SU1054872A1 - Linear frequency-modulated signal former - Google Patents

Abstract

FORMER OF LINEAR-FREQUENCY MODULATED SIGIALS, containing sequentially connected integrator, controlled generator, power supply unit / and mixer, the second input of which is connected to the output of controlled generator, differing in that, in order to expand the working frequency band when increasing the range of adjustments the rate of change of frequency, between the output of the mixer and the input of the integrato1, serially connected frequency detector and a differential amplifier are introduced, to the second input of which is connected the output inputted reference voltage source, between the output of the mixer and the control input of the integrator administered serially connected inverter alternating voltage into a pulse train, a memory unit and down counter, the down counter vykod coupled to the control input yuyshm papam whith block

Description

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4 ;: The invention relates to a radio receiver and can be used to form a linear-frequency mode. of a signal in radio communications, as well as in panoramic radio measuring devices. A linear frequency modulated shaper is known, which contains series-connected controlled high-frequency generator, delay element, mixer, low-pass filter, differential amplifier, single-side modulator and reference generator, Bt i whose input is connected to the second input of the phase detector, this generator compares the instantaneous value of the modulating voltage with the output voltage of the phase detector. The maximum output voltage corresponds to the maximum frequency deviation. When scanning the frequency of a high-frequency generator, the voltage at the output of the low-pass filter varies according to the sine law and to meet the requirements for linearity of tuning, only a small stretcher section is used to characterize the phase detector, resulting in a swing band limited the magnitude of the linear portion of the characteristics of the phase detector. The delayer mixer and the single-sided modulator also form an equivalent frequency detector, the output of which is represented by a sinusoid (a constant tj), the initial phase of which depends on the frequency of the high-frequency oscillator and changes with a period of 1 However, when shifting the initial phase is more than half of the indicated, period, the output signal of the equivalent frequency detector is modulated in amplitude with a beat frequency of about 23 b (and the generator loses its performance With which the working frequency band is limited by magnitude. The closest to the present invention is a linear frequency modulated signal shaper containing a series-connected integrator, a controlled oscillator, a delay element and a mixer whose second input is connected to the output of the controlled oscillator, a phase detector with a reference generator frequency, an active filter, while a delay element, a mixer, a phase detector with a reference frequency generator, and an active filter form a discriminator that isolates the error The frequency of the frequency change is 2, However, in this shaper of linear-frequency-modulated signals, the working frequency band and the frequency control range of the frequency change frequency are not large enough. The purpose of the invention is the expansion of the working frequency band by increasing the range of adjustment of the c-rate of frequency change. This goal is achieved by the fact that a linear frequency-modulated signal shaper containing a series-connected integrator / controlled generator, a delay element and a mixer, the second input of which is connected to the output of a controlled oscillator, between the output of the mixer and the integrator input are introduced a series-connected frequency detector and a differential amplifier, to the second input to Secondly, the output of the input voltage source is connected, between the output of the mixer and the integrator's control input, a serially connected alternating voltage converter into a pulse sequence, a memory unit and a reversible counter are inserted, while the output of the reversible counter is connected to the control input of the unit memory In the drawing, a pre-assembled electrical circuit of a linear frequency modulated signal generator is provided. The linear frequency modulated signal shaper contains a controlled oscillator 1, a delay element 2, a mixer 3, a frequency detector 4, an alternating voltage converter 5, a pulse sequence, a reversible counter 6, memory unit 7, reference voltage source 8, differential amplifier 9 and integrator 10 The linear-frequency modulated waveform shaper works as follows, At the beginning of bots, until information about the number of switchings determining the frequency deviation is entered into the reversible counter, it is in position O The integrator 10 is off, and the frequency detector 4 and converter 5 do not work, the controlled oscillator 1 generates a constant frequency signal in the initial section working range. The signal from the controlled oscillator 1 is fed to one of the inputs of the mixer 3 directly, and to the other through the delay element 2. At the output of the mixer 3, a certain constant voltage is produced to which the frequency detector 4 does not react and at its output a zero potential. In the reversible counter 6 of the corresponding switching number, the integrator 10 starts and charges it with the output current of the differential amplifier 9. Due to the fact that at the output of frequency detector 4 at the initial moment the voltage is absent, the differential voltage difference at the inputs of differential amplifier 9 is maximal at the differential voltage difference the source 8 of the reference voltage, and the charge rate of the integrator 10 at the same time is maximum. The variable output voltage of the integrator 10 is fed to the control input of the controlled oscillator 1 and adjusts its frequency. At the output of the mixer 3, an alternating voltage appears with a frequency proportional to the rate of change of the frequency of the controlled oscillator 1, the signal from the output of the mixer 3 is detected by the frequency detector 4, the output of which is set to a constant voltage, also proportional to the speed of the controlled oscillator 1 This voltage is applied to the first input of the differential amplifier 9, reduces the differential difference of the voltage applied to the inputs and reduces the charge rate of the integrator 10 so that The differential difference r of the input voltages at the inputs of the differential amplifier 9 was as small as possible. At the same time, the signal from the output of mixer 3 is fed to converter 5 and, acting on the input of the reversing counter b, reduces the value of the recorded number by one each time the signal from the forward current of mixer 3 passes through extreme points, and so until the reversible counter b reaches the zero state. At this moment there is an integrator discharge of 10 and. overwriting the specified number into the reversible counter b with the memory block 7. A new cycle of the linear scanning of the frequency of the controlled oscillator 1 begins. The specified number defining the frequency deviation of the controlled oscillator 1 is recorded in the memory block 7 and cyclically transferred to the reversible counter b by the zero potential of its output. In this case, the frequency detector 4 does not measure the deviation of the frequency of the controlled oscillator 1 from the initial one, but the rate of change over time, and the nonlinearity of the characteristics of such a detector does not affect the linearity of the tunable oscillator 1. The tuning rate is determined by the reference voltage of the source 8 the reference voltage can always be set with the necessary accuracy and is adjustable over a wide range. The differential amplifier 9 combines the functions of the Voltage comparator and the source of a sawtooth voltage for the tuning of a low-frequency controlled oscillator 1. The operating frequency band in the proposed linear frequency modulated signal shaper is fundamentally limited only by the range of the characteristics of frequency detector 4, but since it measures the low frequency signal, and the nonlinearity of its characteristics does not affect the linearity of the tuning of the controlled oscillator 1, the deviation work-by- The frequency band is practically limited by the tuning band of the most controlled oscillator 1. For wideband oscillators on traveling and reverse waves, for example, the tuning band is hundreds of MHz. Thus, in the proposed one. A linear frequency modulated signal shaper achieves a significant expansion of the working frequency band by increasing the frequency control rate range.

Claims (1)

(541 LINEAR-FREQUENCY DRIVEN SIGNALS FORMER, containing a series-connected integrator, a controlled generator, a delay element; and a mixer, the second input of which is connected to the output! controlled generator, characterized in that, in order to expand the working frequency band while increasing the range of regulation of the rate of change of frequency, between the output of the mixer and the input of the integrator are introduced series-connected frequency detector and differential amplifier, the second input of which is connected to the output of the input reference voltage source, between the output the mixer and the control input of the integrator introduced in series connected converter of alternating voltage into a pulse sequence, a memory block and a reversible 'counter, while! output of the reversible counter is connected to the control input of the unit pa- | of memory