RU70423U1 - MULTI-FREQUENCY SIGNAL SHAPER IN THE CENTIMETER RANGE OF MODULATED FREQUENCY, AMPLITUDE AND PHASE - Google Patents

Abstract

The utility model relates to the field of radio engineering and can be used in centimeter-range radio transmitting devices as a master oscillator. The multi-frequency signal generator in the centimeter range modulated in frequency, amplitude and phase contains a frequency synthesizer (1), a frequency multiplier (2), a first frequency converter (9), a reference generator (5), a second frequency converter (12), an amplitude modulator (10 ), phase modulator (6), adder (3), first switch (13), second switch (11), first linear frequency modulation generator (8), control device (16). The first output of the frequency synthesizer (1) is connected to the first input of the frequency multiplier (2), the first output of the reference generator (5) is connected to the first input of the frequency synthesizer (1), the third output of the reference generator (5) is connected to the second input of the first frequency converter (9) ), the second output of the reference generator (5) is connected to the first input of the first linear frequency modulation generator (8), the output of the first frequency converter (9) is connected to the first input of the amplitude modulator (10), the output of the amplitude modulator (10) is connected to the first input of the phase Maud insulator (6), the output of the phase modulator (6) connected to the first input of the second inverter (4). To achieve the possibility of obtaining many sets of different composition, with amplitude frequency and phase modulation of all carrier frequencies of the signals making up the set, with an adjustable relative time delay and frequency shift of the spectra of multi-frequency signals at one output relative to the other, a second linear frequency modulation generator ( 12), synchronizer (14), power divider (7), third

switch (15). The fourth output of the reference oscillator (5) is connected to the first input of the second linear frequency modulation generator (12), the fifth output of the reference generator (5) is connected to the first input of the synchronizer (14), the output of the second linear frequency modulation generator (12) is connected to the first input of the first switch (13). The output of the first linear frequency modulation generator (8) is connected to the third input of the first switch (13), the output of the first switch (13) is connected to the first input of the first frequency converter (9), the fourth output of the control device (16) is connected to the third input of the second linear generator frequency modulation (12). The third output of the control device (16) is connected to the second input of the first switch (13), the second output of the control device (16) is connected to the third input of the first linear frequency modulation generator (8), the first output of the control device (6) is connected to the second input of the frequency synthesizer (1), the fifth output of the control device (16) is connected to the second input of the synchronizer (14), the first output of the synchronizer (14) is connected to the second input of the amplitude modulator (10). The third output of the synchronizer (14) is connected to the second input of the phase modulator (6), the fourth output of the synchronizer (14) is connected to the second input of the first linear frequency modulation generator (8), the second output of the synchronizer (14) is connected to the second input of the second linear frequency modulation generator (12). The fifth output of the synchronizer (14) is connected to the second input of the second switch (11), the sixth output of the synchronizer (14) is connected to the second input of the third switch (15). The second output of the frequency synthesizer (1) is connected to the second input of the frequency multiplier (2), the third output of the frequency synthesizer (1) is connected to the third input of the frequency multiplier (2), the fourth output of the frequency synthesizer (1) is connected to the fourth input of the frequency multiplier (2) , the fifth output of the frequency synthesizer (1) is connected to the fifth input of the frequency multiplier (2), the first output of the frequency multiplier (2) is connected to the first input of the adder (3) second

the output of the frequency multiplier (2) is connected to the second input of the adder (3), the third output of the frequency multiplier (2) is connected to the third input of the adder (3), the fourth output of the frequency multiplier (2) is connected to the fourth input of the adder (3), the fifth output of the multiplier frequency (2) is connected to the fifth input of the adder (3). The output of the adder (3) is connected to the second input of the second frequency converter (4), the output of the second frequency converter (4) is connected to the input of the power divider (7), the first output of the power divider (7) is connected to the first input of the second switch (11). The second output of the power divider (7) is connected to the first input of the third switch (15), 4 ill.

