RU2458461C1 - Frequency synthesiser - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: device comprises two generators of a reference frequency signal, a source of supply to a generator of a reference frequency signal, a frequency divider with a fixed coefficient of division, a frequency-phase detector, a low pass filter, a generator controlled by voltage, a fractional frequency divider with an alternating division coefficient, a microcontroller, two electronic two-way switches.

EFFECT: lower level of indirect spectral components of a synthesised signal.

1 dwg

Description

The invention relates to radio engineering and can be used in receiving devices as a small-sized frequency oscillator and other devices that require frequency tuning with a low level of side spectral components in the output signal.

Known frequency synthesizer, made on the basis of a pulse-phase self-tuning system with a frequency divider having a variable division ratio [1, p. 9, Fig. 1.1].

The advantage of such a synthesizer when using microcircuits is the possibility of forming at its output a large number of discrete frequencies with relative stability equal to the relative stability of the reference crystal oscillator, with a low level of secondary spectral components in the output signal, small dimensions and low power consumption. The disadvantage of this frequency synthesizer is that it does not allow to simultaneously obtain a low level of phase noise of the output high-frequency signal during tuning with a small step and a low level of secondary spectral components in the output signal.

The closest in technical essence to the proposed device is a frequency synthesizer based on a pulse-phase self-tuning with a fractional frequency divider having a variable division factor [2, p. 8, Fig. B.1].

The prototype device comprises a reference frequency signal generator connected to a power source, a frequency divider with a fixed division ratio, having one controlled signal input connected to the output of the reference frequency signal generator, one control signal input and one output, a phase-phase detector having two inputs the first of which is connected to the output of the frequency divider with a fixed division ratio, a low-pass filter, the input of which is connected to the output of the frequency-phase detector, generator, control voltage, containing one input connected to the output of the low-pass filter, and two outputs, the first of which is the output of the frequency synthesizer, a fractional frequency divider with a variable division coefficient, having two inputs, the first of which is connected to the second output of the voltage-controlled generator, and one output connected to the second input of the frequency-phase detector, a microcontroller, the control bus of which is connected to the input of the control signal of the frequency divider with a fixed division factor and the second Odom fractional frequency divider with variable division ratio.

The advantage of the prototype device when using microcircuits is the possibility of forming at its output a large number of discrete frequencies with relative stability equal to the relative stability of the reference crystal oscillator, low phase noise, small dimensions of the device and low power consumption. The disadvantage of the prototype device is that even when using frequency synthesizer circuits with sigma-delta modulators in it (see, for example, the technical characteristics of the Hittite HMC704LP4E microcircuit), there are interferences generated by the synthesizer, since it has a spurious connection between synthesized signal and the first input of the frequency-phase detector. Due to the fact that the synthesized frequencies are not multiples of the signal frequency at the first input of the frequency-phase detector (not multiples of the comparison frequency), side (spurious) spectral components appear in the output signal. The worst case is when the difference between the synthesized frequencies and the nearest frequency multiple of the comparison frequency is so small that the low-pass filter does not provide the required suppression of side spectral components. The highest level of secondary spectral components in the synthesized signal is near the frequencies

subject to the conditions: d <m and m≤4,

where f _PFD is the comparison frequency used in the frequency-phase detector;

n, d and m are integers, with a larger value of m corresponding to a lower level of incidental spectral components [3, p. 17, Fig. 26].

The level of incidental spectral components in the synthesized signal near the frequencies determined by expression (1) decreases when the condition:

nf _PFD + f _PFD + d / m + l · Δ / m≤f _out ≤nf _PFD + f _PFD + d / ml · Δ / m,

where f _o - synthesized frequency;

Δ is the passband of the low-pass filter;

l is a coefficient depending on the parameters of the characteristics of the low-pass filter and the required suppression of secondary spectral components (a larger value corresponds to a larger suppression).

The task to which the proposed solution is aimed is to reduce the level of secondary spectral components of the synthesized signal.

