RU135468U1 - FAST FREQUENCY SYNTHESIS - Google Patents

Abstract

A frequency synthesizer containing a first frequency synthesizer block (BCH1), the first input of which receives a signal from the reference generator, a first low-pass filter (LPF1) and a first voltage-controlled generator (VCO1), the output of which is connected to the second input of the BCH1, a group of control inputs which, using the control bus, is connected to an external control device, characterized in that a second voltage-controlled generator (VCO2), a high-frequency switch (VK), the output of which is the output of the device, and the second block of the frequency synthesizer (BCH2) and the second low-pass filter (LPF2), the output of which is connected to the control input of the VCO2, the output of the BSC1 through the LPF1 is connected to the control input of the VCO1, the output of which is also connected to the first input of the VC, the second input of which connected to the output of the VCO2 and the second input of the BSCH2, the first input of which receives a signal from the reference generator, and the group of control inputs of the BSCH2 is connected to the group of control inputs of the VC and to an external control device using the control bus.

Description

The utility model relates to radio engineering and can be used to form a grid of stable frequencies with a uniform pitch in the receiving and transmitting devices.

In modulators of radio transmitters and local oscillators of radio receivers of connected equipment, frequency synthesizers (MF) are used, based on a phase-locked-loop frequency-locked loop (IFAPCH). The main requirements for such devices include reducing the level of phase noise and spurious spectral components of the output signal of the midrange, reducing the frequency tuning time.

Frequency synthesizers with IFAP are widely known in the technical literature [1], [2], [3], etc. Such MFs allow one to obtain harmonic oscillations with a given frequency step, and the frequency stability is determined by a precision quartz reference oscillator. However, frequency synthesizers based on the IFAPH have a significant level of secondary spectral components and phase noise in their output signal.

The functional diagram of a typical midrange is shown in Fig.5.15 p.142 in the book [4].

In such an MF, a reference generator is connected to the first input of the frequency-phase detector (PFD) (more precisely, after a divider by 4), and the output voltage from the voltage-controlled generator (VCO) is connected to the second input of the PFD. The output of the PFD through a low-pass filter (LPF) controls the frequency of the output signal of the VCO so that it takes a value exactly equal to the frequency of the reference oscillator multiplied by the division coefficient N of the divider with a variable division coefficient (DPCD). Such a frequency synthesizer is an astatic autoregulation system. It is known that an integrator is present in the ring of such a system. An integrator is implemented as a low-pass filter with a transmission coefficient K (f), which depends on the frequency f:

Where f _CP - cutoff frequency of the low-pass filter.

The low-pass filter isolates the constant component of the difference between the frequency of the signal of the reference oscillator and the frequency of the VCO signal (divided by N times) and filters (suppresses) the output voltage with the frequencies of the reference oscillator, with the frequency of the VCO, which has been divided in the DPCD, as well as various spurious interference and noise. It is fundamentally impossible to increase the filtering using a higher-order low-pass filter, for example, with a transmission coefficient (1 + f / f _SR ) ² . For this reason, the filtering of interference and various interference occurring in the DPCD and PFD occurs according to the law (1 + f / f _SR ) and, therefore, is limited.

In the book [3], the noise level in the passband of the low-pass filter of the IFAP system is determined in the region of 100 dBc in the frequency band of 10 Hz. In the same place, on page 87 are shown the dependences of “noise” caused by the phase-locked loop of Fig.2.37, from which it can be seen that when tuning to 10 kHz from the carrier frequency the attenuation of “noise” is 90-110 dBc in the 1 Hz frequency band. In [2], the level of noise suppression of fractionality was estimated at (80 ÷ 120) dB. Similar figures are given in many other sources.

Such suppression of interference and interference in the output voltage of the synthesizer for current conditions of loading the radio frequency range is insufficient.

The second drawback of the considered midrange is as follows.

