in series, a fourth mixer, an adjustable broadband amplifier, a third controlled key connected to the first input of the first matching unit , digital code generator, second differentiation unit connected in series, first OR element, delay element, reversible counter, decoder, last a properly connected start block, the output of which is connected to the second input of the first OR element, and the second OR element, connected in series with the defifier, the third OR element and the fourth controlled key, the fourth OR element in series connected to the decoder, the output of which is connected to the control input of the first managed key, and a fifth managed key, connected in series with the decoder, the fifth OR element and the sixth managed key, as well as the seventh managed key, while the input of the third bandpass filter and connected to the output of the broadband amplifier, the information input of the second managed key is connected to the output of the second bandpass filter, and the control input is connected to the output of the fifth OR element, the second input and output of the second matching unit are connected respectively to the output of the intermediate frequency amplifier of the studied radio receiver and the detector input, heterodyne the input of the fourth mixer is connected to the output of the third band-pass filter and the information input of the seventh managed key, the output of which is connected to the third input the first matching unit, the output of which is connected to the input of the studied radio receiver, the second input of the second OR element is connected to the output of the second differentiation unit, the information bit inputs and the summing input of the reverse counter are connected respectively to the bit outputs of the digital code generator and the output of the first differentiation unit, the corresponding decoder output is connected with the input of the second differentiation unit, the output of the second OR element is connected to the installation input of the reverse counter, output One of the fifth controlled key is connected to the first information input of the three-beam oscilloscope, the output of the third OR element is connected to the control input of the third controlled key, the output of the fourth controlled key is connected to the second information input of the three-beam oscilloscope, the output of the sixth controlled key is connected to the information third input of the three-beam oscilloscope, to the input amplifier and to the input of the amplifier vertical deviation, the control input of the seventh control key is connected to the control input tr tego controllable switch and the output of the third OR gate, and objective data inputs of the fourth, fifth and sixth driven keys connected to the output of the video amplifier.

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