RU103995U1 - SIGNAL FORMING DEVICE - Google Patents

Abstract

 The signal conditioning apparatus comprises a first frequency synthesizer, a reference generator, a signal distribution device, a frequency multiplier, a frequency converter, a first frequency driver, a first modulator, a second modulator, a first output of a signal distribution device is connected to a first input of a first frequency synthesizer, a fifth output of a signal distribution device is connected with the second input of the first modulator, the output of the frequency multiplier is connected to the second input of the frequency converter, the first output of the first modulator is Din with the fifth input of the first frequency driver, characterized in that it additionally introduces a frequency shaper and a splitter of the generated signals, a frequency corrector, a second frequency synthesizer, a second frequency shaper, the output of the first frequency synthesizer connected to the first input of the second frequency synthesizer, the first output of the series shaper frequency and splitter of the generated signals is connected to the second input of the first frequency synthesizer, the second output of the shaper of a number of frequencies and the splitter of the generated signal in is connected to the second input of the frequency multiplier, the third output of the frequency generator and the generated signal splitter is connected to the fourth input of the second modulator, the fourth output of the frequency generator and the generated signal splitter is the fifth output of the signal conditioning device, the fifth output of the frequency generator and the generated signal splitter is the sixth output of the signal conditioning device, the sixth output of the frequency former and the splitter of the generated signals is

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.

A device is known for generating discretely tunable frequency-stable signals [RU No. 77733, Н03С 5/00, 2002], comprising a frequency synthesizer, a frequency multiplier, an amplitude modulator, an adder, a pulse shaper, a first frequency converter, a reference generator, a second frequency converter, phase modulator, first switch, second switch, first linear frequency modulation generator, second linear frequency modulation generator, control device, synchronizer, second amplitude modulator, stub generator frequency, phase detector, first frequency divider, second frequency divider, first frequency driver, second frequency driver.

The closest in technical essence to the proposed utility model is a device for the formation of broadband spectra in the centimeter range [RU No. 71196 U1, IPC Н03С 5/00, 2006], comprising a frequency synthesizer, a frequency multiplier, a first frequency converter, a reference generator, a second converter frequency, amplitude modulator, control device, first phase modulator, frequency modulation generator and switch, second phase modulator, synchronizer and attenuator, moreover, the output of the frequency synthesizer is connected to the input frequency multiplier, the output of the frequency multiplier is connected to the second input of the first frequency converter, the first output of the reference generator is connected to the first input of the frequency grid synthesizer, the second output of the reference generator is connected to the first input of the second frequency converter, the third output of the reference generator is connected to the first input of the frequency modulation generator, the output of the first phase modulator is connected to the first input of the first frequency converter, the fourth output of the control device is connected to the second input of the switch , 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 second input of the frequency modulation generator, the third output of the control device is connected to the second input of the synchronizer, the fifth output of the control device is connected to the second input of the attenuator, the input of the control device is a signal input control modes of the device for forming broadband spectra in the centimeter range, the output of the frequency modulation generator is connected to the second input of the second frequency converter, the output of which is connected to the first input of the first phase modulator, the second input of the amplitude modulator is connected to the third output of the synchronizer, the second output of the synchronizer is connected to the second input of the second phase modulator, the output of which is connected to the first input of the amplitude modulator, the first output of the synchronizer is connected with the second input of the first phase modulator, the fourth output of the synchronizer is connected to the third input of the frequency modulation generator, the fourth output is the generator is connected to the first input of the synchronizer, the output of the first frequency converter is connected to the first input of the second phase modulator, the output of the amplitude modulator is connected to the first input of the switch, the second output of the switch is connected to the first input of the attenuator, the output of which is the second output of the broadband spectrometer in the centimeter range , and the first output of the switch is the first output of the device for the formation of broadband spectra in the centimeter range.

The disadvantages of the known devices is the inability to form radio signals at several outputs with various types of modulations satisfying the requirements for on-board master generators (BZG) in full.

The technical result of the proposed device for the formation of signals is the ability to generate radio signals at several outputs with various types of modulations satisfying the requirements for onboard BZG in full.

