RU70422U1 - COMPOSITOR OF COMPOSITE MULTI-FREQUENCY SIGNAL IN THE CENTIMETER RANGE - 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 of a composite multi-frequency pulse signal. The centimeter-range composite multi-frequency signal generator comprises a frequency synthesizer (1), a frequency multiplier (2), a first frequency converter (5), a reference generator (4), a second frequency converter (6), a pulse shaper (9), a control device (8) . The first input of the frequency synthesizer (1) is connected to the first output of the reference generator (4), the first output of the frequency synthesizer (1) is connected to the first input of the frequency multiplier (2), the third output of the reference generator (4) is connected to the second input of the first frequency converter (5) ), the output of the second frequency converter (6) is the output of the shaper of the composite multi-frequency signal of the centimeter range. To generate a composite pulse signal, consisting of several successive video pulsed, coherently generated signals of different carrier frequencies, a shear frequency generator is introduced (7). The input of the control device (8) is the input of the control signals of the operating mode of the shaper of the composite multi-frequency signal of the centimeter range, the first output of the control device (8) is connected to the second input of the frequency synthesizer (1), the second output of the control device (8) is connected to the input of the pulse shaper (9) ), the first output of the pulse former (9) is connected to the sixth input of the amplitude modulator (3), the second output of the pulse former (9) is connected to the seventh input of the amplitude modulator (3), the third output is formed I pulse (9) is connected to an eighth input of the amplitude modulator (3), the fourth output pulse shaper (9) is connected to a ninth input

amplitude modulator (3), the fifth output of the pulse shaper (9) is connected to the tenth input of the amplitude modulator (3), the second output of the reference generator (4) is connected to the input of the shear frequency generator (7), the output of the shear frequency generator (7) is connected to the first the input of the first frequency converter (5). 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 amplitude modulator (3), the second output of the frequency multiplier (2) is connected to the second input of the amplitude modulator (3), the third output of the frequency multiplier (2) is connected to the third input of the amplitude modulator (3) . The fourth output of the frequency multiplier (2) is connected to the fourth input of the amplitude modulator (3), the fifth output of the frequency multiplier (2) is connected to the fifth input of the amplitude modulator (3). The output of the amplitude modulator (3) is connected to the first input of the second frequency converter (6), and the second input is connected to the output of the first frequency converter (5), 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 of a composite multi-frequency pulse signal.

Known multi-frequency generator device [RU No. 2076549 C1, 6 H03B 5/18, 1997], containing N, where N = 2, 3 ... connected to a common load via an N-channel switch or adder microwave oscillators, each which contains an amplifier and a feedback circuit made in the form of a bandpass filter on a dielectric resonator and connected between the input and output of the amplifier, characterized in that the active elements of all the oscillators are directly connected to the power source, and in the feedback circuit of each autogenerator torus introduced p-i-n-diode phase shifter arranged to phase imbalance in the oscillator.

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 generator is connected to the input of the frequency divider, the frequency 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. First exit

the 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 form a composite pulse signal, consisting of several, one after another video pulsed, coherently generated signals of different carrier frequency.

The technical result of the proposed shaper of a composite multi-frequency signal in the centimeter range is the ability to generate a composite pulse signal consisting of several successive video pulsed, coherently generated signals of different carrier frequencies.

The essence of the proposed technical solution lies in the fact that the shaper of the composite multi-frequency signal in the centimeter range contains a frequency synthesizer, a frequency multiplier, an amplitude modulator, a first frequency converter, a reference generator, a second frequency converter, a pulse shaper, a control device. The first input of the frequency synthesizer is connected to the first output of the reference generator, the first output of the frequency synthesizer is connected to the first input of the frequency multiplier, the third output of the reference generator is connected to the second input of the first frequency converter, the output of the second frequency converter is the output of the shaper of the composite multi-frequency signal in the centimeter range.

