RU173337U1 - DEVICE FORMATION OF FREQUENCIES OF DECIMETER RANGE OF WAVES - Google Patents

Abstract

The utility model relates to microwave technology and can be used in transmitting devices to form frequencies. The technical result of the claimed utility model is aimed at creating a device for forming frequencies of the decimeter wave range, providing operation with high stability and switching speed of carrier frequencies at three spaced frequencies. The device for forming the frequencies of the decimeter wave range includes a first reference generator; first phase locked loop, first low pass filter, first voltage controlled oscillator, high frequency switch; a second phase locked loop, a second low pass filter, a second voltage controlled oscillator, and a second reference oscillator. A signal from the first reference oscillator is supplied to the first input of the first phase locked loop and the first input of the second phase locked loop. 1 ill.

Description

The invention relates to microwave technology and can be used in transmitting devices to form carrier frequencies.

A frequency synthesizer is known from the prior art (Patent RU for utility model No. 100348, IPC: H03L 7/00, 2013), comprising a voltage controlled oscillator, a first low pass filter and a frequency synthesizer unit adapted to exchange control signals with an external control device , the first input of the frequency synthesizer block is the input of the reference frequency signal, and the second input is connected to the first output of the voltage-controlled generator, the first and second switches, the second low-pass filter and a buffer amplifier, the output of the synthesizer block the frequency mash is connected to the input of the first switch, the first and second outputs of which are connected through the first and second low-pass filters respectively to the first and second inputs of the second switch, the output of which is connected to the control input of the voltage-controlled generator, the second output of which is connected to the input of the buffer amplifier the output of which is the output of the device, the first and second switches are configured to supply them with control signals from an external control device.

The disadvantages of this frequency synthesizer include the lack of the possibility of combining in one operating mode the required small time of frequency tuning with the required small phase noise of the output signal, limiting the applicability of this device.

The closest in technical essence and the achieved result to the proposed technical solution is a high-speed frequency synthesizer (Patent RU for utility model No. 135468, IPC: H03L 7/00, 2013), containing the first block of the frequency synthesizer, the first input of which receives a signal from the reference generator , the first low-pass filter and the first voltage-controlled oscillator, the output of which is connected to the second input of the frequency synthesizer unit, the group of control inputs of which is connected to an external control bus via a control bus the device, a second voltage-controlled generator, a high-frequency switch, the output of which is the output of the device, and a second frequency synthesizer unit and a second low-pass filter connected in series to the control input of the second voltage-controlled generator, the output of the first frequency synthesizer through the first filter low-frequency is connected to the control input of the first generator, voltage-controlled, the output of which is also connected to the first input of the high-frequency switch, the second input of which is connected to the output of the second generator, controlled by voltage and the second input of the second block of the frequency synthesizer, the first input of which is supplied with a signal from the reference generator, and the group of control inputs of the second block of the frequency synthesizer is connected via the control bus to the group of control inputs of the high-frequency switch and external control device.

The technical problem solved by the creation of this utility model is that the frequency synthesizer blocks are controlled via the control bus from an external control device via the Serial Peripheral Interface (SPI), one of the frequency synthesizer blocks is configured during the operation of another frequency synthesizer block, which significantly reduces performance.

The technical result of the claimed utility model is aimed at creating a device for forming the frequencies of the decimeter wave range with high speed, providing work at three spaced frequencies, with high stability and switching speed of the carrier frequencies.

The technical result is achieved in that the device for forming the frequencies of the decimeter wave range contains a first reference generator; connected in series to the first phase locked loop, the first low-pass filter, and the first voltage controlled oscillator, the first output of which is connected to the second input of the first phase locked loop, the second output of the first voltage controlled oscillator is connected to the first input of the high-frequency switch; connected in series to the second phase-locked loop, the second low-pass filter, and the second voltage-controlled oscillator, the first output of which is connected to the second input of the second phase-locked loop, the second output of the second voltage-controlled generator is connected to the second input of the high-frequency switch, to the first the input of the first phase locked loop and the first input of the second phase locked loop receives a signal from the first reference oscillator, in addition it contains a second reference generator, the output of which is connected to the third input of the high-frequency switch, to the fourth input of which a start signal is received, the output of the high-frequency switch is the output of one of the signals received from the output of the first voltage-controlled generator, the second voltage-controlled generator and the second reference generator, the first phase-locked loop and the second phase locked loop are controlled by their external terminals, connected ny to a power source.

The essence of the claimed utility model is illustrated in the figure, which shows a functional diagram of a device for forming the frequencies of the decimeter wave range.