The essence of the proposed technical solution is that the signal conditioning apparatus comprises a first frequency synthesizer, a reference generator, a signal distribution device, a frequency multiplier, a frequency converter, a first frequency driver, a first modulator, and a second modulator. The first output of the signal distribution device is connected to the first input of the first frequency synthesizer, the fifth output of the signal distribution device is connected to the second input of the first modulator, the output of the frequency multiplier is connected to the second input of the frequency converter, the first output of the first modulator is connected to the fifth input of the first frequency generator. To achieve the possibility of generating signals, a frequency shaper and a splitter of the generated signals, a frequency corrector, a second frequency synthesizer, a second frequency shaper are introduced, moreover, the output of the first frequency synthesizer is connected to the first input of the second frequency synthesizer, the first output of a series of frequency shaper and a splitter of generated signals is connected to the second input of the first frequency synthesizer, the second output of the shaper of a number of frequencies and the splitter of the generated signals connected to the second input will multiply For frequency, the third output of the frequency generator and the splitter of the generated signals is connected to the fourth input of the second modulator, the fourth output of the frequency generator and the splitter of the generated signals is the fifth output U5 of the signal conditioning device, and the fifth output of the frequency generator and the splitter of the generated signals is the sixth output U6 of the device signal generation, the sixth output of the frequency shaper and the splitter of the generated signals is the seventh output U7 of the pho signal conditioning, the seventh output of the frequency shaper and the splitter of the generated signals is connected to the second input of the first frequency shaper, the eighth output of the frequency shaper and the splitter of the generated signals is connected to the third input of the first frequency shaper, the ninth output of the frequency shaper and the splitter of the generated signals is connected to the fourth input the first frequency former, the tenth output of the frequency former and the splitter of the generated signals is connected to the first input of the first modulator, the eleventh output of the frequency generator and the splitter of the generated signals is connected to the second input of the frequency corrector, the output of the reference generator is connected to the second input of the frequency generator and the splitter of the generated signals, the output of the frequency corrector is connected to the fifth input of the signal distribution device, the second output of the signal distribution device connected to the first input of the frequency shaper and the splitter of the generated signals, the third output of the signal distribution device in connected to the first input of the reference generator, the fourth output of the signal distribution device is connected to the first input of the frequency corrector, the sixth output of the signal distribution device is connected to the first input of the frequency multiplier, the seventh output of the signal distribution device is connected to the second input of the second frequency synthesizer, the eighth output of the signal distribution device connected to the first input of the first frequency driver, the ninth output of the signal distributor device is connected to the third input of the second modulator, the tenth output of the signal distribution device is connected to the second input of the second modulator, the eleventh output of the signal distribution device is connected to the third input of the second frequency driver, the twelfth output of the signal distribution device is connected to the second input of the second frequency driver, the thirteenth output of the signal distribution device is connected to the first input of the frequency converter, the first input of the signal distribution device is the first input Y1 of the signal conditioning device, the second input signal distribution device is the second input Y2 of the signal conditioning device, the third input of the signal distribution device is the third input Y3 of the signal conditioning device, the fourth input of the signal distribution device is the fourth input Y4 of the signal conditioning device, the output of the second frequency synthesizer is connected to the third input of the frequency converter, the first output the first driver is the eighth output U8 of the signal conditioning device, the second output of the first driver the one connected to the fifth input of the second frequency driver, the second output of the first modulator connected to the sixth input of the first frequency driver, the first output of the frequency converter is the first output U1 of the signal conditioning device, the second output of the frequency converter is the second output U2 of the signal conditioning device, the third output of the frequency converter is connected with the first input of the second frequency driver, the first output of the second frequency driver is the third output U3 of the signal conditioning apparatus, the second output of the second frequency driver is the fourth output U4 of the signal conditioning device, the third output of the second frequency driver is connected to the first input of the second modulator, the fourth input of the second frequency driver is the fifth input Y5 of the signal conditioning device, the output of the second modulator is the ninth output U9 of the signal conditioning device, fifth the input of the second modulator is the sixth input Y6 of the signal conditioning apparatus.

Figure 1 presents the functional diagram. signal conditioning devices.