New in the proposed utility model is that a shear frequency generator is introduced, and the input of the control device is the input of the control signals of the operating mode of the shaper of the composite multi-frequency signal in the centimeter range, the first output of the control device is connected to the second input of the frequency synthesizer, the second output of the control device is connected to shaper input

pulses, the first output of the pulse shaper is connected to the sixth input of the amplitude modulator, the second output of the pulse shaper is connected to the seventh input of the amplitude modulator, the third output of the pulse shaper is connected to the eighth input of the amplitude modulator, the fourth output of the pulse shaper is connected to the ninth input of the amplitude modulator, the fifth output of the pulse shaper connected to the tenth input of the amplitude modulator, the second output of the reference generator is connected to the input of the shear frequency generator, output q the shear frequency generator is connected to the first input of the first frequency converter. 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 amplitude modulator, the second output of the frequency multiplier is connected to the second input of the amplitude modulator, the third output of the frequency multiplier is connected to the third input of the amplitude modulator. The fourth output of the frequency multiplier is connected to the fourth input of the amplitude modulator, the fifth output of the frequency multiplier is connected to the fifth input of the amplitude modulator. The output of the amplitude modulator is connected to the first input of the second frequency converter, and the second input is connected to the output of the first frequency converter.

Figure 1 presents the functional diagram of the shaper of the composite multi-frequency signal in the centimeter range.

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 arrangement in the frequency domain of the signals Uo at the output of the device

Figure 3 presents a timing diagram of the operation of the device.

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

The shaper of a multi-frequency composite signal in the centimeter range contains a frequency synthesizer 1, a frequency multiplier 2, an amplitude modulator 3, a reference generator 4, a first frequency converter 5, a second frequency converter 6, a shift frequency generator 7, a control device 8, a pulse shaper 9.

The first input of the control device 8 is the input of the control signals of the operating modes of the shaper of the composite multi-frequency signal in the centimeter range.

The first input of the frequency synthesizer 1 is connected to the first output of the reference generator 4.

The second input of the frequency synthesizer 1 is connected to the first output of the control device 8.

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

The third output of the reference generator 4 is connected to the second input of the first frequency converter 5.

The second output of the reference generator 4 is connected to the input of the shear frequency generator 7.

The output of the shear frequency generator 7 is connected to the first input of the first frequency converter 5.

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 pulse shaper 9 is connected to the sixth input of the amplitude modulator 3.

The second output of the pulse shaper 9 is connected to the seventh input of the amplitude modulator 3.

The third output of the pulse shaper 9 is connected to the eighth input of the amplitude modulator 3.

The fourth output of the pulse shaper 9 is connected to the ninth input of the amplitude modulator 3.

The fifth output of the pulse shaper 9 is connected to the tenth input of the amplitude modulator 3.

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

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

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

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

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

The output of the amplitude modulator 3 is connected to the first input of the second frequency converter 6.

The output of the second frequency converter 6 is the output of the shaper of the composite multi-frequency signal in the centimeter range.

The second input of the second frequency converter 6 is connected to the output of the first frequency converter 5.

Frequency synthesizer 1, an example of which is shown in Fig. 4, consists of a frequency divider 10, a second frequency multiplier 11, a third frequency multiplier 12, a fourth frequency multiplier 13, a fifth frequency multiplier 14, a sixth frequency multiplier 15, a seventh frequency multiplier 16, and an eighth frequency multiplier 17, ninth frequency multiplier 18, tenth frequency multiplier 19, eleventh frequency multiplier 20, twelfth frequency multiplier 21, thirteenth frequency multiplier 22, switch 23, third frequency converter 24, fourth p eobrazovatelya frequency 25, a fifth inverter 26, inverter 27, the sixth, the seventh inverter 28.

The input of the frequency divider 10 is connected to the combined inputs of the eleventh 20, twelfth 21 and thirteenth 22 frequency multipliers and is the first input of the frequency synthesizer 1.

The first output of the eleventh frequency multiplier 20 is connected to the first input of the third frequency converter 24.

The first output of the twelfth frequency multiplier 21 is connected to the first input of the fourth frequency converter 25.

