SU1035775A1 - Frequency modulated oscillation shaper - Google Patents

Abstract

FORMER OF FREQUENCY-MODULATED VIBRATIONS, containing a series-connected synchronizer, phase detector and reHepa-i. oscillations, the second input of which is connected to the modular output; a general synchronizer signal, characterized in that, in order to increase the linearity of the modulation law, between the output of the FM oscillator and the second input of the phase detector, a series-connected pulse suppression unit and a frequency divider are inserted between the output the modulating signal of the synchronizer and the installation of the installation of the division factor of the frequency divider introduced a block of forms of the support of the control signals of the frequency delggle, the second input of which is connected the output of the frequency divider, between the output clock signal and the clock sinhro1gazatora vhods dobavle1ga block -escaping pulses introduced howling synthesizer, wherein the set input: d) Operating mode dobavleii -Exclude unit (A cos audio impul1 soeainen with vyhoaom Ko, command-signal sinhronipatora.

Description

The invention relates to a radio-geo-gyne and can be used to form frequency-modulated signals in instrumental equipment, radar and communications systems, Cavestine frequency-modulated (FM) oscillator, in which the measurement of errors relative to the required quadratic law of phase variation is carried out discrete moments of time, followed by a repetition period T QD (. / W, where T and XX / are, respectively, the duration of the signal a signal with linear often modulation (chirp) t.17 Disadvantage The formation of FM frequency oscillations is that, at low rates of frequency change (i.e., small WI Tj.), errors are rarely measured, through T U / W, the closest to the one proposed is the FM shaper, a serially connected synchronizer, a phase detector and a generator of NM oscillations, the second input of which is connected to the output of the modulating signal of the synchronizer, and a recirculator on delay line 2. In this former, FM oscillator in a recirculator on the delay line from the initial chirp section the signal generated by the controlled oscillator of the FM oscillation generates the reference chirp modulator, which is then compared in the phase detector with the signal of the controlled V th FM oscillator. The errors in the phase detector are measured at the frequency of the chirp signal generated, and its inertia does not affect the results of the measurement of gaiobok. However, in the known FM oscillator, for normal operation of the recirculator on the delay delay, special measures must be taken to stabilize the gain, and in addition, the reference signal in the recirculator is obtained from the initial part of the chirp oscillation generated directly in the control of the FM oscillator, and this results It means that the quality of the reference signal is determined not only by the stability of the delay in the delay line, but also by & l, how accurately the law of frequency variation is broken at the initial m segment of the chirp signal generated in the controlled generator. However, in the initial part of the FMC signal with a duration equal to the delay time in the delay line, the stabilization of the FM law in the controlled FM generator does not occur. The scraper noise during the repeated passage of the delay line increases, which is an additional source of vibration, TjaK as a signal from the output of the delay line is used every time as a reference. Due to the inadequacy of the gain around the ring, which includes the delay line, the amplitude of the reference signal is also non-constant. As a result, in a known FM oscillator, the linearity of the modulation law is not high enough. The purpose of the invention is to increase the linearity of the modulation law. In order to achieve this goal, a sequentially connected oscillator, a second input of which is connected to the output of a synchronizing signal of the synchronizer, is inserted into the shaper of frequency-modulated (FM) oscillations containing serially connected synchronizer, phase detector and oscillator modulating signal. addition - exclusion of pulses and a frequency divider, between the output of the modulator signal of the synchronizer and the input of the installation factor of the split divider; The unit for generating the control signals of the frequency divider, the second input of which is connected to the output of the frequency divider, is inserted between the clock output of the synchronizer (and the clock input of the pulse addition-exclusion unit is entered CI | {phy synthesizer, with the pulse-elimination block setting mode input connected to the output of the synchronizer command signal. In Fig. 1, a structural electrical circuit of the proposed frequency-modulated oscillation generator, 4ig, is shown. 