The signal conditioning apparatus comprises a first frequency synthesizer 1, a series of frequency shaper and a generated signal splitter 2, a reference generator 3, a frequency corrector 4, a signal distribution device 5, a second frequency synthesizer 6, a frequency multiplier 7, a first frequency shaper 8, a first modulator 9, a converter frequency 10, the second frequency driver 11, the second modulator 12.

The output of the first frequency synthesizer 1 is connected to the first input of the second frequency synthesizer 6.

The first output of the shaper of a number of frequencies and the splitter of the generated signals 2 is connected to the second input of the first frequency synthesizer 1.

The second output of the shaper of a number of frequencies and the splitter of the generated signals 2 is connected to the second input of the frequency multiplier 7.

The third output of the shaper of a number of frequencies and the splitter of the generated signals 2 is connected to the fourth input of the second modulator 12.

The fourth output of the frequency former and the splitter of the generated signals 2 is the fifth output U5 of the signal conditioning apparatus.

The fifth output of the frequency shaper and the splitter of the generated signals 2 is the sixth output U6 of the signal conditioning apparatus.

The sixth output of the frequency former and the splitter of the generated signals 2 is the seventh output U7 of the signal conditioning apparatus.

The seventh output of the shaper of a number of frequencies and the splitter of the generated signals 2 is connected to the second input of the first frequency shaper 8.

The eighth output of the shaper of a number of frequencies and the splitter of the generated signals 2 is connected to the third input of the first frequency shaper 8.

The ninth output of the shaper of a number of frequencies and the splitter of the generated signals 2 is connected to the fourth input of the first frequency shaper 8.

The tenth output of the shaper of a number of frequencies and the splitter of the generated signals 2 is connected to the first input of the first modulator 9.

The eleventh output of the shaper of a number of frequencies and the splitter of the generated signals 2 is connected to the second input of the frequency corrector 4.

The output of the reference generator 3 is connected to the second input of the shaper of a number of frequencies and the splitter of the generated signals 2,

The output of the frequency corrector 4 is connected to the fifth input of the signal distribution device 5.

The first output of the signal distribution device 5 is connected to the first input of the first frequency synthesizer 1.

The second output of the signal distribution device 5 is connected to the first input of the splitter 2.

The third output of the signal distribution device 5 is connected to the first input of the reference generator 3.

The fourth output of the signal distribution device 5 is connected to the first input of the frequency corrector 4.

The fifth output of the signal distribution device 5 is connected to the second input of the first modulator 9.

The sixth output of the signal distribution device 5 is connected to the first input of the frequency multiplier 7.

The seventh output of the signal distribution device 5 is connected to the second input of the second frequency synthesizer 6.

The eighth output of the signal distribution device 5 is connected to the first input of the first frequency driver 8.

The ninth output of the signal distribution device 5 is connected to the third input of the second module mount 12.

The tenth output of the signal distribution device 5 is connected to the second input of the second modulator 12.

The eleventh output of the signal distribution device 5 is connected to the third input of the second frequency driver 11.

The twelfth output of the signal distribution device 5 is connected to the second input of the second frequency driver 11.

The thirteenth output of the signal distribution device 5 is connected to the first input of the frequency converter 10.

The first input of the signal distribution device 5 is the first input Y1 of the signal conditioning apparatus.

The second input of the signal distribution device 5 is the second input Y2 of the signal conditioning apparatus.

The third input of the signal distribution device 5 is the third input Y3 of the signal conditioning apparatus.

The fourth input of the signal distribution device 5 is the fourth input Y4 of the signal conditioning apparatus.

The output of the second frequency synthesizer 6 is connected to the third input of the frequency converter 10.

The output of the frequency multiplier 7 is connected to the second input of the frequency converter 10.

The first output of the first frequency driver 8 is the eighth output U8 of the signal conditioning apparatus.

The second output of the first frequency driver 8 is connected to the fifth input of the second frequency driver 11.

The first output of the first modulator 9 is connected to the fifth input of the first formed frequency 8.

The second output of the first modulator 9 is connected to the sixth input of the first frequency driver 8.

The first output of the frequency converter 10 is the first output U1 of the signal conditioning apparatus.

The second output of the frequency converter 10 is the second output U2 of the signal conditioning apparatus.

