RU18032U1 - DIGITAL FREQUENCY SYNTHESIS WITH FREQUENCY MODULATION - Google Patents

Abstract

A digital frequency synthesizer with frequency modulation, containing a controlled oscillator connected in a ring, a variable divider frequency divider, a pulse-phase detector and a low-pass filter, a reference oscillator connected in series, a fixed division divider and a pulse-phase modulator, the output of which is connected with a second pulse-phase detector input, a modulating signal source, a controlled attenuator and an integrator, the output of which is connected in series with a modulating input of a pulse-phase modulator, as well as a frequency setting unit, the output of which is connected to the installation input of a frequency divider with a variable division coefficient and a control input of a controlled attenuator, the modulating input of a controlled generator being connected to the output of a modulating signal source, connected in series with a first integrating filter, a first DC amplifier, and an inverter, as well as a controlled phase shifter, the first input of which is connected to the output of a controlled generator, In this case, the input of the first integrating filter is connected to the output of the low-pass filter, characterized in that, in order to attenuate stray phase increments of the self-compensator itself due to the action of destabilizing factors while maintaining a wide range of modulating frequencies with an information signal, high speed and decreasing the level of spurious frequency modulation , a phase detector, a second integrating filter, a second DC amplifier and an adder are introduced in series with it, output

Description

The utility model relates to radio engineering and can be used as the exciter of a transmitter with frequency modulation and a local oscillator of the receiver without supplying a modulating signal.

Known digital frequency synthesizer (DSC) with frequency modulation (FM), built on the basis of a pulse-phase-locked loop (IFAP) with a frequency divider with a variable division coefficient (DPC) in the feedback circuit, in which to generate a frequency-modulated signal in a wide band of the modulating frequencies, a combined two-point method is used, when the modulating signal is fed to the modulating input of the compensated generator (UG) and through the integrator simultaneously to the modulating input of the pulse-phase an odulator included in the reference channel between a frequency divider with a fixed division ratio (DPCD) and a pulse-phase detector (IFD) (see a. from the USSR No. 919040, N 03 C 3/10 N 03 L 7 / 16.1982) .

With two-point modulation by this method using a pulse-phase modulator (IFM), the pulses at the reference input of the IPD should be phase-modulated in the same way as pulses after the DPD, i.e., in phase. Then, there will be no pulse error signal from the modulation at the output of the IFD and, therefore, there will be no reaction of the IFAPH ring to a modulating disturbance. In other words, the IFAPCH ring in this case is as if open by a modulating effect. At the same time, it is possible in principle to introduce a modulating signal into the DSS in a wide frequency band without distortion and maintaining the same high speed as without modulation, since the choice of a low-pass filter (LPF) in the UG control circuit now almost does not depend on the condition of passing a given baseband bands.

However, in this case, the speed of the known DSC remains insufficient, due to the inertia of the low-pass filter in the IFAP ring. The inertia of the low-pass filter in this CSC is mainly determined by the need to suppress to a given level of interference in the control circuit of the supercharged with frequencies that are multiples of the comparison frequency. It is known that the comparison frequency Fcp in a single-ring CSC is selected based on a given step of the RF frequency grid and cannot exceed it, that is). With a tendency to decrease the frequency grid spacing and tighten the norms for suppressing spurious frequency modulation, the passband in the IFAP ring is usually much lower than the comparison frequency, which drastically reduces the speed of the DSC.

In addition, spurious frequency modulation in the MSC with FM increases when the modulating frequencies are close to the comparison frequency. This is explained by the fact that as a result of the interaction of the comparison frequency Рf with the modulating frequencies FM, the Raman frequencies FK are formed at the output of the pulse-phase detector, i.e. IFD works as a mixer: FK n FM ± k Fcp. Moreover, the total combination components do not pass through the PSF, and the difference ones can go through and modulate the frequency of the UG.

In the well-known CSC with a two-phase FM, compensation of the IFAPH ring response to the main modulating effect by UG is compensated, and it is difficult to eliminate the additional spurious frequency modulation (FFM) from the combination frequencies FK, since in the compensating signal supplied to the IFM modulating input through a number of nodes, these no combinational components. Thus, to increase the suppression of the FFM from these effects, it is necessary to increase the inertia of the low-pass filter, and this leads to a decrease in the speed of the synthesizer.

The closest in technical essence to the proposed one is the DSS with FM (see the description of PM No. 13279 to the certificate of the Russian Federation with priority dated 10.12.1999), in which the MFM of the output signal is additionally suppressed (compensated) using the introduced new elements (integrating filter, DC amplifier, inverter and controllable phase shifter), combined by corresponding links with the rest of the synthesizer nodes. Such a redistribution of the IFM suppression between the HPF and the newly introduced elements of the auto-compensator made it possible to reduce the inertia of the LPF and thereby increase the speed of the DSC. In this case, the MFD is significantly suppressed, caused not only by interferences that are multiples of the comparison frequency, but also by the combination frequencies FK.