It is known that the IFAPH MF system is a low-pass filter with respect to the noise of the reference signal (multiplied by a factor of division times, summed with the noise of the detector, etc.) and a high-pass filter with respect to the noise of the output signal of the VCO. In other words, the noise of the reference oscillator multiplied by the division coefficient is dominated by the noise of the reference oscillator, detector noise, etc., and the noise of the VCO prevails outside the bandwidth of the IFAP. Therefore, if it is necessary to use large division factors (in the midrange with a high output signal frequency and a relatively low comparison frequency), it is advisable to reduce the passband of the IFAP MF system. But to ensure the necessary speed of the midrange (determined by the inertia of the low-pass filter of the IFAPCH system), it is necessary to use the broadband system of the IFAP midrange.

Thus, in a single-ring midrange with IFAPCH, it is almost impossible to simultaneously obtain high speed and the necessary noise characteristics of the output signal. So, to implement a fixed-frequency mode with improved spectral characteristics (slow mode) and to implement programmable tuning of the radio frequency, which requires high speed (fast mode), you have to create two frequency synthesizers for both modes, or to switch the low-pass filter with a wide and narrow passband to combine both modes in one device.

The closest in technical essence to the proposed device can be considered a frequency synthesizer with IFAPCH described in the patent for utility model RU 100348, adopted as a prototype.

The functional diagram of the prototype device is presented in figure 1, where the following notation is introduced:

1 - block frequency synthesizer (BSC);

2, 10 - the first and second low-pass filters (LPF1 and LPF2);

3 - voltage controlled oscillator (VCO);

8 - control bus (ШУ);

9, 11 - the first and second low-frequency switches (NK1 and NK2).

The prototype device contains a series-connected BSH 1, the first input of which receives a signal from the reference generator, and NK1 9, the first output of which through the LPF1 2 is connected to the first input of NK2 11; the second output of NK1 9 through LPF2 10 is connected to the second input of NK2 11, the output of which through the VCO 3 is connected to the second input of the BCCH 1. The BCCH 1, NK1 9 and NK2 11 are controlled via the control bus SHU 8 from an external control device (VUU).

The prototype device operates as follows.

From VUU in BSH 1 commands are received to record the necessary division factors, and NK1 9 and NK2 11 receive switching signals determined by the operating mode of the device - "fast" mode, or "slow" mode. The reference signal from the reference generator is fed to the first input of the BSC 1, in which, in the general case, the frequency of this signal is converted (reduction of the signal frequency to the comparison frequency by dividing) and its supply to the frequency-phase detector, which is part of the BCH 1. To the second input BSN 1 receives a signal from the output of the VCO 3, the frequency of the output signal in BSCH 1 is divided into a division coefficient N times (N in the general case can be either integer or fractional) and is fed to a frequency-phase detector BSCH 1. Signal frequency inconsistency signal a given input to the phase detector frequency-BSCH 1, formed at the outlet and enters BSCH 1 through 9 HC1 FNCH1 2 in the case of the slow mode, or a FNCH2 10 in the case of a fast mode. The extracted constant component of the frequency mismatch signal from the output of the corresponding filter is fed to the control input of the VCO 3, the frequency of the output signal of which changes until it is divided by N times in BSC 1 and becomes equal to the comparison frequency (i.e., divided by a given number times the frequency of the reference oscillator signal). Thus, the output device - the output of the VCO 3 - will be supported by the oscillation with a given frequency. Moreover, in the “fast” mode of operation, the required small frequency tuning time is provided by choosing a wide passband of the low-pass filter 2 10, and in the “slow” mode of operation, the required small phase noise of the output signal is provided by choosing a narrow pass-band of the low-pass filter 9.

Given the above, the disadvantage of the prototype device is the inability to combine the required small frequency tuning time in the same operating mode with the required small phase noise of the output signal, which limits the practical applicability of this device.

The problem to which the claimed utility model is directed is to improve the dynamic and spectral characteristics of frequency synthesizers.

Achievable technical result - the realization in one frequency synthesizer with one operating mode of the advantages of narrow-band IFAPC systems (in terms of providing the required small phase noise of the output signal) in combination with a small frequency tuning time.