The second output of the twelfth frequency multiplier 21 is connected to the first input of the fifth frequency converter 26.

The first output of the thirteenth frequency multiplier 22 is connected to the first input of the sixth frequency converter 27.

The second output of the thirteenth frequency multiplier 22 is connected to the first input of the seventh frequency converter 28.

The outputs of the second 11, third 12, fourth 13, fifth 14, sixth 15, seventh 16, eighth 17, ninth 18 and tenth 19 frequency multipliers are connected respectively to the second, third, fourth, fifth, sixth, seventh, eighth, ninth and tenth inputs switch 23.

The first output of the switch 23 is connected to the second input of the third frequency converter 24.

The second output of the switch 23 is connected to the second input of the fourth frequency converter 25.

The third output of the switch 23 is connected to the second input of the fifth frequency converter 26.

The fourth output of the switch 23 is connected to the second input of the sixth frequency converter 27.

The fifth output of the switch 23 is connected to the second input of the seventh frequency converter 28.

The outputs of the third 24, fourth 25, fifth 26, sixth 27 and seventh 28 frequency converters are the first, second, third, fourth and fifth outputs of the frequency synthesizer 1, and the first input of the switch 23 is the second input of the frequency synthesizer 1.

The shaper of the composite multi-frequency signal in the centimeter range (Figure 1) works as follows:

Frequency synthesizer 1 (Figure 4) coherently generates frequency networks of signals at its, in the presented example, five outputs: - at the first output Fci (from the output of the third frequency converter 24); - at the second output Fcj (from the output of the fourth frequency converter 25); - at the third output Fck (from the output of the fifth frequency converter 26); - at the fourth output of Fcl (from the output of the sixth frequency converter 27); - at the fifth output Fcm (from the output of the seventh frequency converter 28). The output signals are generated from the input signal Fo, arriving at the first input of the frequency synthesizer 1 from the first output of the reference generator 4, and their carrier frequency is switched by control signals at its second input. The signal Foop is supplied to the frequency divider 10 and is divided by the division coefficient n, up to the frequency F, _{synth step,} which determines the minimum step of tuning the output frequencies Fci, Fcj, Fck, Fcl, Fcm of the synthesizer 1. Signal F _{step synt.} arrives at nine, in the submitted

for example, frequency multipliers from the second to the tenth (11 ... 19) with multiplication factors N ₄ , N ₄ +1, N ₄ +2 ..., N ₄ +8 (increasing by one). At the outputs of these frequency multipliers (11 ... 19), 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 synth} , and which then go to the nine, in the presented example, inputs, from the second to the tenth, of the switch 23. From the second input of the frequency grid synthesizer 1, the control signals are received at the first input of the switch 23, which, depending on the choice of frequency values of the signals Fci , Fcj, Fck, Fcl, Fcm, form on the five, in the presented example, outputs, from the first to the fifth, switch 23, the frequencies of the stands from FP1 to FP9, which are fed to the second inputs, from the third to the seventh, of five frequency converters (24 ... 28). The first inputs, from the third to the seventh, of the five frequency converters (24 ... 28) receive signals from the outputs, in our example, three, from the eleventh to the thirteenth frequency multipliers (20, 21, 22), in which the signal Fo on their inputs, multiplied by the multiplication factors N ₁ , N ₂ and N ₃ , respectively. The signals Fci, Fcj, Fck, Fcl, Fcm, (Fig. 2a) formed at five outputs one through five in the frequency synthesizer 1 are fed to the five inputs of the frequency multiplier 2, which contains, in the presented example, five multiplication channels in which multiplication occurs the frequency of the signals at 4 at its input to the values, respectively, Ai, Aj, Ak, Al, Am at the output (Fig.2b). Further, the signals Ai, Aj, Ak, Al, Am, from the five outputs of the frequency multiplier 2, are fed to the five inputs of the amplitude modulator 3, containing five switching channels in which the input signals are sequentially switched to a single output. Five inputs from the sixth to tenth amplitude modulator 3 from the first to fifth outputs of the pulse shaper 9, according to the control signals from the second output of the control device 8 at the input of the pulse shaper 9, modulating pulses are received, respectively, T ₁ , T ₂ , T ₃ , T ₄ , T ₅ (Figure 3).