Description

The utility model relates to the field of radio engineering and can be used in centimeter-range radio transmitting devices as a master oscillator.

Known shaper of amplitude-phase-modulated signals of the centimeter range [RU No. 26708, Н03С 5/00, 2002], comprising a reference generator, a frequency divider, first and second frequency converters, amplitude modulator, frequency synthesizer, signal multiplier, phase modulator. In addition, the first and second switches, the first and second pulse shapers, the control circuit, the signal adder, the waveguide of the output signal, the input signal of the phase switching signal, the connectors of the first and second input modulating pulses, the connectors of the output signals of the first and second frequency oscillator of the receiver, the signal connector control modes and a connector for synthesizer control signals.

The closest in technical essence to the proposed utility model is a centimeter-wave signal shaper with amplitude, phase, and linear-frequency modulations [RU No. 2253182 C1, IPC Н03С 5/00, 2005], comprising a reference generator, a frequency divider, the first and second frequency converters, amplitude modulator, phase modulator, frequency synthesizer, frequency multiplier, first and second pulse shapers, first and second switches, control circuit and adder. The fourth input of the frequency synthesizer is connected to the connector of the control signals of the frequency synthesizer, the first input of the frequency synthesizer is connected to the first output of the reference generator.

The fourth output of the reference oscillator is connected to the input of the frequency divider, the third output of the frequency divider is connected to the first input of the first frequency converter. The first output of the first frequency converter is connected to the first input of the amplitude modulator, the output of the amplitude modulator is connected to the first input of the phase modulator. The second input of the phase modulator is connected to the input terminal of the phase switching signal, the output of the phase modulator is connected to the first input of the second frequency converter, the output of the second frequency converter is connected to the waveguide of the output signal. The third output of the reference generator is connected to the second input of the first frequency converter, the second output of the first frequency converter is connected to the output signal connector of the second receiver local oscillator. The first and second outputs of the frequency divider are connected respectively to the second and third inputs of the frequency synthesizer, the first output of the frequency synthesizer is connected to the output signal connector of the first receiver local oscillator. The second output of the frequency synthesizer is connected to the input of the frequency multiplier, the output of the frequency multiplier is connected to the second input of the second frequency converter. The input of the control circuit is connected to the connector of the control signal of the operating modes, the first output of the control circuit is connected to the second input of the first switch, the second output of the control circuit is connected to the second input of the second switch. The first input of the second switch is connected to the connector of the second input modulating pulse. In addition, it contains a linear frequency modulation generator, the output of which is connected to the third input of the first frequency converter. The first input of the linear frequency modulation generator is connected to the second output of the reference generator, the second input of the linear frequency modulation generator is connected to the signal control connector, the linear frequency modulation generator. The input of the first pulse shaper is connected to the connector of the first input modulating pulse, the output of the first pulse shaper is connected to the first input of the first switch.

The output of the first switch is connected to the first input of the adder, the second input of the adder is connected to the output of the second switch. The output of the adder is connected to the input of the second pulse shaper, the output of the second pulse shaper is connected to the second input of the amplitude modulator.

The disadvantages of the known devices is the inability to sequentially generate multi-frequency, coherently generated signals on two parallel outputs, consisting of a set of several signals with carriers switched over the frequency grid in order to obtain many sets of different composition, with amplitude frequency and phase modulations of all carrier frequencies of the signals constituting a set with adjustable relative time delay and frequency shift of the spectra of multi-frequency signals at one output relative to of another.

The technical result of the proposed multi-frequency signal shaper in the centimeter range modulated in frequency, amplitude and phase consists in the possibility of sequentially generating multi-frequency, coherently generated signals at two parallel outputs, consisting of a set of several signals with carriers switched over the frequency grid in order to obtain many different signals the composition of sets, with amplitude frequency and phase modulations of all carrier frequencies of the signals making up the set, with ositelnoy time delay and frequency shift spectra multifrequency signals on a single output relative to the other.

