RU72803U1 - DIGITAL FREQUENCY SYNTHESIS WITH FREQUENCY MODULATION - Google Patents

Abstract

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.

The technical result is a significant expansion of the range of modulating frequencies in the low-frequency region and obtaining a uniform amplitude-frequency modulation characteristic in a wide band of modulating frequencies with minimal distortion.

To do this, the proposed device includes: the first and second adjustable amplifiers, integrator, adder and microcontroller.

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 ratio (DPC) in the feedback circuit, in which the modulating signal is fed to the modulating input of the controlled generator (UG) (see certificate for utility model No. 22729 of 10/31/2001)

In this DSP with FM, negative frequency feedback (OOS) is introduced in phase in the reference channel from the output of the loopback low-pass filter (LPF) through a series-connected DC amplifier (CTF), an inverter (INV ) and a key (C) for a phase modulator (FM), included between the reference generator (OG) and the frequency divider with a fixed division ratio (DPCD).

A disadvantage of the known device is that when the FM is turned on after the exhaust gas, in order to attenuate the frequency distortions and interference in the region of lower modulating frequencies, it is necessary to obtain a large phase deviation in the FM, which is not feasible in the linear mode in the FM.

The closest in technical essence to the proposed one is the single-ring TSSCh with the World Cup (see certificate on PM No. 29813 dated 12/20/2002), which is adopted as a prototype.

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

1 - controlled generator (UG);

2 - frequency divider with a variable division ratio (DPKD);

3 - pulse-phase detector (IFD);

4 - low-pass filter (low-pass filter);

5 - direct current amplifier (UPT);

6 - inverter (INV);

7 - key (C);

8 - phase modulator (FM);

9 - frequency divider with a fixed division ratio (DPCD);

10 - reference quartz generator (OKG);

11 - frequency divider (DF);

12 - indicator of synchronism (IP);

13 - source modulating signal (IC).

The prototype device contains connected in a ring controlled generator UG 1, DPKD 2, IFD 3 and low-pass filter 4, the output of which is connected to the control input of UG 1; series-connected OKG 10, DC 11, FM 8

and DFKD 9, the output of which is connected to the second input of the IFD 3; connected in series UPT 5, INV 6 and the key Kl 7, the output of which is connected to the modulating input of FM 8, as well as IS 12, the output of which is connected to the control input of Kl 7, and the input is connected to the output of IFD 3, and IC 13, the output of which is connected with modulating input UG 1. In this case, the input of the UPT 5 is connected to the output of the low-pass filter 4.

The prototype device operates as follows.

After the establishment of the synchronism mode in the IFAPC ring, when the modulating voltage is supplied from the IMS 13 to the modulating input of UG 1, its frequency modulation occurs. In this case, the pulses at the output of the DPKD 2 will be phase-modulated in accordance with the modulation of the UG 1 by an information signal from the IC 13. From the output of the DPKD 2, the phase-modulated short pulses are fed to the first input of the IFD 3, where they are compared with the short reference pulses from the output of the DFKD 9 s comparing the frequency F _CP is obtained by dividing the frequency of the laser 10, the constant division coefficients PM DFKD 4 and 9. As a result of comparison of these pulses at the output 3 IFD control voltage generated frequency and phase, which via a loop FN 4 is supplied to the control input HS 1 for its adjustment to the reference signal. At the same time, the control signal from the output of the loop low-pass filter 4 through UPT 5, INV 6 and Cl 7 (open in synchronism mode according to the enable signal from the IC 12) is fed to the modulating input of FM 8 and modulates its input reference pulses in phase, which weakens the response of the MFAP ring to modulating effect in the region of low modulating frequencies. In addition, the presence of negative phase feedback weakens the parasitic FM that occurs in the output signal of the DSC due to the influence of destabilizing factors on the reference signal.