The solution to this problem is achieved by the fact that in a frequency synthesizer containing a reference frequency signal generator, a power source of a reference frequency signal generator, a frequency divider with a fixed division coefficient, having one input of the control signal, one input of the controlled signal and one output, frequency-phase detector, having two inputs, the first of which is connected to the output of the frequency divider with a fixed division coefficient, a low-pass filter, the input of which is connected to the output of the frequency-phase detector, a voltage-controlled herator containing one input connected to the output of a low-pass filter and two outputs, the first of which is the output of the frequency synthesizer, a fractional frequency divider with a variable division coefficient, having two inputs, the first of which is connected to the second output of the generator controlled voltage, and the output is with the second input of the frequency-phase detector, a microcontroller, the control bus of which is connected to the input of the control signal of the frequency divider with a fixed division factor and the second input m of a fractional frequency divider with a variable division coefficient, the first electronic on-off switch is introduced, which has one control signal input, one controlled signal input connected to the output of the power source of the reference frequency signal generator, and two outputs, the first of which is connected to the input of the reference signal generator frequency, the second signal generator of the reference frequency, the input of which is connected to the second output of the first electronic on-off switch, the second electronic two A positioning switch having two inputs of controlled signals, the first of which is connected to the output of the first generator of the signal of the reference frequency, and the second to the output of the second generator of the signal of the reference frequency, one input of the control signal and one output connected to the input of the controlled signal of the frequency divider with a fixed coefficient division, while the inputs of the control signal of the first and second electronic on / off switches are connected to the control bus of the microcontroller.

A block diagram of the proposed device is shown in the drawing of the attached graphic material, where the following notation is introduced:

1 - power source of signal generators of reference frequencies;

2 - the first signal generator of the reference frequency;

3 - frequency divider with a fixed division ratio;

4 - frequency-phase detector;

5 - low pass filter;

6 - voltage controlled oscillator;

7 - fractional frequency divider with a variable division ratio;

8 - microcontroller;

9 - the first electronic on-off switch;

10 - second signal generator of the reference frequency;

11 - the second electronic on-off switch.

The proposed device contains a power source 1 of the first 2 and second 10 signal generators of the reference frequencies, the first electronic on-off switch 9 having one input of the control signal, one input of the controlled signal connected to the output of the power source 1, and two outputs, the first generator of the signal of the reference frequency 2 having a power input connected to the first output of the first electronic on-off switch 9, and one output, a second signal generator of a reference frequency 10 having a power input connected to the second output of the first switch 9, and one output, the second electronic on-off switch 11, which has two inputs of controlled signals, the first of which is connected to the output of the first generator 2, and the second to the output of the second generator 10, one input of the control signal and one output, divider frequency 3 with a fixed division ratio, having one input of a controlled signal connected to the output of the second switch 11, one input of a control signal and one output, a frequency-phase detector 4 having two inputs, the first of which connected to the output of the frequency divider 3, a low-pass filter 5, the input of which is connected to the output of the frequency-phase detector 4, a voltage-controlled generator 6, containing one input connected to the output of the low-pass filter 5, and two outputs, the first of which is the output frequency synthesizer, fractional frequency divider 7 with a variable division coefficient, having two inputs, the first of which is connected to the second output of the generator 6, and one output connected to the second input of the frequency-phase detector 4, microcontroller 8, control w which is connected to the inputs of the control signals of the first 9 and second 11 switches, frequency divider 3 and the second input of the fractional frequency divider 7.

The frequencies f ₁ and f ₂ for the first 2 and second 10 signal generators of the reference frequencies are selected so that the following conditions are met:

,

,

where l is a coefficient depending on the parameters of the characteristics of the low-pass filter 5 and the required suppression of the side spectral components of the synthesized signal (a larger suppression corresponds to a larger value of l).

Δ is the passband of the lowpass filter 5;

и

- минимальная и максимальная синтезируемые частоты;

and

- minimum and maximum synthesized frequencies;

R is the division ratio of the frequency divider 3 with a fixed division ratio.

The proposed device operates as follows.

When the frequency synthesizer is turned on at a given frequency, the microcontroller 8 outputs the binary code for four inputs via the control bus: the second input of the frequency divider 7 with a variable division coefficient, setting the fractional division coefficient N _{1 in it} , the input of the control signal of the frequency divider 3 with a fixed the division coefficient, setting in it the division coefficient R, the input of the control signal of the first electronic on-off switch 9, connecting the input of the controlled signal with its first output, input One of the control signal of the second electronic on-off switch 11, connecting the first input of the controlled signal with its output. The signal from the second output of the generator 6 through the fractional frequency divider 7 and the signal from the output of the generator 2 through the frequency divider 3 and the second switch 11 are respectively supplied to the second and first inputs of the frequency-phase detector 4. The signal from the output of the frequency-phase detector 4 through a low-pass filter 5 is fed to the input of the generator 6, which after a certain period of time ensures that the frequency of the generator 6 coincides with the frequency of the generator 2 in the phase-locked loop based on the generator 6. the output of the generator 6 is formed synthesized frequency f _o equal to the frequency of the signal f _{1 the} first generator of the reference frequency 2, multiplied by N ₁ / R. In the operating mode of the synthesizer when the condition is met:

