SU773540A1 - Apparatus for monitoring variable-frequency selective amplifiers - Google Patents

Description

The invention relates to a technique for measuring the transmission coefficient of selective amplifiers at a frequency from tuning and can be used to control selective voltmeter radio receivers, spectrum analyzers, etc. A device for measuring amplifier parameters is known, comprising a parametric amplifier under test, a test signal generator, a selective switch, attenuators , amplitude detector and oscilloscope 1. The disadvantage of the device is a significant measurement error of the tuning frequency of the frequency gain markers on the oscilloscope screen. It is also known a device for a baseline oscilloscopic indication of frequency characteristics containing a controlled oscillator, amplifier, tracking and frequency searching devices, an attenuator, a voltmeter frequency meter and an amplitude controller. The disadvantage is the low measurement performance and significant measurement errors of the transmission coefficient in a wide frequency band. The purpose of the invention is to improve the accuracy and performance of measurements. The goal is achieved in that a device containing a frequency meter, a voltmeter, an amplitude controller and an attenuator connected to the input of a selective amplifier under test, the output of which is connected to the control input of a controlled generator via serially connected tracking and control devices phase corrector, a comparator and an amplitude detector, an output connected to one of the inputs of the amplitude controller and to the second input of said frequency searching device, and The amplitude detector is connected to the input of the frequency meter, to one of the inputs of the frequency tracking device and to one of the inputs of the comparator, the output of which is connected to the input of a voltmeter, and the other input of the comparator is connected to the output of the reference voltage source and to the second input of the amplitude regulator, the third input which is connected to the output of the controlled generator, with

the input of the attenuator and the input phase correction, the output connected to the second input of the device tracking frequency, while the controller

amplitude is made in the form of an operational amplifier, the non-inverting input of which through the first resistor is connected to the device case and to the diode output, the input connected to the capacitor and the second resistor, and its inverting input through the third resistor is connected to the output of the threshold element and through serially connected fourth resistor and a capacitor is connected to the output of the mentioned amplifier.

FIG. 1 shows a block diagram of the device; FIG. 2 - diagram of the amplitude control; in fig. 3 timing charts

The device contains {FIG. 1) attenuator 1, selective amplifier 2, comparator 3, voltmeter 4, amplitude regulator 5, controlled generator 6 phase corrector 7, tracking device 8, frequency meter 9, reference source 10, search device J.1, amplitude detector 12.

The amplitude regulator circuit 5 (Fig. 2) contains a resistor 13, a capacitor 14, a diode 15, an operational amplifier 16, a resistor 17, a threshold element 18, resistors 19 and 20, a capacitor 21, a controlled resistor 22 operational amplifier 23, a threshold element 24 , a resistor 25, a capacitor 26, a directive e 1 resistor 27.

The device works as follows.

In the static state, the harmonic frequency of the controlled oscillator 6 coincides with the tuning frequency of the selective amplifier 2 and these oscillations pass to the comparator 3, the output voltage of which is proportional to the difference between the amplitude of the voltage at the output of the selective amplifier 2 and the voltage of the reference source 10. Coefficient the transmission of attenuator 1 is selected in such a way that this difference and, accordingly, the readings of voltmeter 4 are proportional to the deviation from the nominal value of the value of the parameter being monitored tra is the transmission coefficient of the tested selective amplifier 2 at the tuning frequency, which is recorded by the frequency meter 9.

The voltages at the outputs of the regulator 5 and the controlled generator b do not change in the static state. Based on the readings of a voltmeter 4 and a frequency meter 9, a conclusion is made that the selective amplifier is 2 technical requirements.

The operation of the device in dynamics is illustrated by graphs (Fig. 3). The controller sets the tuning knob in frequency, as well as other organs.

setting the selective amplifier 2 to the desired position. When significant oscillations of the frequency of the self-oscillations of the controlled oscillator b from the tuning frequency of the selective amplifier 2 begin its fast search. In this mode, there is no voltage at the outputs of the tracking device 8 and the amplitude detector 12, since oscillations of the generator b do not pass through the selective amplifier.

S 2. In the absence of voltage at the output of the amplitude detector 12, the regulator 5 of the amplitude does not affect the amplitude of oscillations of the generator b, i.e. parametric reverse circuit

5 communication is open.

It is known that the higher the stability of the amplitude of the generator b, the longer the transition process in the parametric feedback loop.