The device for forming the frequencies of the decimeter wave range contains a first reference generator (OG1) 1; connected in series are the first phase-locked loop (BFAP1) 2, the first low-pass filter (LPF1) 3, and the first voltage-controlled oscillator (VCO1) 4, the first output of which is connected to the second input of BFAPCH1 2, the second output of VCO1 4 is connected to the first input high-frequency switch (VK) 5; connected in series to the second phase-locked loop (BFAPCH2) 6, the second low-pass filter (LPF2) 7, and the second voltage-controlled oscillator (VCO2) 8, the first output of which is connected to the second input BFAPCH2 6, the second output of the VCO2 4 is connected to the second input high-frequency switch (VK) 5. In this case, the first inputs of BFAPCH1 2 and BFAPCH2 6 receive a signal from OG1 1. The third input of VK 5 receives a high-frequency signal from OG2 9. The fourth input (control input) of VK 5 receives a start signal. The output of VK 5 is the output of one of the signals received from the output of VCO1 4, VCO2 8 and OG2 9.

The device for forming the frequencies of the decimeter wave range works as follows. When power is supplied to the frequency shaping device: BFAPCH1 2 and BFAPCH2 6 go into DIRECT mode (blocks are controlled without using the SPI interface), the necessary division ratios R and N are recorded through the external outputs of BFAPCH1 2 and BFAPCH2 6 connected to the power source, VK 5 goes All_off mode (matched loads are connected to inputs 1, 2, 3).

The first input of BFAPCH1 2 receives a signal from OG1 1, the frequency of which is divided by R times (R integer) and is fed to one of the inputs of the frequency-phase detector, which is part of BFAPCH1 2.

The second input of BFAPCH1 2 receives a signal from the first output of VCO1 4, the frequency of which is divided by N times (N integer) and goes to the second input of the frequency-phase detector, which is part of BFAPCH1 2. Frequency-phase detector, which is part of BFAPCH1 2 compares the signals at the inputs and gives an error signal (the output voltage of the frequency-phase detector), which then goes to the input of the low-frequency filter 1 3, in which the high-frequency components of this signal are suppressed. Then, from the output of the LPF1 3, the signal goes to the control input of the VCO1 4, the frequency of the output signal of which changes until it is divided by N times in BFAPCH1 2, it becomes equal, divided by R times in BFAPCH1 2, the frequency of the signal OG1 1, arriving at the input of the frequency-phase detector, which is part of BFAPCH1 2.

When the equality of the frequencies of the signals at the inputs of the frequency-phase detector included in the BFAPCH1 2 occurs, the signal at its output ceases to change, and the frequency of the output signal at the first output of the VCO1 4 is maintained equal to the frequency of the OG1 signal multiplied by R times N times from the second output of VCO1 4 is supplied to the coordinated load of the first input of VK 5.

The first input of BFAPCH2 6 receives a signal from OG1 1, the frequency of which is divided by R times (R integer) and is fed to one of the inputs of the frequency-phase detector, which is part of BFAPCH2 6.

The second input of BFAPCH2 6 receives a signal from the first output of VCO2 8, the frequency of which is divided by N times (N integer) and goes to the second input of the frequency-phase detector, which is part of BFAPCH2 6. Frequency-phase detector, which is part of BFAPCH2 6 compares the signals at the inputs and gives an error signal (the output voltage of the frequency-phase detector), which then goes to the input of the low-pass filter 2 7, in which the high-frequency components of this signal are suppressed. Then, from the output of the LPF2 7, the error signal is fed to the control input of the VCO2 8, the frequency of the output signal of which changes until, divided by N times in BFAPCH2 6, it does not become equal to the frequency of the signal ОГ1 1 divided by R times in BFAPCH2 6 to the input of the frequency-phase detector, which is part of BFAPCH2 6.

When the equality of the frequencies of the signals at the inputs of the frequency-phase detector, which is part of the BFAPCH 6, occurs, the signal at its output ceases to change, and the frequency of the output signal at the first output of the VCO2 8 is maintained equal to the frequency of the signal OG1 1 times N times times the frequency. from the second output of the VCO2 8 is supplied to the coordinated load of the second input of VK 5.

The high-frequency signal from OG2 9 is supplied to the coordinated load of the third input of VK 5.

At the fourth input (control input) of VK 5, a start signal is received, which switches VK 5 to one of three positions and gives one of the signals received from the output of VCO1 4, VCO2 8 and OG2 9 to VC 5 output.

Claims (1)

A decimeter wave frequency forming apparatus comprising a first reference oscillator, a first phase locked loop, a first low pass filter and a voltage controlled first oscillator, the first output of which is connected to a second input of a first phase locked loop, a second output of a first oscillator controlled voltage, connected to the first input of the high-frequency switch, connected in series to the second phase-locked loop, the second filter three low frequencies and a second voltage-controlled oscillator, the first output of which is connected to the second input of the second phase-locked loop, the second output of the second voltage-controlled generator is connected to the second input of the high-frequency switch, to the first input of the first phase-locked loop and the first input of the second of the phase locked loop, a signal is supplied from the first reference generator, characterized in that, in addition, it contains a second reference generator, the output of which is connected to a high-frequency switch input, the fourth input of which triggers a signal, the high-frequency switch output is the output of one of the signals from the output of the first voltage-controlled oscillator, the second voltage-controlled oscillator and the second reference oscillator, control of the first phase-locked loop and the second block phase-locked loop is carried out through their external terminals connected to a power source.

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