To solve the problem, a frequency synthesizer containing a first frequency synthesizer unit (BSC1), the first input of which receives a signal from a reference oscillator, a first low-pass filter (LPF1) and a first voltage-controlled oscillator (VCO1), the output of which is connected to the second input BSCH1, the group of control inputs of which is connected to an external control device using the control bus, according to a utility model, a second voltage-controlled oscillator (VCO2), a high-frequency switch (VK), the output of which is the output of the device, and the second block of the frequency synthesizer (BCH2) and the second low-pass filter (LPF2), the output of which is connected to the control input of the VCO2 in series, the output of the BSC1 through the LPF1 is connected to the control input of the VCO1, the output of which is also connected to the first input VK, the second input of which is connected to the output of the VCO2 and the second input of the BCCH2, to the first input of which a signal is supplied from the reference generator, and the group of control inputs of the BCCH2 is connected via the control bus to the group of control inputs of the VK and to the external control device.

Functional diagram of the inventive device is shown in figure 2, where the following notation is introduced:

1 - the first block of the frequency synthesizer (BSCh1);

2 - the first low-pass filter (LPF1);

3 - the first voltage-controlled generator (VCO1);

4 - the second block of the frequency synthesizer (MF2);

5 - the second low-pass filter (LPF2);

6 - the second voltage-controlled generator (VCO2);

7 - high-frequency switch (VK);

8 - control bus (ШУ).

The inventive device contains a series-connected first block of the frequency synthesizer (BSC1) 1, the first low-pass filter (LPF1) 2 and the first generator controlled by voltage (VCO1) 3, the output of which is connected to the second input of the BSC1 1 and to the first input of the high-frequency switch (VK) 7; the second block of the frequency synthesizer (BSC2) 4, the second low-pass filter (LPF2) 5 and the second generator controlled by voltage (VCO2) 6, the output of which is connected to the second inputs of the BSC2 4 and VK 7, the output of which is the device output, are connected in series. At the same time, the signal from the reference generator (OG) is supplied to the first inputs of BSCh1 1 and BSCh2 4, and the groups of control inputs BSCh1 1, BSCh2 4 and VK 7 are connected to an external control device (CCU) via a control bus (ШУ) 8.

The inventive device operates as follows.

From VUU through SHU 8 to the control inputs of the BSC 1 receive commands to record the necessary division coefficients, and to the control inputs of the VK 7 receives a switching signal that provides switching of the signal from the output of the VCO 1 3 to the output of the device.

In this case, the BSCH1 1 can be performed, for example, on the basis of the ADF4158 microcircuit from Analog Devices [5], or HMC704LP4E from Hittite [6]. Such microcircuits incorporate a frequency divider of the reference oscillator signal, a frequency divider of the VCO signal, a frequency-phase detector, and a current pump device, and such microcircuits are controlled by the Serial Peripheral Interface (SPI) protocol.

BK 7 can be performed, for example, on the basis of the Hittite chip HMC349LP4C, such a chip is controlled by two logical signals Vctl and EN.

The exhaust gas signal arrives at the first input of BSCH 1, the frequency of which is divided in BSCh 1 1 (in the general case) and fed to one of the inputs of the frequency-phase detector included in BSCh1 1. The output signal of VCO 3 is fed to the second input of BSCh1 1, frequency which is divided by N times (in the general case, N can be either an integer or a fractional number) and is fed to another input of the frequency-phase detector, which is a part of BSCh1 1. At the output of BSCh1 1, a signal is mismatching the frequencies (and phases) of both signals arriving at the inputs of the frequency-phase detector BSN1 1, which the input to FNCH1 2, wherein the constant component is allocated an error signal and suppresses high-frequency components of the signal. Then, from the output of the LPF1 2, the constant component of the mismatch signal is fed to the control input of the VCO1 3, the frequency of the output signal of which changes until it is divided by N times in the BCCH1 1, it does not become equal to the frequency of the exhaust signal input to the BCCH1 1 frequency-phase detector, which is a part of BSCh1 1. After the equality of the frequencies of the signals at the inputs of the frequency-phase detector, which is a part of BSCh1 1, the signal at its output ceases to change, and the frequency of the output signal of the VCO1 3 is kept equal to multiply hydrochloric N times divided into a predetermined number of times the frequency signal FG. The signal from the output of the VCO1 3 through BK 7 is fed to the output of the device.