The third output of the frequency converter 10 is connected to the first input of the second frequency driver 11.

The first output of the second frequency driver 11 is the third output U3 of the signal conditioning apparatus.

The second output of the second frequency driver 11 is the fourth output U4 of the signal conditioning apparatus.

The third output of the second frequency driver 11 is connected to the first input of the second modulator 12.

The fourth input of the second frequency driver 11 is the fifth input Y5 of the signal conditioning apparatus.

The output of the second modulator 12 is the ninth output U9 of the signal conditioning apparatus.

The fifth input of the second modulator 12 is the sixth input Y6 of the signal conditioning apparatus.

The signal conditioning device (Figure 1) works as follows:

The first frequency synthesizer 1 from the signal fop entering the second input from the first output of the frequency shaper and the splitter of the generated signals 2, when the voltage is supplied to the first input and the frequency control code from the first output of the signal distribution device 5, forms a frequency grid fci at its output coherent to the frequency fop. The signal fci, with the frequency set in accordance with the incoming code, is fed to the first input of the second frequency synthesizer 6.

The generator of a number of frequencies and the splitter of the generated signals 2, when a voltage is supplied to the first input from the second output of the signal distribution device 5, from the 2 · fop signal at the second input coming from the output of the reference generator 3, generates signals: - at the first, fourth, fifth , sixth, tenth and eleventh outputs, signals with a frequency fop; - at the second output, a signal with a frequency of 2 · fop; - at the third output, a signal with a frequency of 4 · fop; - at the seventh and eighth outputs, signals with a frequency of K · fop; - at the ninth output, a signal with a frequency fpr2. These signals are received: - from the first output to the second input of the first frequency synthesizer 1; - from the second output to the second input of the frequency multiplier 7; - from the third output to the second input of the second modulator 12; - from the fourth, fifth and sixth outputs, respectively, to the fifth U5, sixth U6 and seventh U7 outputs of the signal conditioner; - from the seventh, eighth and ninth outputs, respectively, to the second third and fourth inputs of the first frequency driver 8; - from the tenth output to the first input of the first modulator 9; - from the eleventh output to the second input of the frequency corrector 4.

The reference generator 3, which is a generator of the reference frequency Fkg with the possibility of adjusting the frequency and phase of oscillation (KGUN), when the voltage is supplied to the first input from the third output of the signal distribution device 5, it generates a signal with a frequency Fkg arriving at the second input of the row shaper frequencies and splitter of the generated signals 2.

A frequency corrector 4, designed to correct the frequency and increase the stability of a quartz controlled oscillator (KGUN) - reference oscillator 3, with the help of its PLL (phase-locked loop) and built-in precision thermostatic quartz oscillator, generates a signal fupr., arriving at the eleventh input of the signal distribution device 5, and from its fourth output, at the first input of the reference generator 3.

Signal distribution device 5, from control signals and supply voltages. arriving at the first, second and third inputs, which are, respectively, the first Y1, second Y2 and third Y3 inputs, the signal conditioning device, at its outputs, from the first to the eighth, tenth, eleventh, twelfth and thirteenth, generates supply voltages, codes and management team, and the outputs of nine and eleven forms the video pulse signals E _Σ; from the video of the pulsed signal D _∑ entering the fourth input from the fourth input Y4 of the signal conditioning apparatus. The signals generated by the signal distribution device 5, from the first output go to the first input of the first frequency synthesizer 1, from the second output - to the first input of the frequency shaper and splitter of the generated signals 2, from the third output - to the first input of the reference generator 3, from the fourth output - to the first input of the frequency corrector 4, from the fifth output - to the second input of the first modulator 9, from the sixth output - to the first input of the frequency multiplier 7, from the seventh output - to the second input of the second frequency synthesizer 6, from the eighth output - to the the first input of the first frequency driver 8, from the ninth output to the third input of the second modulator 12, from the tenth output to the second input of the second modulator 12, from the eleventh output to the third input of the second frequency driver 11, from the twelfth output to the second input of the second driver frequencies 11, from the thirteenth output to the first input of the frequency converter 10.