However, in the well-known CSC, parasitic phase increments of the autocompensator itself occur at the output of the phase shifter (device output) due to the action of destabilizing factors in these elements: an integrating filter (IF), a direct current amplifier (DC), an inverter (INV) and a controlled phase shifter (UVB ) These phase increments at the output of the UVB lead to an additional parasitic phase (frequency) modulation of the output signal of the synthesizer.

The aim of the proposed technical solution is to weaken the parasitic phase increments of the auto-compensator itself, arising due to the action of destabilizing factors while maintaining a wide range of modulating frequencies with an information signal, high speed and a decrease in the level of parasitic frequency modulation.

This goal is achieved by the fact that in a digital frequency absorber with frequency modulation, containing a controlled oscillator connected in a ring, divide; n frequencies with a variable division coefficient, a pulse-phase detector and a low-pass filter, connected in series

a reference oscillator, a frequency divider with a fixed division coefficient and a pulse-phase modulator, the output of which is connected to the second input of the pulse-phase detector, a modulating signal source, a controlled attenuator and an integrator, the output of which is connected to the modulating input of the pulse-phase modulator, as well as a frequency setting unit, the output of which is connected to the installation input of a frequency divider with a variable division coefficient and a control input of a controlled attenuator, and m the modulating input of the controlled generator is connected to the output of the modulating signal source, the first integrating filter, the first DC amplifier and the inverter are connected in series, as well as the controlled phase shifter, the first input of which is connected to the output of the controlled generator, while the input of the first integrating filter is connected to the output of the lower filter frequencies, a phase detector, a second integrating filter, a second DC amplifier and an adder, the output of which is connected a second control input of the phase shifter, the second input of the adder connected to the inverter output, said first input of the phase detector is connected to the output of controlled oscillator, the second input - with the output controls the phase rotator, which is an output device.

A significant difference of the proposed DSS with FM is the additional suppression (compensation) of spurious phase increments of the autocompensator itself in the passband of the second integrating filter (in the band of the useful modulating signal) arising in the serially connected elements of the autocompensator (first integrating filter, first DC amplifier, inverter and controlled phase shifter) due to various destabilizing factors. At the same time, the IFM is significantly suppressed, caused not only by interference with frequencies that are multiples of the comparison frequency, but also by combinational frequencies resulting from the interaction of the frequencies of the information modulating signal close to the frequency Fcp with harmonics of the comparison frequency at the output of the IPD, and high speed is also maintained and a wide range of modulating frequencies with an information signal.

The proposed technical solution, according to the applicant, has significant differences, since the search did not reveal analogues containing signs similar to the distinctive ones.

PA figure 1 shows the structural electrical diagram of the proposed device.

A digital frequency synthesizer with frequency modulation contains a controlled oscillator UG1 connected in a ring, a frequency divider with a variable division coefficient DPKD2, a pulse-phase detector PFDZ and a low-pass filter LPF4, the output of which is connected to the control input UG1, the reference oscillator OG5 is connected in series, the frequency divider a fixed dividing factor DFKD6 and a pulse-phase modulator IFM7, the output of which is connected to the second input of the IFDZ, series-connected source of the modulating signal IMS8, control UA9 attenuator and integrator INT 10, the output of which is connected to the IFM7 modulating input, as well as a BUCHI frequency setting unit, the output of which is connected to the DPKD2 installation input and UA9 control input, the modulating input of UG1 connected to the output of IC8, the first integrated filter of IF12 , the first UPT13 direct current amplifier and INV14 inverter, as well as the controlled UVV15 phase shifter, the first input of which is connected to the UG1 output, the PD16 phase detector, the second integrated filter 17, a second DC amplifier A19 U11118 and an adder. In this case, the output of the NWF of the C19 motherboard is connected to the second input of UVB15, the second input of C19 is connected to the output of INV14, the first input of the PD16 is connected to the output of UG1, the second input to the output of UVB15, which is the output of the device.

A digital frequency synthesizer with frequency modulation operates as follows.

