DE2341784A1 - FREQUENCY CONVERTER AND DEMODULATOR CIRCUIT ARRANGEMENT - Google Patents

Description

It 2583

SONY CORPORATION Tokyo / Japan

Frequency converter and demodulator circuitry

The invention relates generally to a demodulator circuit arrangement for demodulating an amplitude-modulated signal and in particular a synchronous demodulator for demodulating a converted IF signal.

A synchronous demodulator is known as a demodulator, which is used to demodulate a low voltage signal with low distortion is suitable.

A common demodulator used in a television receiver generally has the following construction. An IF signal from a converter is amplified by an IF amplifier after it has passed through a bandpass filter,

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234-84

and is then connected to the input terminals of the synchronous demodulator given. Part of the output signal of the IF amplifier passes through a bandpass filter with a narrow Passband to obtain a signal in which only one signal component with the same frequency as the Carrier frequency of the IF signal is available. The signal thus obtained is then amplified by an amplifier limited by a limiter to constant amplitude and then to the synchronous demodulator as the reference carrier signal given.

The above-mentioned synchronous demodulator circuitry has the following disadvantage. To a reference carrier signal To obtain a stable and constant amplitude, the signal that passes the bandpass filter must have a narrow passband has passed through can be amplified sufficiently, and therefore an amplifier having a large gain must be used will.

If the level of the input signal is lowered, the limiter works unstably and thus a reference carrier signal can hardly be heard constant amplitude can be obtained. Since the side and component of the IF signal is not completely eliminated can be used even if the band pass filter with narrow pass band is used, the reference carrier signal is subject to a phase modulation. When the frequency of an output signal from a tuner or the IF signal deviates from the normal frequency, the output signal of the band pass filter becomes narrow pass band is decreased abruptly, and hence a normal reference carrier signal cannot be obtained.

It is also difficult to find a band pass filter with a narrow pass band and to create a desired characteristic.

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The invention is based on the object of a synchronous demodulator circuit arrangement to create a device for automatic frequency stabilization and a Has synchronous demodulator circuit with a reference oscillator, in which the automatic frequency tuning device can precisely retune an input RF signal, and the one demodulated output signal generated without distorted components.

The invention provides a circuit arrangement for receivers that have a frequency converter a mixer and a local oscillator variable frequency for converting a received RF signal into an IF signal in the mixer, a synchronous demodulator for demodulating the IF signal with a reference signal supplied from a constant frequency reference oscillator and a control circuit to control the frequency of the local oscillator in order to have a correct frequency and phase relationship between the IF signal and the reference signal. The control circuit can set the frequency and the Compare the phase of the IF signal with that of the reference signal and use the local oscillator as a function apply a control voltage from the comparison result.

The invention is explained below with reference to FIGS. 1 to 4, for example. It shows:

Figure 1 is a block diagram of an embodiment of the invention, - ⁼

Figures 2A to 2D are waveform diagrams for explaining the Operation of the invention, and

FIGS. 3 and 4 are block diagrams of further embodiments of the invention.

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Fig. 1 shows a block diagram of an embodiment the invention. In the embodiment of FIG. 1 feeds an antenna 1 a frequency converter 2 with an input RF television signal, which converts this signal into an IF signal. The converter 2 has an RF amplifier 2a, one Mixer 2b and a voltage controlled oscillator 2c, which serves as a local oscillator.

The output IF signal generated by the converter 2 is passed through a bandpass filter 3 to an IF amplifier 4. The resonance frequencies of the bandpass filter 3 and the IF amplifier 4 are chosen so that they are 45.75 MHz. An amplified IF signal that is output by the IF amplifier 4, a synchronous demodulator 5 is supplied and a demodulated signal which is output from the synchronous demodulator 5 is A video signal output terminal 7 is supplied via a low-pass filter 6.

A reference oscillator 8, which serves as a reference signal generator, feeds a reference carrier signal to the synchronous demodulator 5 and the phase shifter 9, which shifts the phase of the reference carrier signal by 90 °. The reference oscillator 8 generates the reference carrier signal, the one Has a frequency of 45.75 MHz and is constant in amplitude. The IF signal of the IF amplifier 4 is a Phase comparator 10 is supplied, which also receives the output signal of the phase shifter 9. One from the phase comparator 10 derived signal is fed to a low-pass filter 11, and an output DC voltage signal, output from the low-pass filter 11 is supplied to the voltage controlled oscillator 2c of the converter 2 supplied as tuning frequency control voltage.

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The tuning and demodulation process will now be described. In the invention, the mixer 2b, the bandpass filter 3, the IF amplifier 4, the phase comparator 10, the low-pass filter 11 and the voltage-controlled oscillator 2c form a so-called phase-locked loop. The basic principle of how the phase-locked loop works can be briefly described as follows. if the frequency of the IF signal derived from the output signal of the voltage controlled oscillator 2c by conversion is formed from the RF signal, is sufficiently close to the reference frequency of the reference signal, forces the Feedback property of the phase-locked loop of the voltage controlled oscillator 2c on the reference signal to lock in or to be in sync with it and follow it with a small change in frequency. This way of working is similar to that of a standard automatic frequency tuning, but with the exception that the reference oscillator 8 and the phase comparator 10 instead of one Frequency discriminator can be used.