The essence of the proposed technical solution lies in the fact that the driver of the multi-frequency signal in the centimeter range modulated in frequency, amplitude and phase contains a frequency synthesizer,

frequency multiplier, first frequency converter, reference generator, second frequency converter, amplitude modulator, phase modulator, adder, first switch, second switch, first linear frequency modulation generator, control device.

The first output of the frequency synthesizer is connected to the first input of the frequency multiplier, the first output of the reference generator is connected to the first input of the frequency synthesizer, the third output of the reference generator is connected to the second input of the first frequency converter, the second output of the reference generator is connected to the first input of the first linear frequency modulation generator, the output of the first the frequency converter is connected to the first input of the amplitude modulator, the output of the amplitude modulator is connected to the first input of the phase modulator, the output of the phase m undulator connected to the first input of the second inverter.

To achieve the possibility of generating a multi-frequency signal in the centimeter range modulated in frequency, amplitude and phase, it consists in the possibility of sequentially generating multi-frequency signals at two parallel outputs, consisting of a set of several signals with carriers switched over the frequency grid in order to obtain many sets of different composition, with amplitude frequency and phase modulations of all carrier frequencies of the signals making up the set, with adjustable relative time delay and with Vig frequency spectra multifrequency signals on a single output relative to the other, a second generator administered chirp, synchronizer, a power divider, the third switch. The input of the control device is the input of the control signals of the operating modes of the multi-frequency signal driver in the centimeter range modulated in frequency, amplitude and phase, the fourth output of the reference generator is connected to the first input of the second linear frequency modulation generator, the fifth output of the reference generator is connected to the first input of the synchronizer, the output of the second generator linear

frequency modulation is connected to the first input of the first switch, the output of the first linear frequency modulation generator is connected to the third input of the first switch, the output of the first switch is connected to the first input of the first frequency converter, the fourth output of the control device is connected to the third input of the second linear frequency modulation generator, the third output of the device control is connected to the second input of the first switch, the second output of the control device is connected to the third input of the first linear generator frequency modulation, the first output of the control device is connected to the second input of the frequency synthesizer, the fifth output of the control device is connected to the second input of the synchronizer, the first output of the synchronizer is connected to the second input of the amplitude modulator, the third output of the synchronizer is connected to the second input of the phase modulator, the fourth output of the synchronizer is connected to the second the input of the first linear frequency modulation generator, the second output of the synchronizer is connected to the second input of the second linear frequency oscillator Ul, the fifth synchronizer output is connected to the second input of the second switch, the sixth synchronizer output is connected to the second input of the third switch, the second output of the frequency synthesizer is connected to the second input of the frequency multiplier, the third output of the frequency synthesizer is connected to the third input of the frequency multiplier, the fourth output of the frequency synthesizer is connected to the fourth input of the frequency multiplier, the fifth output of the frequency synthesizer is connected to the fifth input of the frequency multiplier, the first output of the frequency multiplier is connected to the first input ummatora, the second output frequency multiplier is connected to the second input of the adder, a third frequency multiplier output is connected to the third input of the adder, a fourth multiplier output frequency is connected to the fourth input of the adder, a fifth multiplier output frequency is connected to the fifth input of the adder. The output of the adder is connected to the second input of the second frequency converter, the output of the second frequency converter

connected to the input of the power divider, the first output of the power divider is connected to the first input of the second switch, the output of which is the first output of the multi-frequency signal shaper in the centimeter range modulated in frequency, amplitude and phase, the second output of the power divider is connected to the first input of the third switch, the output of which is the second output is a shaper of a multi-frequency signal shaper in the centimeter range with amplitude frequency and phase modulations.

Figure 1 presents the functional diagram of the driver of a multi-frequency signal in the centimeter range modulated in frequency, amplitude and phase.

On figa) presents the arrangement in the frequency domain of the signals Fc generated at the outputs of the frequency synthesizer.