After the synchronism mode is established in the IFAPH ring, when the modulating voltage is introduced from the IC8 to the modulating input of UG1, its frequency modulation occurs. At the same time, at the output of D11KD2, the pulses will be modulated in phase in accordance with the modulating signal. To compensate for this reaction of the IFAPC ring to the modulating disturbance UG1, the modulating signal from IMS8 is simultaneously fed through UA9, the IPT10 integrator, to the IFM7 modulating input, in which the reference pulses from the DFKD6 output are phase-modulated in the same way as the pulses from the output of DPKD2 are modulated. As a result of comparing the phase-modulated input pulses of the IFDZ, an error signal from modulation is not generated at its output. Therefore, there is no reaction of the IFAPH ring to a modulating disturbance of UG1. In the control signal coming from the output of the FPF4 to the control input of UG1, there is only a component of interference multiple of the comparison frequency Fcp and combinational components FK, which cause the corresponding spurious angular modulation of the output signal of UG1. From the output of UG1, a high-frequency (HF) signal, modulated by an information signal and containing spurious frequency modulation, is supplied to the first input of UVB15. To compensate for this IFM, from the output of the LPF4, parasitic increments of the control voltage Aed (1), causing a parasitic increment

frequency output UG1, comes through the first IF12, the first UPT13, IPV14 and the adder C19 to the second input UVV15.

The modulating voltage Ae (t) supplied from the output of C19 to the second input of UVB15 causes antiphase (reverse) modulation of the high-frequency signal from UG1 with a frequency converter, which is transmitted to the first input of UVB15. As a result, a high-frequency synthesizer signal is generated at the output of UVB15 with significantly suppressed IFM and maintaining useful

modulation by an information signal in a wide band of modulating frequencies.

However, when a compensating signal passes from the output of the low-pass filter 4 through the series-connected elements of IF12, U11113, INV14, spurious phase increments appear in it due to the influence of various destabilizing factors on these elements. The resulting parasitic phase increments of the control signal additionally modulate the RF signal in UFE 15, which leads to additional parasitic angular modulation of the output signal of the DSC. To compensate for these parasitic phase increments, the signal from the output of the UVE 15 is fed to the second input of the PD16, the first input of which receives the RF signal from the output of UG1. As a result, a differential voltage is generated at the output of PD16, which is proportional to the value of the parasitic phase increment. This differential voltage through the second IF17 with a passband equal to the useful modulating band passes to the input of the second U11118, where it is amplified to a value sufficient to fully compensate for the increased phase increments and goes to the first input C19 in antiphase with those phase increments that are on the second input C19 with output INE14. As a result of the linear summation at the output C19, the arisen phase increments of the control signal are suppressed, and the UHF signal 15 is generated at the output of the UVE 15 with suppressed additional rear modulation and preserving useful modulation by the information signal in a wide band of modulating frequencies. The degree of suppression of additional angular modulation in this case depends on the choice of parameters of the introduced compensation scheme.

Proof of the feasibility of the proposed device is that the input blocks are typical.

Phase detectors can be performed either on the basis of phase-frequency discriminators (see, for example, Manaev EI Fundamentals of Radio Electronics. Textbook for High Schools. - 2nd ed., Revised and additional - M .: Radio and Communications, 1985 , pp. 403-405, Figs. 16.36 - 16.41), or based on phase discriminators of balanced transducers (see. Radio receivers. Edited by A.P. Zhukoveny. M.: "School School, 1989, pp. 142.143, Fig. 7.29, 7.31).

The adder can be made passive on the resistors. The IF12 Integrating Filter is an integrating RC circuit. The DC amplifier can be made on the basis of well-known operational amplifiers (for example, on a chip 544 UD2).

Thus, the use of the proposed digital frequency synthesizer with frequency modulation can significantly attenuate stray phase increments of the signal of the auto-compensator itself while reducing the level of stray frequency modulation, increasing speed and maintaining a wide range of modulating frequencies with an information signal.

Claims (1)

A frequency-modulated digital frequency synthesizer comprising a controlled oscillator connected in a ring, a variable divider frequency divider, a pulse-phase detector and a low-pass filter, a reference oscillator connected in series, a fixed division divider and a pulse-phase modulator, the output of which is connected with the second input of the pulse-phase detector, a source of a modulating signal, a controlled attenuator and an integrator, the output of which is connected in series with a modulating input of the pulse-phase modulator, as well as a frequency setting unit, the output of which is connected to the installation input of a frequency divider with a variable division coefficient and the control input of a controlled attenuator, the modulating input of a controlled generator being connected to the output of the modulating signal source, connected in series with the first integrating filter, a first DC amplifier, and an inverter, as well as a controlled phase shifter, the first input of which is connected to the output of a controlled generator, In this case, the input of the first integrating filter is connected to the output of the low-pass filter, characterized in that, in order to attenuate stray phase increments of the self-compensator itself due to the action of destabilizing factors while maintaining a wide range of modulating frequencies with an information signal, high speed and decreasing the level of spurious frequency modulation , a phase detector, a second integrating filter, a second DC amplifier and an adder are introduced in series with it, output otorrhea connected to a second control input of the phase shifter, the second input of the adder connected to the inverter output, said first input of the phase detector is connected to the output of controlled oscillator, the second input - with the output controls the phase rotator, which is an output device.