In the transition mode, when switching the frequency of the central frequency converter, when the phase difference at the inputs of the IFD 3 exceeds a predetermined value, the IP 12 is triggered from the output signal of the IFD 3 and an inhibit signal is generated at its output, which is fed to the control input of Cl 7. As a result, Cl 7 closes and in the PLL ring, the usual synthesizer frequency tuning occurs.

The advantage of the prototype device is that in order to attenuate frequency distortions and interference in the region of lower modulating frequencies, it is necessary to have phase deviation in FM R-times less than in the analogue due to the presence of PM 11 with division factor R. before FM 8. At the same time, in order to reduce the level of spurious frequency modulation (FFM) that occurs in the reference channel, the prototype device operates the OOS from the output of the low-pass filter 7 through UPT 5, INV 6 and Cl 7 to the modulating input of FM 8 so that all the interference in the reference channel and noise components are processed in s toron of reduction.

The disadvantage of the prototype device is that in it the attenuation of frequency distortion is carried out using negative feedback in the reference channel not in frequency but in phase, therefore, the efficiency of attenuation of frequency distortion with decreasing values of the modulating frequencies decreases

the final value of the UPT5 gain in the feedback circuit, i.e. at the final value of the regulation coefficient in the feedback circuit.

To eliminate this drawback in a digital frequency synthesizer with frequency modulation, containing a controlled oscillator connected in a ring, a frequency divider with a variable division ratio, a frequency-phase detector, which is widely used in digital frequency synthesizers instead of an IFD and a low-pass filter, the output of which is connected to the control controlled generator input; a reference crystal oscillator, a frequency divider, a phase modulator and a frequency divider with a fixed division coefficient, the output of which is connected to the second input of the frequency-phase detector in series; series-connected DC amplifier, inverter and switch, as well as a synchronism indicator, the output of which is connected to the control input of the switch, and the input to the output of the frequency-phase detector, and the modulating signal source, while the input of the DC amplifier is connected to the output of the low-pass filter , the first adjustable amplifier, integrator and adder are connected in series, the output of which is connected to the modulating input of the phase modulator, the second adjustable amplifier connected between the output of the source a modulating signal and a modulating input of a controlled generator, and a microcontroller, the control bus of which is connected to the control inputs of a frequency divider with a variable division coefficient, the first and second adjustable amplifiers. In this case, the second input of the adder is connected to the output of the key, and the output of the controlled generator is simultaneously the output of the device.

A significant difference of the proposed technical solution is that with the help of the introduced new elements, combined by appropriate links with the other nodes of the circuit, it is possible to completely attenuate the frequency distortions at lower modulating frequencies close to zero frequency while maintaining the effect of attenuation of interference.

The block diagram of the proposed device is shown in figure 2, where the following notation is introduced:

1 - controlled generator (UG);

2 - frequency divider with a variable division ratio (DPKD);

3 - frequency-phase detector (ChFD);

4 - low-pass filter (low-pass filter);

5 - direct current amplifier (UPT);

6 - inverter (INV);

7 - key (C);

8 - phase modulator (FM);

9 - frequency divider with a fixed division ratio (DPCD);

10 - reference quartz generator (OKG);

11 - frequency divider (DF);

12 - indicator of synchronism (IP);

13 - source modulating signal (IC);

14 - the first adjustable amplifier (1RU);

15 - integrator (INT);

16 - adder (SUM);

17 - the second adjustable amplifier (2RU);

18 - microcontroller (MK).

The proposed device contains connected in a ring controlled generator UG 1, DPKD 2, ChFD 3 and low-pass filter 4, the output of which is connected to the control input of UG 1; serially connected OKG 10, DC 11, FM 8 and DFKD 9, the output of which is connected to the second input of the PSD 3; series-connected UPT 5, INV 6 and CL 7; connected in series are the first adjustable amplifier 1RU 14, INT 15 and SUM 16, the output of which is connected to the modulating input of FM 8, as well as the IC 12, the output of which is connected to the control input of CL 7, and the input to the output of ChFD 3, the second adjustable amplifier 2RU 17 connected between the output of the IC 13 and the modulating input of UG 1, and the microcontroller MK 18, the control bus of which is connected to the control inputs of the DPKD 2, of the first and second adjustable amplifiers 1RU 14 and 2RU 17. In this case, the input of the CTF 5 is connected to the output of the low-pass filter 4, the output Kl 7 is connected to the second input of the SUM 16, and you od HS 1 is simultaneously the output device.