On figb) presents the arrangement in the frequency domain of the signals And at the outputs of the frequency multiplier.

On figv) presents the spectrum of the multi-frequency signal Uo, consisting of five carriers Fo and the frequency range in which it is possible to switch the frequency of each carrier, when combined.

Figure 3 presents the timing diagram of the shaper.

Figure 4 presents an example of constructing a functional diagram of a frequency synthesizer 1.

Figure 5 presents an example of constructing a functional diagram of the control device 16.

The multi-frequency signal generator in the centimeter range modulated in frequency, amplitude and phase contains a frequency synthesizer 1, a frequency multiplier 2, an adder 3, a second frequency converter 4, a reference generator 5, a phase modulator 6, a power divider 7, a first linear frequency modulation generator 8, the first converter

frequency 9, amplitude modulator 10, second switch 11, second linear frequency modulation generator 12, first switch 13, synchronizer 14, third switch 15, device 16.

The first output of the frequency synthesizer 1 is connected to the first input of the frequency multiplier 2.

The first output of the reference generator 5 is connected to the first input of the frequency synthesizer 1.

The third output of the reference generator 5 is connected to the second input of the first frequency converter 9.

The second output of the reference oscillator 5 is connected to the first input of the first linear frequency modulation generator 8.

The output of the first frequency converter 9 is connected to the first input of the amplitude modulator 10.

The output of the amplitude modulator 10 is connected to the first input of the phase modulator 6.

The output of the phase modulator 6 is connected to the first input of the second frequency converter 4.

The input of the control device 16 is the input of the control signals of the operating modes of the multi-frequency signal driver in the centimeter range modulated in frequency, amplitude and phase.

The fourth output of the reference oscillator 5 is connected to the first input of the second linear frequency modulation generator 12.

The fifth output of the reference generator 5 is connected to the first input of the synchronizer 14.

The output of the second linear frequency modulation generator 12 is connected to the first input of the first switch 13.

The output of the first linear frequency modulation generator 8 is connected to the third input of the first switch 13.

The output of the first switch 13 is connected to the first input of the first frequency converter 9.

The fourth output of the control device 16 is connected to the third input of the second linear frequency modulation generator 12.

The third output of the control device 16 is connected to the second input of the first switch 13.

The second output of the control device 16 is connected to the third input of the first linear frequency modulation generator 8.

The first output of the control device 16 is connected to the second input of the frequency synthesizer 1.

The fifth output of the control device 16 is connected to the second input of the synchronizer 14.

The first output of the synchronizer 14 is connected to the second input of the amplitude modulator 10.

The third output of the synchronizer 14 is connected to the second input of the phase modulator 6.

The fourth output of the synchronizer 14 is connected to the second input of the first linear frequency modulation generator 8.

The second output of the synchronizer 14 is connected to the second input of the second linear frequency modulation generator 12.

The fifth output of the synchronizer 14 is connected to the second input of the second switch 11.

The sixth output of the synchronizer 14 is connected to the second input of the third switch 15.

The second output of the frequency synthesizer 1 is connected to the second input of the frequency multiplier 2.

The third output of the frequency synthesizer 1 is connected to the third input of the frequency multiplier 2.

The fourth output of the frequency synthesizer 1 is connected to the fourth input of the frequency multiplier 2.

The fifth output of frequency synthesizer 1 is connected to the fifth input of frequency multiplier 2.

The first output of the frequency multiplier 2 is connected to the first input of the adder 3.

The second output of the frequency multiplier 2 is connected to the second input of the adder 3.

The third output of the frequency multiplier 2 is connected to the third input of the adder 3.

The fourth output of the frequency multiplier 2 is connected to the fourth input of the adder 3.

The fifth output of the frequency multiplier 2 is connected to the fifth input of the adder 3.

The output of the adder 3 is connected to the second input of the second frequency converter 4.

The output of the second frequency converter 4 is connected to the input of the power divider 7.