Q Since the feedback circuit is open, the search mode is performed. Selective amplifier monitoring is not performed. Therefore, the requirements for stability and the form of oscillations are low. At the same time, the frequency searching device 11 can scan at the maximum allowed speed. Detected by the inertia of the controlled oscillator 6 and the selective amplifier 2. The signal from the output of the search device 11 acts on the controlled oscillator b and tunes it in frequency ..

When this frequency approaches the setting frequency of the selective amplifier 2, the device switches to the slow search mode. At the output of the amplitude detector 12, a signal appears that acts on the search device 11 in such a way that the rate of change of the output voltage of this device and, accordingly, the rate of change of the frequency of self-oscillations of the controlled oscillator b are reduced. At the same time, the amplitude detector 12 acts on the amplitude controller 5, closes the parametric feedback loop, and a transient process begins in it. In a closed loop, the amplitude is automatically stabilized, which in the steady state is almost independent of the elements of the controlled oscillator circuit b and is determined only by the voltage value of the reference source 10. At the same time, the harmonic ratio of the controlled oscillator b is significantly reduced. The slow search mode continues until the frequency of this generator becomes equal to the setting frequency of the selective amplifier 2.

After that, the device enters the tracking mode, which is characterized by the presence of a signal at the output of the tracking device 8,

5 made in the form of a phase detector. It uses the well-known property of selective circuits that have a zero phase shift at the resonance or quasi-resonance frequency. The use of a phase detector makes it possible to accurately determine this frequency. At the edges of the frequency range. Additional selective phase shifts introduced by elements that are not part of the selective circuit, such as split capacitors, can occur during the construction of the selective amplifier 2. Phase corrector 7 is introduced into the device to compensate for these shifts. Its elements are selected in such a way that the output voltage of the tracking device 8 reaches a maximum at the tuning frequency (maximum gain) of the selective amplifier 2. In the tracking mode, the frequency control system, formed by 6,1,2,7,8 and 11, automatically supports the maximum output voltage of the tracking device 8 and changes in the tuning frequency of the selective amplifier 2 is accompanied by equal in magnitude and in sign changes in the frequency of self-oscillations of the controlled oscillator 6. At the same time The amplitude stabilization system formed by blocks 5.6 and 10 ensures the exact equality of the amplitude of self-oscillations to the voltage of the reference source 10 and a low harmonic coefficient. With sufficiently slow automatic or manual tuning of the selective amplifier 2 in the tracking mode, it is possible to monitor its transmission coefficient at the tuning frequency using instruments 4 and 9. At a constant tuning frequency, a static condition occurs. The amplitude controller 5 and search device 11 11 (FIG. 2) operate as follows. In the fast search mode, the output voltage of the threshold element 18 through the resistor 19 is fed to the operational amplifier 16 and maintains any of the states (saturation or from the cross section) in which this amplifier does not amplify the properties. The output voltage of the operational amplifier is zero or maximum and does not affect the amplitude of self-oscillations of the generator 6. In this mode, the resistance of the controlled resistor 22 in the search device 11 is minimal, through it the maximum current flows from the power source to the operand the amplifier 23 and passes the fast charge of the capacitor 26. The magnitude of the resistor 27 is maximum. The voltage at the output of the operational amplifier 23 quickly increases and provides a quick re-adjustment of the controlled oscillator 6 in frequency. If the setting frequency of the selective amplifier is not detected in a given generator tuning range, then at the maximum output voltage of the operational amplifier 23. the threshold element 24 is activated, the resistance of the controlled resistor 27 decreases sharply and the capacitor 26 is discharged to it. The output voltage of the search device is also sawtooth. If the tuning frequency of the selective amplifier is detected, a voltage appears at the output of the amplitude detector 12, tilting the threshold element 18 and the slow search mode begins. Here, the operational amplifier 16 is brought to the active state and has a high gain. The input of this amplifier receives pulses from the output of the amplitude limiter formed by elements 13, 14, 15 and 17, the amplitude of which is equal to the difference between the amplitude of self-oscillations of the controlled generator 6 and the voltage of the reference source 10. In C, there is a parametric feedback containing blocks 5 and 6, which together with block 10 form an amplitude stabilization system, the transition process begins. As is known, such systems can work without a static error (astatism of the first order) if they contain an integrator. An op amp 16 can be used as an integrator, capturing it with capacitive negative feedback. However, taking into account that the controlled generator 6 is a conservative envelope system, it can be shown that with integrated control, the proposed system of stabilizing the aggregate is unstable. Stability and astatism can be ensured with integroproportional control. This is achieved by introducing a resistor 20 and a capacitor 21 into the negative feedback circuit of operational amplifier 16. Thus, after the transient process is complete, the amplitude of self-oscillations of the controlled oscillator 6 n is equal to the voltage of the reference source 10 o. Simultaneously with the process of establishing stable self-oscillations in the slow search mode reducing the speed of the controlled oscillator 6 in frequency. This is necessary. In order not to skip the tuning frequency of the selective amplifier. As the output voltage of the amplitude detector 12 increases, the resistance of the controlled resistor 22 increases and the current flowing through it to the input of the operational amplifier 23 decreases. This leads to a decrease in the charge rate of the capacitor 26.