The second frequency synthesizer 6 filters the input signals fci received at the first input from the output of the first frequency synthesizer 1 when a voltage is supplied to the second input and a code that switches the filter in accordance with the frequency of the received signal fci. The signal fci from the output of the second frequency synthesizer 6 is fed to the third input of the frequency converter 10.

Frequency multiplier 7, from a 2 · fop signal supplied to the second input from the second output of a series of frequency former and a splitter of generated signals 2, upon supplying the first input of supply voltages and control commands, generates N · fop signals, where N, upon receipt corresponding command can take values N = N1, N2 ... Nn. The signal N · fop from the output of the frequency multiplier 7 is supplied to the second input of the frequency converter 10.

The first frequency driver 8, when the voltage is supplied to the second input from the fifth output of the signal distribution device 5, generates the following signals at the first and second outputs: - at the second output, from the signal K · fop at the second input coming from the seventh output of the frequency generator and the splitter of the generated signals 2 and from the signal fmpr1 arriving at the fifth input from the first output of the first modulator 9, generates a signal fpr1 = K · fop + fmpr1, which is fed to the fifth input of the second frequency former 11; - at the first output, from the signal K · fop at the third input coming from the eighth output of the frequency series former and the splitter of the generated signals 2, from the fpr2 signal coming to the fourth input from the ninth output of the frequency series former and the splitter of the generated signals 2 and from the fmg2 signal coming to the sixth input from the second output of the first modulator 9 generates a signal fg2 = K · fop-fpr2 + fmg2, which goes to the eighth output U8 of the signal conditioning device.

The first modulator 9, upon supplying the second input of supply voltages, control commands and codes from the fifth output of the signal distribution device 5, from the signal fop at the first input coming from the tenth output of the frequency generator and the splitter of the generated signals 2, generates at the first and second outputs signals, respectively, fmp1 and fmg2, respectively, arriving at the fifth and sixth inputs of the first frequency driver 8 in two modes: - mode without modulation, i.e. fmpr1 = fop, fmg2 = fop, and several modes with frequency modulation, depending on the received codes and control commands.

Frequency converter 10, from the fci signal at the third input coming from the output of the second frequency synthesizer 6 and from the N · fop signal at the second input coming from the output of the frequency multiplier 7, at the first input of the supply voltage and control commands from the thirteenth output of the distribution device of signals 5, generates signals fg1i / 4 = N · fop + fci at its three outputs, coming from the first output to the first output U1 of the signal conditioning device, from the second output to the second output U2 of the signal conditioning device, from the third output to the first input of the second frequency generator 11.

The second frequency driver 11, from the signal fг1i / 4 at the first input received from the third output of the frequency converter 10, and from the signal fpr1 at the fifth input, received from the second output of the first frequency converter 8, upon receipt, to the second input of the supply voltages and control commands a twelfth output signals distribution device 5, and the third video input pulse signal D _Σ eleventh output signals distribution device 5, and the fourth video input of the pulse signal D from the fifth input _π Y5 forming apparatus ignals, generates at its three outputs signals foi = 4 · fg1i / 4 + fpr1, coming from the first output to the third output U3 of the signal conditioning device, from the second output to the fourth output U4 of the signal conditioning device, and from the third output to the first input of the second modulator 12, the signals formed in modes PAM (pulse amplitude modulation), and FKM mode (phase-code modulation), depending on the state of the video pulse signals D and D _{Σ π,} respectively independently turned on and off when you receive respective Koman q control, the signal level at the second output is controlled by code commands.

The second modulator 12, from the foi signal at the first input received from the third output of the second frequency driver 11, upon receipt, to the second input of the supply voltage and control commands from the tenth output of the signal distribution device 5, to the third input of the video pulse signal D _∑ from the ninth output signal distribution device 5, to the fourth input of the video pulse signal D _{π shchfkm} from the sixth input Y6 of the signal conditioning device, and to the fourth input of the signal 4 · fop from the third output of the frequency former and the splitter 2 signals, it generates the output signal foi with AIM, when a video pulse signal D _∑ arrives and with a BFKM (broadband phase-code modulation) when a video pulse signal D _{π shfkm arrives} , amplifies the output signal to the required value and continuously adjusts the output signal power within the required limits upon receipt of appropriate control signals. The signal foi from the output of the second modulator 12 is supplied to the ninth output U9 of the signal conditioning apparatus. The technical result of the proposed device for the formation of signals is the ability to generate radio signals at several outputs with different types of modulations that satisfy the requirements for onboard BZG in full.