The first output of the power splitter 7 is connected to the first input of the second switch 11, the output of which is the first output of the shaper of a multi-frequency signal in the centimeter range modulated in frequency, amplitude and phase.

The second output of the power splitter 7 is connected to the first input of the third switch 15, the output of which is the second output of the driver of the multi-frequency signal in the centimeter range modulated in frequency, amplitude and phase.

Frequency synthesizer 1, an example of which is shown in Figure 4, consists of a frequency divider 17, a second frequency multiplier 18, a third frequency multiplier 19, a fourth frequency multiplier 20, a fifth frequency multiplier 21, a sixth frequency multiplier 22, and a seventh

frequency multiplier 23, eighth frequency multiplier 24, ninth frequency multiplier 25, tenth frequency multiplier 26, eleventh frequency multiplier 27, twelfth frequency multiplier 28, thirteenth frequency multiplier 29, fourth switch 30, third frequency converter 31, fourth frequency converter 32, fifth converter frequency 33, the sixth frequency converter 34, the seventh frequency converter 35.

The input of the frequency divider 17 is connected to the inputs of the eleventh frequency multiplier 27, the twelfth frequency multiplier 28, the thirteenth frequency multiplier 29 and is the second input of the frequency synthesizer 1. The control signals of the operating modes of the frequency synthesizer 1 are fed through its first input to the first input of the fourth switch 30.

The output of the frequency divider 17 is connected to the inputs of the second frequency multiplier 18, the third frequency multiplier 19, the fourth frequency multiplier 20, the fifth frequency multiplier 21, the sixth frequency multiplier 22, the seventh frequency multiplier 23, the eighth frequency multiplier 24, the ninth frequency multiplier 25, and the tenth frequency multiplier 26.

The outputs of the second frequency multiplier 18, the third frequency multiplier 19, the fourth frequency multiplier 20, the fifth frequency multiplier 21, the sixth frequency multiplier 22, the seventh frequency multiplier 23, the eighth frequency multiplier 24, the ninth frequency multiplier 25, the tenth frequency multiplier 26 are connected respectively to the second, the third, fourth, fifth, sixth, seventh, eighth, ninth, tenth inputs of the fourth switch 30.

The outputs of the first, second, third, fourth, fifth of the fourth switch 30 are connected to the second inputs, respectively, of the third frequency converter 31, fourth frequency converter 32, fifth converter

frequency 33, the sixth frequency converter 34, the seventh frequency converter 35.

The output of the eleventh frequency multiplier 27 is connected to the first input of the third frequency converter 31.

The first output of the twelfth frequency multiplier 28 is connected to the first input of the fourth frequency converter 32.

The second output of the twelfth frequency multiplier 28 is connected to the first input of the fifth frequency converter 33.

The first output of the thirteenth frequency multiplier 29 is connected to the first input of the sixth frequency converter 34.

The second output of the thirteenth frequency multiplier 29 is connected to the first input of the seventh frequency converter 35.

The output of the third frequency converter 31 is the first output of the frequency synthesizer 1.

The output of the fourth frequency converter 32 is the second output of the frequency synthesizer 1.

The output of the fifth frequency converter 33 is the third output of the frequency synthesizer 1.

The output of the sixth frequency converter 34 is the fourth output of the frequency synthesizer 1.

The output of the seventh frequency converter 35 is the fifth output of the frequency synthesizer 1.

The control device 16, an exemplary embodiment of which is shown in Fig. 4, consists of a series-connected decoder 36 and a matching device 37. The input of the decoder 36 is connected to the input of the driver 38 and is the input of the control device 16. The output of the matching device 37 is the first output of the control device 16. The first output of the driver 38 is the second output of the control device 16, the second output of the driver 38 is the third output of the control device 16, the third output of the driver 38 is

the fourth output of the control device 16, the fourth output of the driver 38 is the fifth output of the control device 16.