The proposed device operates as follows.

In the synchronism mode, the modulating signal U _M (t) is supplied from the IC 13 through the second 2RU 17 to the modulating input of UG 1 and through the first 1RU 14, INT 15 and SUM 16 to the modulating input of FM 8 in the reference channel. From the output of FM 8, short pulses, phase-modulated in the same way as pulses from the output of DPKD 2, are fed to the input of DPCD 9. As a result, pulses equally modulated in phase are fed to the first and second inputs of the PFD 3. In this case, the control voltage is generated at the output of the ChFD 3, which, after the low-pass filter 4, is supplied to the control input of UG 1 and adjusts it in frequency and phase to the reference signal. In this control voltage, the component from the response of the IFAPH ring to the modulating effect is already absent, which allows us to completely reduce the frequency distortion at the lower modulating frequencies to almost zero frequency.

To effectively mitigate the frequency distortions during the tuning of the DSC in a given range of carrier frequencies, the first and second switchgear are used, the transmission coefficients of which are changed by commands from MK 13 via the control bus as follows: in the second switchgear 17, the transmission coefficient changes inversely with the change in the steepness of UG 1, in the first RU 14 - inversely proportional to the division coefficient N in DPKD 2.

The control bus from MK 18 is a standard three-wire interface, where pulse signals are received in a serial code via three wires: 1) clock pulses; 2) information signal; 3) an impulse to enable the recording of transmitted information in one of the blocks: DPKD 2, 1RU 14, 2RU 17.

The feasibility of the proposed device is determined by the fact that the input units are typical and can be performed on widely known microcircuits. The digital part of the synthesizers is performed on DSC chips with IFAPCH of different companies. For example, chips LMX2364, LMX2470 from National Semiconductor or ADF4001, ADF4252 from Analog Devices. Scheme

integrator and adder are based on the AD822AR operational amplifiers from Analog Devices. Variable amplifiers can also be made on the same Analog Devices AD822AR operational amplifiers in conjunction with Digital Potentiometers on the Analog Devices AD8402AR10 chip. The digital potentiometers are controlled via the control bus from the microcontroller, which can be used with the SILABS (CYGNAL) type C8051F221.

Thus, in the proposed FMC with FM it is possible to significantly expand the range of modulating frequencies to the low frequency region and to obtain a uniform frequency response in a wide band of modulating frequencies to zero frequency while maintaining the effect of decreasing the IFM level in the output signal of the synthesizer due to the influence of destabilizing factors on the reference signal .

Claims (1)

A digital frequency synthesizer with frequency modulation, comprising a controlled oscillator connected in a ring, a frequency divider with a variable division coefficient, a frequency-phase detector and a low-pass filter, the output of which is connected to the control input of the controlled generator; a reference crystal oscillator, a frequency divider, a phase modulator and a frequency divider with a fixed division coefficient, the output of which is connected to the second input of the frequency-phase detector in series; a DC amplifier, an inverter and a key, as well as a synchronism indicator and a modulating signal source, are connected in series, while the DC amplifier input is connected to the low-pass filter output, the synchronism indicator output is connected to the key control input, and the input to the frequency-phase detector output , the first adjustable amplifier, the integrator and the adder, the output of which is connected to the modulating input of the phase modulator, the second adjustable amplifier, are included in series between the output of the source of the modulating signal and the modulating input of the controlled generator, as well as a microcontroller, the control bus of which is connected to the control inputs of the frequency divider with a variable division ratio, the first and second adjustable amplifier, while the second input of the adder is connected to the output of the key, and the output of the controlled generator is simultaneously output device.