nf _PFD + f _PFD d / ml · Δ / m≤f _out ≤nf _PFD + f _PFD d / m + l · Δ / m,

where f _PFD = f ₁ / R, from the output of the microcontroller 8 via the control bus signals are sent in binary code to the second input of the frequency divider 7, setting in it a fractional division coefficient N ₂ corresponding to the frequencies f ₂ and f _o , to the input of the control signal of the divider frequency 3, setting in it the division coefficient R, at the input of the control signal of the first switch 9, connecting the input of the controlled signal with its second output, the input of the control signal of the second switch 11, connecting the second input of the controlled signal with its output. After a certain period of time, synchronization is achieved in the phase-locked loop based on the generator 6. At the first output of the generator 6, a frequency f _o is generated equal to the frequency of the signal f _{2 of the} second generator 10 multiplied by N ₂ / R. In this case, the frequency sections nf _ChFD + f _ChFD d / m ± l · Δ / m, in which there is a high level of secondary spectral components, are excluded.

The digital part of the frequency synthesizer, which includes a fractional frequency divider 7 with a variable division ratio, a frequency divider 3 with a fixed division coefficient and a frequency-phase detector 4, can be performed on one of the microcircuits of a digital frequency synthesizer with a pulse-phase-locked loop, for example manufactured by Hittite chip NMS 700/701/702 or 704. The first 9 and second 11 switches can be performed on chips IRF7317 company National Rectifier and NMS349 company Hittite, respectively.

The main advantage of the proposed technical solution is that with the help of the introduced new nodes, combined with new connections with the other nodes of the circuit, it is possible to reduce the level of side spectral components in the output signal, which is very important when using frequency synthesizers with a fractional frequency divider. This allows you to use the proposed synthesizer in promising systems where it is necessary to ensure a low level of secondary spectral components in the output signal with a small size of the device and low power consumption.

Experimental studies of the prototype synthesizer and the proposed device in the frequency range of 2.9-3.0 GHz showed that the level of secondary spectral components of the proposed device was 30-40 dB lower than the level of secondary spectral components of the prototype device.

Information sources

1. Levin V.A. et al. Frequency synthesizers with a phase-locked-loop system. - M .: Radio and communications, 1989. - 232 p .;

2. Shakhtarin B.I. et al. Frequency synthesizers. - M .: Hot line. - Telecom, 2007. - 128 p. - prototype;

3. Datasheet v01.0111 HMC704LP4E 8 GHz fractional synthesizer. 2011. www.hittite.com.

Claims (1)

A frequency synthesizer comprising a reference frequency signal generator, a power source of a reference frequency signal generator, a frequency divider with a fixed division ratio, having one control signal input, one controlled signal input and one output, a frequency-phase detector having two inputs, the first of which is connected with the output of the frequency divider with a fixed division ratio, a low-pass filter, the input of which is connected to the output of the frequency-phase detector, a voltage-controlled generator containing one in a stroke connected to the output of the low-pass filter, and two outputs, the first of which is the output of the frequency synthesizer, a fractional frequency divider with a variable division coefficient, having two inputs, the first of which is connected to the second output of the voltage-controlled generator, and the output to the second the input of the frequency-phase detector, a microcontroller, the control bus of which is connected to the input of the control signal of the frequency divider with a fixed division coefficient and the second input of the fractional frequency divider with a variable coefficient dividing step, characterized in that it additionally introduces a first electronic on-off switch having one control signal input, one controlled signal input connected to the output of the power source of the reference frequency signal generator, and two outputs, the first of which is connected to the input of the reference signal generator frequency, a second generator of a signal of a reference frequency, the input of which is connected to the second output of the first electronic on-off switch, the second electronic on-off switch a spruce having two inputs of controlled signals, the first of which is connected to the output of the first generator of the signal of the reference frequency, and the second to the output of the second generator of the signal of the reference frequency, one input of the control signal and one output connected to the input of the controlled signal of the frequency divider with a fixed division ratio while the inputs of the control signal of the first and second electronic on / off switches are connected to the control bus of the microcontroller.