Shaper of a multi-frequency signal in the centimeter range modulated in frequency, amplitude and phase. (Figure 1) works as follows:

Frequency synthesizer 1 (Figure 4) coherently generates frequency grids of signals at its outputs, in the presented example, five: - at the first output Fci (from the output of the third frequency converter 31); - at the second output Fcj (from the output of the fourth frequency converter 32); - at the third output Fck (from the output of the fifth frequency converter 33); - at the fourth output of Fcl (from the output of the sixth frequency converter 34); - at the fifth output of Fcm (from the output of the seventh frequency converter 35). The output signals are generated from the input signal Pho, arriving at the first input of the frequency synthesizer 1 from the first output of the reference generator 5, and their carrier frequency is switched by the control signals at its second input, coming from the first output of the control device 16. The signal Pho is fed to the frequency divider 17 and divided by the division coefficient n, up to the frequency F, the synthesizer _{step ,} which determines the minimum tuning step of the output frequencies Fci, Fcj, Fck, Fcl, Fcm of the synthesizer 1. The signal F, the synthesizer _step. arrives at nine, in the presented example, frequency multipliers from the second to the tenth (18 ... 26) with multiplication factors N ₄ , N ₄ +1, N ₄ +2 ..., N ₄ +8 (increasing by one). At the outputs of these frequency multipliers (18 ... 26), stand signals are generated, in the presented example, from the frequency Fп1 = (N ₄ ) × Foп to the frequency Fп9 = (N ₄ +8) × Foop, the values of which sequentially increase by the value of the step F _{step synt.,} and which then enter the nine, in the presented example, inputs 2 through 10 of the fourth switch 30. From the first input of the frequency synthesizer 1 to the first input of the fourth switch 30, control signals are received, which, depending on selection of frequency values of signals Fci, Fcj, Fck, Fcl,

Fcm, form on the five, in the presented example, outputs, from the first to the fifth, the fourth switch 30, the frequencies of the stands with Fп1 no Фп9, which are fed to the second inputs of five, from the third to the seventh, frequency converters (31 ... 35). The first inputs of five, from the third to the seventh frequency converters (31 ... 35) receive signals from the outputs, in our example, three, from the eleventh to the thirteenth frequency multipliers (27, 28, 29), in which the signal Fоп arriving at their inputs, multiplied by the multiplication factors N ₁ , N ₂ and N ₃ , to the frequency N ₂ × Fo at the output of the eleventh frequency multiplier 27, to the frequency N ₃ × Fo at the output of the twelfth frequency multiplier 28 and to the frequency N ₃ × Fo at the output of the thirteenth frequency multiplier 29. The signals Fci, Fcj, Fck, Fcl, Fcm, formed in the frequency synthesizer 1 (Fig. 2a) are received a frequency multiplier inputs 2, comprising, in the illustrated example, five multiplication channels, in which there is multiplication of the frequency signals at 4 at its input respectively to the values Ai, Aj, Ak, Al, Am outlet (2b). Further, the signals Ai, Aj, Ak, Al, Am, from the outputs of the frequency multiplier 2, go to the adder 3, which at the output generates a multi-frequency signal, consisting of a combination of five coherent signals (set) with the carrier frequencies Ai; Aj; Ak; Al; Am, each of which has the ability to switch in frequency. This provides a combination of signal frequencies in sets.

The generated multi-frequency signal from the output of the adder is fed to the second input of the second frequency converter 4.