2 - time diagrams of his work. The form of frequency-modulated oscillations contains synchronizer 1, phase detector 2, FM oscillator 3, PF synthesizer 4, block 5 for adding and excluding pulses, frequency divider 6, block 7 for forming the signal for controlling the frequency divider. The shaper of frequency-modulated oscillations works as follows). Before starting the FM signal, the digital synthesizer 4 is turned off and the unit 5 for adding and excluding pulses to the frequency divider 6 sends pulses to the input of the generator 3 FM oscillations. After dividing the pulse frequency of these pulses (Fig, 2a) in R since they arrive at phase detector 2, in which they are compared f, arriving at the reference frequency At the time point of Synchronizer 1. At a command from the synchronizer 1, the frequency of the 3 FM oscillation generator begins to change according to the linear law. 4. Molded intezator they have the same oscillation FM The speed that generates and FM oscillation torus 3, but alitelnost T and W of the frequency deviation is much smaller {FIG. 26). On the BpevieHHOM interval, about iJ divider 6 frequency input (fuR. 2c; also pulses with a following frequency are received (in the considered example, block 5 excludes pulses from the digital synthesizer 4 from the 3 FM oscillator generator pulses). At the output of the block, a sequence of pulses is obtained that is close to uniform. At time T, the pulse frequency of the digital synthesizer, 4 meas, 1 is jumped from W to O, and then rises again. At the same time, the pulse following frequency is output to the output; 5 of block 5 jumps to size. the linear-frequency integral of the chirp signal of block 7, connected to the output of frequency divider 6, is blocked, with the result that the frequency division factor R does not change from C. The frequency reduction in the target frequency frequency 6 times RQ is obtained, the oscillation with frequency / 1, which contains information in the phase deviations from the quadratic law of its change. With the beginning of the chirp signal, block 7, connected to the output of frequency divider 6, is opened by a command from synchronizer 1 and at block 7, the action of pulses n frequency n with frequency divider 6 .. After averaging the phase error, vector 2 over the time interval Ro / f. phase deviation information from a square law of frequency variation is used to correct the frequency of the 3 FM oscillator. After passing the pulses at time T-1, the pulse frequency at the output of the yuphro synthesizer 4 skips to W ,, and the division factor of the frequency divider 6 changes. It increases to a value (for example, ®P D °, the frequency of the following pulses at the output of divider 6 frequency on average remains the same and is approximately equal to f .. Approximately moments of change of division factor R and R; -Po + (M), / 1 where j The numbers of the LPU pulses from the output of the digital synthesizer 4 coincide with the moments of time t-lj-I T. There will be no difference in these points if the frequency of the generator of the FM oscillation 3 changes strictly in accordance with the required law (Fig. 2d). All processes are repeated. After passing the W / W pulses from the output of the digital synthesizer 4 o ceases to generate pulses and begins the mode of initial tuning of the frequency of the 3 FM oscillation oscillator. Thus, in both modes, the following frequency: pulses at the output of the frequency divider 6 with the exact shape of the required FM law equal to the reference frequency f (Fig. 2e) .When excluding pulses in the block 5 adding-excluding pulses at the output of the generator of FM oscillations, the linearly increasing FM law is obtained, and when block 5 is in the mode of adding pulses it is linearly incident. The synchronous gas generator 1 can be executed, for example, in the form of a clock generator with a set of frequency dividers with corresponding division factors. The SG level at the output of the last of the dividers, which is the output of the command signal from the synchronizer signal 1, corresponds to the exclusion mode, and the level 1 corresponds to the pulse addition mode. In the proposed Oscillator shaper, by introducing a digital synthesizer into it, forming a footer oscillation with a frequency varying according to a sawtooth law, which, in combination with a frequency divider and a frequency divider control signal generating unit, performs the same functions as the controller on the delay line in known shaper FM oscillations, eliminates the shortcomings of the prototype and significantly increases the linearity of the modulation laws.

Claims (1)

FREQUENCY FREQUENCY REDODED OSCILLATIONS SHAPER containing a synchronizer, a phase detector and a generator *, an FM oscillator, the second input of which is connected to the output of the synchronizer modulating signal, characterized in that, in order to increase the linearity of the modulation law, between the output of the FM generator oscillations and the second input of the phase detector, a series-connected block for adding an exception of pulses and a frequency divider are introduced, between the output of the modulating signal of the synchronizer and the input of the installation A frequency divider control signal generation block is introduced for the frequency divider, the second input of which is connected to the output of the frequency divider, a digital synthesizer is inserted between the output of the clock signals of the synchronizer and the clock input of the add-exclude pulses unit, while the input of the setting of the operation cycle of the add-exclude unit pulses connected to the output of co-. command signal, synchronizer. .SU <1035775 1035775 ..1 .. walking along. Sampling noise during multiple passage of the delay line increases, which is an additional source of errors, since the signal from the output of the delay line is used each time as a reference. Due to the inconstancy of amplification along the ring into which the delay line enters, the amplitude of the reference signal also turns out to be unstable. As a result, in the known shaper of FM oscillations, linearity is not high enough: the modulation law. The purpose of the invention is the improvement of the line20 I