At the output of the amplitude modulator 3, a composite pulse signal is formed, consisting of several (from 2 to 5 + α, where α is any number), successive videos of pulsed, coherently generated signals differing in the carrier frequency Ai; Aj; Ak; Al; Am, each of which has the ability to switch in frequency. This ensures the combination of the number of video pulses (from 2 to 5 + α, where α is any number) in the generated sequence and the frequency of the video pulsed video signals.

From the third output of the reference generator 4 to the second input of the first frequency converter 5 (Figure 4), a signal Foop is received, which is multiplied by the multiplication factor N to the frequency N × Foop. The first input of the frequency converter 5 receives the signal Fsdv. The signal Fsdv is generated in the shear frequency generator 7 from the signal Fop, which is fed to its input from the second output of the reference oscillator 4. From the output of the converter 5, the signal F _pr. 1 = (Fop × N) -Fsdv goes to the output of the second frequency converter 6.

At the first input of the second frequency converter 6, a signal is generated at the output of the amplitude modulator 3. In the second frequency converter 6, the frequency spectrum is transferred at its first input in the direction of increasing the signal frequency Fpr.1.

At the output of the second frequency converter 6, which is the output of the multi-frequency signal driver in the centimeter range, a composite pulse signal Uo is formed, consisting of several (from 2 to 5 + α, where α is any number), video pulses that follow without pause different carrier frequency F ₀ i = Ai + F _{pr 1} ; F ₀ J = Aj + F _pr . ₁ ; F ₀ k = Ak + F _{pr 1} ; F ₀ l = Al + F _{pr 1} ; F ₀ m = Am + F _{pr 1} , each of which has the ability to switch in frequency in a given range. This ensures the combination of the number of video pulses (five on the graph) in the generated sequence (Fig.3) and the carrier frequency (Fig.2c).

Using the proposed shaper of a multi-frequency signal in the centimeter range allows you to generate a composite pulse signal, consisting of several, one after another, coherently generated video pulse signals of different carrier frequency.

Claims (1)

The centimeter-range composite multi-frequency signal generator comprises a frequency synthesizer, a frequency multiplier, a first frequency converter, a reference generator, a second frequency converter, a pulse shaper, a control device, the first input of the frequency synthesizer being connected to the first output of the reference generator, the first output of the frequency synthesizer connected to the first the input of the frequency multiplier, the third output of the reference generator is connected to the second input of the first frequency converter, the output of the second dividing the frequency is the output of the shaper of the composite multi-frequency signal in the centimeter range, characterized in that the shift frequency generator is additionally introduced, the input of the control device being the input of the control signals of the operating mode of the shaper of the composite multi-frequency signal in the centimeter range, the first output of the control device is connected to the second input of the frequency synthesizer , the second output of the control device is connected to the input of the pulse shaper, the first output of the pulse shaper with is single with the sixth input of the amplitude modulator, the second output of the pulse shaper is connected to the seventh input of the amplitude modulator, the third output of the pulse shaper is connected to the eighth input of the amplitude modulator, the fourth output of the pulse shaper is connected to the ninth input of the amplitude modulator, the fifth output of the pulse shaper is connected to the tenth input of the amplitude modulator , the second output of the reference oscillator is connected to the input of the shear frequency generator, the output of the shear frequency generator is connected to the first input the house of the first frequency converter, 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 the output of the frequency multiplier is connected to the first input of the amplitude modulator, the second output of the frequency multiplier is connected to the second input of the amplitude modulator, the third output is nozhitelya frequency is connected to the third input of the amplitude modulator, the fourth output frequency multiplier is connected to fourth input of the amplitude modulator, the fifth frequency multiplier output connected to fifth input of the amplitude modulator. The output of the amplitude modulator is connected to the first input of the second frequency converter, and the second input is connected to the output of the first frequency converter.