The first input of the second frequency converter 4 receives the signals F _np1 or F ' _np1 from the output of the first frequency converter 9 through the amplitude modulator 10 and the phase modulator 6. At the output of the second frequency converter 4, the spectrum of the multi-frequency signal at its second input is transferred upward by equal to the carrier frequency of the pulsed signals F _np1 or F ' _np1 . As a result, at the output of the first frequency converter 4, pulses are alternately formed

multi-frequency signals 1Uo or 2Uo. The 1Uo signal consists of a combination of five coherent, simultaneously generated signals (set) with carrier frequencies F ₀ i = Ai + F _p.1 ; F _0j = Aj + F _p . ₁ ; F ₀ k = Ak + F _p . ₁ ; F ₀ l = Al + F _p . ₁ ; F ₀ m = Am + F _{pp. 1} (Fig.2c) and enters the first output. And the signal 2Uo, consisting of F ' ₀ i = Ai + F'_p.1; F ' ₀ j = Aj + F' _approx . ₁ ; F ' ₀ k = Ak + F' _p . ₁ ; F ' ₀ l = Al + F' _approx. 1 F ' ₀ m = Am + F' _p.1 (Fig.2d), is fed to the second output. Signals 1Uo and 2Uo are generated with a time shift by ΔT, varying from zero values to the maximum possible, within the repetition period (Figure 3). The pulse signal U1, formed by the control pulses T ₁ , T ₂ , T ₃ (Figure 3), from the output of the first frequency converter 9 is fed to the power divider 7, from the first output of the power divider 7 to the first input of the second switch 11 and to its output , which is the first output of the device for generating a multi-frequency signal in the centimeter range modulated in frequency, amplitude and phase. The pulse signal U2 is formed by control pulses T _1set. , T _{2 back.} T _{3 back.} (Figure 3) from the output of the first frequency converter 9 goes to the power divider 7, from the second output of the power splitter 7 to the first input of the third switch 15 and to its output, which is the second output of the multi-frequency signal driver in the centimeter range modulated in frequency, amplitude and phase. The required frequency difference of the signals Fo and F'o, as well as the choice of the presence or absence of modulation, the nature and level of modulation, is determined by the control signals of the operating mode, received at the input of the shaper 38 (Figure 5) and, further, from the outputs of the device control incoming to the first 8 and second 12 linear frequency modulation generators. Linear frequency modulation generators 8 and 12 from the signal F _on , by commands from the control device 16, generate the signals F _PG and F ' _PG . When giving a command to select the steepness Si tuning frequency F _GH and F ' _GH and the pulse durations T ₁ and T _{1 back} to the outputs of the generators linear

frequency modulation 8 and 12 is formed linearly frequency-modulated signals. The presence of amplitude modulation of the signals F _GH and F ' _GH and their temporal arrangement is determined by the control pulses T ₁ and T ₁ received at the inputs 2 of the linear frequency modulation generators from the synchronizer 14. The synchronizer 14 generates from the signal F _on coming from the fifth output of the reference generator for 5 s controlled via the frequency divider with a variable division factor, pulse signals T _1, T _2, T _3, adjustable, control signals, a repetition frequency, duty cycle, and signals T _{1zad, 3zad} T, T _3zad, with a time delay, on you odes 1, 2, 4, 5, 6. At the output of the third synchronizer 14 on command from the control device is formed by modulating a pulse signal T ₄ supplied to the second input of the phase modulator 6 and the phase modulating signal F _np1 (F _'np1), passing through it and, accordingly, the modulating phase of each component of the spectrum of signals U1 and U2.

The first switch 13, by commands from the control device 16, switches the signals with frequencies F _PG and F ' _PG from inputs 1 and 3 to the output in combinations: either both signals F _PG and F' _PG (the mode of generating signals at the outputs 1Uo, 2Uo) ; either only F _PG (signal generation mode only at the output 1Uo); or only F ' _PG (signal generation mode only at the output 2Uo). Signals with frequencies F _np1 or F ' _np1 are generated in the first frequency converter 9 from a signal with a frequency F _on arriving at its second input from the third output of the support generator 5, and from a signal with a frequency F _GH or, respectively, from a signal with a frequency F ' _GH coming to its first input from the output of the first switch 13.