In the tracking mode, the input to the operational amplifier 23 also receives a current through the resistor 25 from the tracking device 8. The total input current provides the output voltage of this amplifier necessary to maintain the oscillation frequency of the controlled oscillator b, equal to the tuning frequency of the selective amplifier 2. In particular, in a steady state (at equal and unchanged frequencies) this current compensates for the capacitor discharge 26 through a controlled resistor 27 having a maximum resistance, and through the input conductivity of the operational amplifier 23. In this case, the voltage at the output of this amplifier does not change

The introduction of new units ensures high accuracy and speed of the instrument. With the help of the amplitude controller 5, in which the integroproportional control law is implemented, the controlled oscillator is calibrated in amplitude in the tracking mode. The introduction of the .3 comparator makes it possible to use the comparison method in measuring the transmission coefficient of the selective amplifier 2. This method is much more accurate than the direct reference method. The introduction of the reference source 10 also contributes to an increase in the measurement accuracy and directly supplies the voltage of this source to the comparator, since the amplitude of the oscillations is exactly equal to this voltage. Introduction of the amplitude detector 12 makes it possible to realize the maximum search speed With significant variations in the frequency of the self-oscillations of the controlled oscillator 6 from the tuning frequency of the selective amplifier 2, and then as these frequencies approach each other, reduce this speed and put the stabilization system into place. The introduction of phase corrector 7 makes it possible to compensate for phase shifts in the 1X selective amplifier 2, which are not included in its selective system, and to reduce the error in determining the tuning frequency at the boundaries of the tuning range of the selective amplifier 2.

Amplitude controller 5 provides an accurate and stable operation of the controlled generator b in the tracking mode and a short time in the amplitude setting mode of this generator (search mode).

The device can be used to monitor selective amplifiers of type U2-8 and selective. Voltmeters of type B6-9.

The time spent on setting up each device is reduced by 35%.

Claims (2)

1. A device for monitoring selective amplifiers tunable in frequency, containing a frequency meter, a voltmeter, an amplitude regulator and an attenuator, output connected to the input of the selective amplifier under test, the output of which is connected to the control input of the controlled oscillator through the serially connected tracking and search devices, characterized in that, in order to improve the accuracy and performance of measurements, a reference voltage source, phase corrector, comparator and amplitude d tector, connected to one of the amplitude controller inputs and to the second input of the specified Frequency Finder, and the amplitude detector input is connected to the frequency counter input, one of the inputs of the frequency tracking device and one of the comparator inputs whose output is connected to the input of a voltmeter and the other input of the comparator is connected to the output of the reference voltage source and to the second input of the amplitude controller, the third input of which is connected to the output of the controlled generator, to the input of the attenuator and to the input of the phase About the corrector, the output connected to the second input of the device tracking frequency. 2. The device according to claim 1, characterized in that the amplitude controller is made in the form of an operational amplifier, the non-inverting input of which through the first resistor is connected to the device case and to the output of the diode, the input connected to the capacitor and the second resistor, and its inverting input through the third resistor is connected to the output of the threshold element and through the fourth resistor connected in series and the capacitor is connected to the output of the mentioned amplifier. Sources of information taken into account in the examination 1. US Patent No. 3904964, cl. 325-67, 1974. 2. Measurements in electronics. Handbook. Edited by Dobrokhotov V. with. 166, fig. 18-2-2 (prototype).