Claims (1)

The signal conditioning apparatus comprises a first frequency synthesizer, a reference generator, a signal distribution device, a frequency multiplier, a frequency converter, a first frequency driver, a first modulator, a second modulator, a first output of a signal distribution device is connected to a first input of a first frequency synthesizer, a fifth output of a signal distribution device is connected with the second input of the first modulator, the output of the frequency multiplier is connected to the second input of the frequency converter, the first output of the first modulator is Din with the fifth input of the first frequency driver, characterized in that it additionally introduces a frequency shaper and a splitter of the generated signals, a frequency corrector, a second frequency synthesizer, a second frequency shaper, the output of the first frequency synthesizer connected to the first input of the second frequency synthesizer, the first output of the series shaper frequency and splitter of the generated signals is connected to the second input of the first frequency synthesizer, the second output of the shaper of a number of frequencies and the splitter of the generated signal in connected to the second input of the frequency multiplier, the third output of the frequency generator and the generated signal splitter is connected to the fourth input of the second modulator, the fourth output of the frequency generator and the generated signal splitter is the fifth output of the signal conditioning device, the fifth output of the frequency generator and the generated signal splitter is the sixth output of the signal conditioning apparatus, the sixth output of the series frequency former and the splitter of the generated signals is I am the seventh output of the signal conditioning device, the seventh output of the frequency generator and the splitter of the generated signals is connected to the second input of the first frequency driver, the eighth output of the frequency generator and the splitter of the generated signals is connected to the third input of the first frequency driver, the ninth output of the frequency generator and the formed signal splitter connected to the fourth input of the first frequency driver, the tenth output of a series of frequency driver and a generated signal splitter alov is connected to the first input of the first modulator, the eleventh output of the frequency range former and the splitter of the generated signals is connected to the second input of the frequency corrector, the output of the reference generator is connected to the second input of the frequency range former and the splitter of the generated signals, the output of the frequency corrector is connected to the fifth input of the signal distribution device, the second output of the signal distribution device is connected to the first input of the shaper of a number of frequencies and the splitter of the generated signals, the third output is signal distribution devices are connected to the first input of the reference generator, the fourth output of the signal distribution device is connected to the first input of the frequency corrector, the sixth output of the signal distribution device is connected to the first input of the frequency multiplier, the seventh output of the signal distribution device is connected to the second input of the second frequency synthesizer, the eighth output of the device signal distribution is connected to the first input of the first frequency driver, the ninth output of the signal distribution device is connected to third by the second input of the second modulator, the tenth output of the signal distribution device is connected to the second input of the second modulator, the eleventh output of the signal distribution device is connected to the third input of the second frequency driver, the twelfth output of the signal distribution device is connected to the second input of the second frequency driver, the thirteenth output of the signal distribution device is connected to the first input of the frequency converter, the first input of the signal distribution device is the first input of the device signal, the second input of the signal distribution device is the second input of the signal conditioning device, the third input of the signal distribution device is the third input of the signal conditioning device, the fourth input of the signal distribution device is the fourth input of the signal conditioning device, the output of the second frequency synthesizer is connected to the third input of the frequency converter, the first output of the first frequency driver is the eighth output of the signal conditioning device, the second output of the first frequency driver is connected to the fifth input of the second frequency driver, the second output of the first modulator is connected to the sixth input of the first frequency driver, the first output of the frequency converter is the first output of the signal conditioning device, the second output of the frequency converter is the second output of the signal conditioning device, the third output of the frequency converter is connected with the first input of the second frequency driver, the first output of the second frequency driver is the third output of the device signals, the second output of the second frequency driver is the fourth output of the signal conditioning device, the third output of the second frequency driver is connected to the first input of the second modulator, the fourth input of the second frequency driver is the fifth input of the signal conditioning device, the output of the second modulator is the ninth output of the signal conditioning device, fifth the input of the second modulator is the sixth input of the signal conditioning device.