SU1702535A1 - Device for bisignal measuring of receivers frequency selectivity characteristic by blocking and cross distortions - Google Patents

Abstract

The invention relates to radio engineering. The purpose of the invention is to increase the reliability of the measurement. The device contains a generator of 1 low frequency signals, three controllable switches 2.1-2.3, a generator of 3 sig.yu working frequency, dvg. amplitude modulators 4.1, 4.2, matching unit 5, two comparison blocks 6.1, 6.2, controlled oscillator 7, controlled attenuator 8, controlled key 9, reference signal shaper 10, band-pass filter 11, rectifier 12, threshold element 13, logarithmic amplifier 14, differentiation unit 15, counting trigger 16, indication unit 16. The introduced set of blocks makes it possible to eliminate the ambiguity in registering the dual-frequency characteristic of the radio receiver 18 under study and thereby achieve the goal set. 2 Il. 1Л С

Description

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ABOUT

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This invention relates to radio engineering and can be used in tuning and adjusting radio receivers.

The purpose of the invention is to increase the reliability of the measurement.

FIG. Figure 1 shows the structural electrical circuit of the proposed device; in fig. 2 - stress diagrams for his work.

A device for measuring the two-signal characteristics of the frequency selectivity of radio receivers for blocking and cross-distortion comprises a generator of 1 low frequency signals, first, second and third controlled switches 2.1, 2.2, 2.3, a generator of 3 operating frequency signals, first and second amplitude modulators 4.1 , 4.2, matching unit 5, first and second comparison blocks 6.1, 6.2, controlled generator 7, controlled antenna, 8 controlled switch 9, reference signal shaper 10, band-pass filter 11, rectifier 12, threshold elec- 13, a logarithmic amplifier 14, a differentiation unit 15, a counting trigger 16, an indication unit 17, as well as a radio receiver 18 under study.

The device works as follows.

The sawtooth voltage Ui (Fig 2a) of the horizontal sweep generator (not shown) of the display unit 17, which enters the input of the controlled oscillator 7, smoothly changes its frequency fi (Fig. 26) in a predetermined range of f -f frequencies.

Using the low frequency generator 1, the operating frequency generator 3 and the first amplitude modulator 4.1, the second input of the matching unit 5 sets the level of the amplitude modulated signal X0 equal to the sensitivity of the studied radio receiver 18, and the second amplitude module of the torus 4.2 and the controlled attenuator 8 at the first input of the matching unit 5 an amplitude unmodulated signal Xi is formed with a level acceptable for the input circuits of the radio receiver under study 18.

At the initial moment of time, the counting trigger 16 is in the position of logical O (logical 1), leaving the normally closed contacts of the first, second, and third controlled switches 2.1, 2.2, and 2.3 in the closed (open) state.

As a result of the formation of the signals X0 and Xi at the output of the detector of the radio 18 under study at the first and second inputs of the radio 18 under study 18

A signal Y is produced, which is fed to the second input of the second comparison unit 6.2, to the first input of which the output of shaper 10 is supplied with a reference signal YO corresponding to the output signal level of the studied radio receiver 18 when a signal corresponding to its sensitivity is fed to its input. At the output of the second block 6 2 of the comparison, a signal VU0-V is formed, which through the normally closed contacts of the second controlled switch 2.2 is fed to the inputs of the logarithmic amplifier 14 and the controlled attenuator 8. In this case, since the level

the input signal Xi of the studied radio receiver 18 is unambiguously related to the magnitude of the control voltage Y, then when tuning the controlled oscillator 7 in frequency, when the varying level of the signal Xi corresponds to the frequency dependence of the dynamic range of the studied radio receiver 18 by blocking, the control voltage also corresponds to the frequency dependence of the dynamic range of the investigated radio 18 by blocking. From the output of the logarithmic amplifier 14, the voltage U2 (Fig. 2c), through the normally closed contacts of the third controlled switch 2.3, goes to the second input of the display unit 17, on the screen of which the left part of the frequency dependence of the dynamic range of the studied radio 18 is blocked.

When the frequency of the controlled oscillator 7 reaches the lower limit fo-Af of the passband of the studied radio receiver 18, a high-frequency voltage Uz is formed at the output of the band-pass filter 11 (fig. 2d), which enters the input of the rectifier 12. The output of the rectifier 12 forms a voltage LM (Fig. 2d) and translates the threshold element 13 into the logical 1 position. At the output of the threshold element 13, a voltage Us is generated. which is fed to the control input of the control key 9. The control key 9 is locked and at its output the voltage U2 becomes equal to

to zero.

If the frequency of the controlled generator 7 reaches the upper limit fo + Af of the passband of the radio receiver 18 under study at the output of the bandwidth

the filter 11, the voltage Uz disappears, the threshold element 13 returns to the logical O state, and the control key 9 is opened. At the output of the control key 9, the signal voltage Xi appears again,

which, via the flea 5, is reconnected to the input of the studied radio receiver 18, and the formation of the frequency dependence of the dynamic range by blocking continues.

 At the time of the end of the frequency tuning of the controlled generator 7, the reverse stroke of the sawtooth voltage Ui (Fig. 2a) is differentiated by differentiation unit 15 and in the form of a pulse Ue (Fig. 2g) is fed to the input of the counting trigger 16. The counting trigger 16 is switched to the logical 1 position ( logical O) and its output voltage is formed logical 1, which, acting on the control inputs of the first, second and third control switches 2.1, 2.2 and 2.3, translates their normally open contacts in the closed position. The low-frequency signal generator 1 is connected to the modulating input of the second amplitude modulator 4.2, and the input and output of the logarithmic amplifier 14 are connected respectively to the output of the second comparison unit 6.2 and the first input of the display unit 17. At the second input of the matching unit 5, the signal X0 becomes unmodulated, and using the low-frequency signal generator 1 controlled by the generator 7, the second amplitude modulator A2 2, the modulated signal Xi is set to the first input of the matching unit 5 for the input circuits of the radio receiver under test 18.