From the third output of the reference oscillator 5, the signal Foop is received at the second input of the first frequency converter 9, which is multiplied by the multiplication factor N to the frequency N × Foop. The first input of the first frequency converter 9 receives a signal Fпг or F'пг from the output of the first

switch and converted to the output signal F _PR. 1 = (Fop × N) -Fpg or F ' _pr. 1 = (Fop × N) -F'pg of the signal F _pr 1 (F' _pr.1 ) modulating pulse. Using the proposed multi-frequency signal shaper in the centimeter range modulated by frequency, amplitude and phase allows you to sequentially generate multi-frequency, coherently generated signals at two parallel outputs, consisting of a set of several signals with carriers switched over the frequency grid in order to obtain many sets of different composition, with amplitude frequency and phase modulations of all hour carriers by signals constituting a set, controlled relative time delay and frequency shift spectra multifrequency signals on a single output relative to another, that extends its functionality.

Claims (1)

The multi-frequency signal generator in the centimeter range modulated in frequency, amplitude and phase comprises a frequency synthesizer, a frequency multiplier, a first frequency converter, a reference generator, a second frequency converter, an amplitude modulator, a phase modulator, an adder, a first switch, a second switch, a first linear frequency modulation generator , a control device, wherein the first output of the frequency synthesizer is connected to the first input of the frequency multiplier, the first output of the reference generator is connected to the first frequency synthesizer, the third output of the reference generator is connected to the second input of the first frequency converter, the second output of the reference generator is connected to the first input of the first linear frequency modulation generator, the output of the first frequency converter is connected to the first input of the amplitude modulator, the output of the amplitude modulator is connected to the first input of the phase modulator , the output of the phase modulator is connected to the first input of the second frequency converter, characterized in that a second generator is additionally introduced frequency modulation, synchronizer, power divider, third switch, and the input of the control device is the input of the control signals of the operating modes of the multi-frequency signal driver in the centimeter range modulated in frequency, amplitude and phase, the fourth output of the reference oscillator is connected to the first input of the second linear frequency modulation generator, the fifth output of the reference oscillator is connected to the first input of the synchronizer, the output of the second linear frequency modulation generator is connected to the first during the first switch, the output of the first linear frequency modulation generator is connected to the third input of the first switch, the output of the first switch is connected to the first input of the first frequency converter, the fourth output of the control device is connected to the third input of the second linear frequency modulation generator, the third output of the control device is connected to the second input the first switch, the second output of the control device is connected to the third input of the first linear frequency modulation generator, the first output of the device The control is connected to the second input of the frequency synthesizer, the fifth output of the control device is connected to the second input of the synchronizer, the first output of the synchronizer is connected to the second input of the amplitude modulator, the third output of the synchronizer is connected to the second input of the phase modulator, the fourth output of the synchronizer is connected to the second input of the first linear frequency generator modulation, the second synchronizer output is connected to the second input of the second linear frequency modulation generator, the fifth synchronizer output under is connected to the second input of the second switch, the sixth output of the synchronizer is connected to the second input of the third switch, the second output of the frequency synthesizer is connected to the second input of the frequency multiplier, the third output of the frequency synthesizer is connected to the third input of the frequency multiplier, the fourth output of the frequency synthesizer is connected to the fourth input of the frequency multiplier, the fifth output of the frequency synthesizer is connected to the fifth input of the frequency multiplier, the first output of the frequency multiplier is connected to the first input of the adder, the second output of the frequency multiplier you are connected to the second input of the adder, the third output of the frequency multiplier is connected to the third input of the adder, the fourth output of the frequency multiplier is connected to the fourth input of the adder, the fifth output of the frequency multiplier is connected to the fifth input of the adder, the output of the adder is connected to the second input of the second frequency converter, the output of the second converter frequency is connected to the input of the power divider, the first output of the power divider is connected to the first input of the second switch, the output of which is the first output of the shaper gochastotnogo signal in the centimeter range modulated by frequency, amplitude and phase, a second power divider output coupled to a first input of the third switch, whose output is the second output of the multi-frequency signal in the centimeter range modulated by frequency, amplitude and phase.