During the setup of the BCCH1 1, by means of the control unit 8, the commands for recording the necessary division factors are received from the BCU2 to the control inputs of the BCCH2 4. Moreover, BSCH2 4 can also be performed, for example, on the basis of the ADF4158 chip from Analog Devices, or HMC704LP4E from Hittite. The signal from the exhaust gas is fed to the first input of BSCH2 4, the frequency of which in BSCH2 4 is, in general, divided and fed to one of the inputs of the frequency-phase detector, which is part of BSCh2 4. The second signal of BSCH2 4 receives the output signal of VCO2 6, whose frequency is divided by N1 times (in the general case, N1 can be either an integer or fractional and not equal to N) and is fed to the other input of the frequency-phase detector, which is part of BSC2 4. At the output of BSC2 4, a frequency mismatch signal (and phases ) both signals arriving at the outputs of the frequency-phase detector, walking in the composition BSCH2 4, which is then input to FNCH2 5, wherein the constant component is allocated an error signal and suppresses high-frequency components of the signal. Then, from the output of LPF2 5, the constant component of the mismatch signal is fed to the control input of VCO2 6, the frequency of the output signal of which changes until then, divided by N1 times in BCCH2 4, it becomes equal to the frequency of the exhaust signal divided into BCCH2 4 and reduced to the input of the frequency-phase detector, which is a part of BSCh2 4. After the equality of the frequencies of the signals at the inputs of the frequency-phase detector, which is a part of BSCh2 4, the signal at its output ceases to change, and the frequency of the output signal of the VCO2 6 is maintained equal to multiplying N1 constant in time divided into a predetermined number of times the frequency of the reference oscillator signal.

Then, if necessary, to rebuild the device from the first tuned frequency to the second, from the VUU by means of the control unit 8, the switching command is sent to VK 7, and the signal from the output of the VCO2 6 passes to the output of the device. The adjustment time will be equal to the switching time VK 7.

Thus, in fact, the proposed device consists of two frequency synthesizers with IFAPCH, the output signals of which are alternately switched to the output of the device. In this case, one of the frequency synthesizers is tuned during the operation of the second synthesizer. Therefore, it is possible to select narrow-band low-pass filters in both frequency synthesizers with IFAP, and this ensures the required small phase noise of the output signals, and due to the alternating switching of the output signals of these synthesizers, provide a short tuning time in the frequency of the entire device.

Information sources:

1. Manassevich V. Frequency synthesizers. Theory and design. Translated from English by V.A. Povzner, ed. A.S. Galina. - M .: Communication, 1979

2. Frequency synthesizers with a pulse-phase self-tuning system // Levin VA, Malinovsky VN, Romanov S.K. - M .: Radio and communications, 1989.

3. Phase synchronization systems // Akimov VN, Belyustina LN, Belykh VN and etc.; Ed. V.V.Shahgildyan, L.N. Belyustina - M .: Radio and communications, 1982

4. Bobkov A.M. Real selectivity of radio channels in a complex jamming environment. - St. Petersburg 2001, p. 142.

5. Description of the ADF4158 chip on the official website of Analog Devices.

http://www.analog.com/static/imported-files/data_sheets/ADF4158.pdf

6. Description of the HMC704LP4E chip on the official website of Hittite.http: //www.hittite.com/content/documents/data_sheet/hmc7041p4.pdf

Claims (1)

A frequency synthesizer containing a first frequency synthesizer block (BCH1), the first input of which receives a signal from the reference generator, a first low-pass filter (LPF1) and a first voltage-controlled generator (VCO1), the output of which is connected to the second input of the BCH1, a group of control inputs which, using the control bus, is connected to an external control device, characterized in that a second voltage-controlled generator (VCO2), a high-frequency switch (VK), the output of which is the output of the device, and the second block of the frequency synthesizer (BCH2) and the second low-pass filter (LPF2), the output of which is connected to the control input of the VCO2, the output of the BSC1 through the LPF1 is connected to the control input of the VCO1, the output of which is also connected to the first input of the VC, the second input of which connected to the output of the VCO2 and the second input of the BSCH2, the first input of which receives a signal from the reference generator, and the group of control inputs of the BSCH2 is connected to the group of control inputs of the VC and to an external control device using the control bus.

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