The sawtooth voltage Ui (Fig. 2a) of the horizontal generator of the display unit 17 again produces a smooth change in the frequency fi of the controlled generator 7 in the f-f frequency range.

As a result of the formation at the input of the studied radio receiver 18 of the signals X0 and Xi, a signal Y is formed at its output, which is fed to the second input of the first comparison unit 6.1, to the first input of which the reference signal V is supplied from the output of the generator 10. The output of the first comparison block 6.1 produces a voltage AY f - O o, which through the normally open contacts of the second switch 2.2 goes to the inputs of the controlled attenuator 8 and the logarithmic amplifier 14.

Moreover, since the input signal level Xi of the studied radio receiver 18 is unambiguously related to the magnitude of the control voltage D Y1, when tuning the controlled oscillator 7 in frequency, when the varying level of the signal Xi corresponds to the frequency dependence of the dynamic range of the radio receiver 18 being crossed distortion, the change in control voltage also corresponds to the frequency dependence

the dynamic range of the studied radio 18 by cross-distortion m.

From the output of the logarithmic amplifier 14, the voltage 1) 2 (Fig. 2c, ti-t2) through the normally open contacts of the third controlled switch 2 3 is fed to the first input of the display unit 17, on the screen of which the left part of the frequency range of the dynamic range is displayed on a logarithmic scale the studied radio 18 by cross-distortion m.

When the frequency of the controlled oscillator 7 reaches the lower limit f0 - Af, the passbands of the studied radio receiver 18 at the output of the band-pass filter 11 produce a high-frequency voltage Uz (Fig. 2d), which is fed to the input of the rectifier 12. At the output of the rectifier 12

voltage UA is formed (Fig. 2e) and translates the threshold element 13 into the logical 1 position. At the output of the threshold element 13, the voltage Us is generated (Fig. 2e), which is fed to the control

the input of the control key 9. The control key 9 is locked and, at its output, the voltage U2 becomes equal to zero.

When the frequency of the controlled

the generator 7 of the upper limit of the bandwidth f0 + Af of the studied radio receiver 18 at the output of the band-pass filter 11, the voltage Uz (Fig. 2d) disappears and the threshold element 13 returns to the state

logical O, and the controllable key 9 is opened again. At the output of the controlled key 9, the voltage of the signal Xi is formed again, which, through the matching unit 5, enters the input of the radio receiver 18 under study and the formation of the frequency dependence of the dynamic range of the radio receiver 18 by cross distortion continues.

When the sawtooth voltage Ui of the horizontal sweep of the display unit 17 ends, the frequency tuning of the controlled generator 7 stops, and the reverse voltage Ui is differentiated by the differentiation unit 15 and in the form of a pulse Ue (Fig. 2g) is fed to the input of the counting trigger 16. The counting the trigger 16 is switched to the state of logical O (logical G) and the output voltage of the logical O is formed.

which, arriving at the control inputs of the first, second and third control switches 2.1, 2.2 and 2.3, puts their normally closed contacts in a closed state. In this case, the low frequency signal generator 1 is connected to the modulating input of the second amplitude modulator 4.2, and the input and output of the logarithmic amplifier 14 is connected to the output of the second comparison element 6.2 and to the second input of the display unit 17. Again, the sawtooth voltage Ui begins to increase and the secondary measurement of the frequency range of the dynamic range of the radio receiver 18 by intermodulation starts.

As a result of the change in the states of the counting trigger 16, the contact positions of the first, second and third controlled switches 2.1, 2.2 and 2.3 also change, which leads to a corresponding change in the order of display on the screen of the two-beam display unit 17 of the frequency dependence curves of the dynamic ranges of the radio receiver 18 under study block and cross distortion

Claims (1)

Apparatus of the Invention A device for measuring the two-signal characteristics of the frequency selectivity of radio receivers for blocking and cross-sectional distortions, containing a threshold element, a controlled oscillator, a first amplitude modulator, serially connected low frequency signal generator, a first control switch, the second output of which is connected to the modulating input of the first amplitude modulator, the second amplitude modulator, the signal input of which is connected to the output of the controlled oscillator, equal attenuator, control key, the control input of which is connected to the output of the threshold element, and the matching unit, the second input of which is connected to the output of the first amplitude modulator, and the output of the matching unit is the input of the subsequent radio receiver, operating frequency generator, the output of which connected to the signal input of the first amplitude modulator, the first comparison unit, logarithmic amplifier, counting trigger, display unit, the output of which is connected to the control input of the controlled oscillator Pa, characterized in that, in order to increase the measurement accuracy, a differentiation unit is introduced, the input and output of which are connected respectively to the output of the display unit and the input of the counting trigger, serially connected band-pass filter, the input of which is connected to the output of the controlled generator, and a rectifier, the output of which is connected to the input of the threshold element, serially connected to the shaper of the reference signal, the output of which is also connected to the first input of the first comparator unit, the second comparator unit and the second control switch, another input and output of which are connected respectively to the output of the first comparator unit and control input of the controlled attenuator, the third controlled switch, the first and second outputs and input of which are connected respectively to the first and second inputs of the display unit and the output of the logarithmic amplifier whose input is connected to the output of the second controlled switch, the second inputs of the first and second comparison units are combined and are the output of the radio receiver under study, while The main inputs of the first, second, and third controlled switches are combined and connected to the output of the counting trigger. ,, P-WAA4И1№ Jk Fi.2