The reference oscillator 8, for example, consists of a crystal-controlled oscillator. The output signal of the reference oscillator 8 is the phase comparator 10 via a Phase shifter 9 supplied. The phase shifter 9 is used to compensate for the 90 ° phase shift caused by the phase-locked loop is caused to eliminate. The frequency and phase of the IF output signal of the IF amplifier 4 are phase-shifted with those of the The reference signal from the phase comparator 10 and the output signal of the phase comparator 10 are compared is fed via a low-pass filter 11 to the voltage-controlled oscillator 2c as a control voltage. The control voltage is dependent on the frequency and phase relationship of the IF signal and the reference signal changed to keep the frequency of the IF signal equal to that of the reference signal and a predetermined phase

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difference of e.g. 90 ° between the IF signal and the Maintain reference signal. The frequency and the phase of the IF output signal of the IF amplifier 4 are set equal to that of the reference carrier signal of the reference oscillator 8, so that the IF signal from the Synchronous demodulator 5 is demodulated normally.

If in the invention the oscillation frequency of the voltage controlled Oscillator 2c is changed because the IF signal is always compared with the reference carrier signal is, the voltage controlled oscillator 2c is controlled so that the IF signal has a predetermined frequency of e.g. 45.75 MHz. Therefore, the exact coordination is always achieved. In addition, the reference oscillator 8 is for Comparison of frequency and phase is provided so that if, for example, a crystal controlled oscillator is used as the reference oscillator, the matching with the accuracy like that of quartz can be carried out. Furthermore, there is the output signal of the reference oscillator 8 as a reference signal carrier for the synchronous demodulator 5 is used, a carrier signal with a sufficient level and a stable and constant Amplitude can be obtained.

Figures 2A through 2D are waveform diagrams used to explain the operation of the invention. Fig. 2A shows the waveform of the IF output signal P, which is an amplitude modulated signal derived from the IF amplifier 4 is output. This IF output signal P is fed to the synchronous demodulator 5.

2B shows the profile of the reference carrier signal Q of the reference oscillator 8. This reference carrier signal Q is fed to the synchronous demodulator 5 as a reference carrier. The phase of the IF output signal P and the reference carrier

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signals Q are kept the same by operating the phase-locked loop. The IF output signal P is gated by the reference carrier signal Q so that the gated signal R, which has only one polarity, and shown in Fig. 2C, as the output of the synchronous demodulator 5 is obtained. The output signal R of the synchronous demodulator 5 is the low-pass filter 6 fed. An IF carrier component of the IF signal R is removed by the low-pass filter 6, so that a Video signal S shown in Fig. 2D on the. Video signal output connector is obtained.

Fig. 3 shows a further embodiment of the invention, in which the same reference numerals as in Fig. 1 are used to designate the same components. Here only the position of the phase shifter 9 is different from the demodulator system of Fig. 1, i.e. the phase shifter 9 of this example is connected between the reference oscillator 8 and the synchronous demodulator 5, so that a detailed description can be omitted. The reason for using the phase shifter 9 at this point is similar to the demodulator system of Fig. 1.

Fig. 4 shows yet another embodiment of the invention, in which the same reference numerals as in FIGS. 2 and 3 to designate the same components are used. Only the position of the phase shifter 9 in relation to the decoding systems of FIG. 1 is important here and 3 different, i.e. the phase shifter 9 is between the IF amplifier 4 and the phase comparator 10 switched so that a detailed description can be omitted. The reason for using the phase shifter 9 at this point is similar to the demodulator systems of FIGS. 1 and 3.

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As described above, in the present invention, the automatic tuning process is carried out by using the Reference oscillator 8 and the phase comparator 10 reached, so that precise tuning is always possible. Here, a frequency discriminator, which consists of an inductance and a capacitance and the Prior art used can be omitted, so that the invention is embodied as an integrated circuit can be.

In addition, since in the invention the reference carrier signal for automatic frequency tuning is the same as for the synchronous demodulation, the phase of the input signal of the synchronous demodulator 5 can always exactly match that of the reference carrier signal. As the reference carrier signal, the output signal of the reference oscillator so that it changes the amplitude and frequency of the input signal is not affected 'and thus that the demodulated output signal does not contain a distorted component.

In the embodiments described above, as the reference signal generator directly uses the oscillator, which oscillates at an IF frequency, but can such a signal that is produced by multiplying, dividing or superimposing a signal that comes from a Vibration generated at a different frequency can be used to generate a reference carrier signal with a Get IF frequency.

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Claims (5)

Claims 1. Circuit arrangement for frequency conversion and demodulation an amplitude-modulated signal, characterized by a frequency converter, which is an RF signal converts to an IF signal and one mixer and has a voltage-controlled oscillator serving as a superimposition frequency oscillator for the mixer, a synchronous demodulator that receives the IF signal from the frequency converter and a demodulated Output signal generated, a reference signal generator that feeds a reference signal to the synchronous demodulator, and a phase comparator which compares the phase of the IF signal with that of the reference carrier signal and the same The output signal is fed to the voltage-controlled oscillator to control its frequency. 2. Circuit arrangement according to claim 1, "characterized by a phase shifter to the phase of the IF signal in agreement with the phase of the reference carrier signal bring to. 3. Circuit arrangement according to claim 2, characterized in that the phase shifter between the reference signal generator and the phase comparator is connected. 4. Circuit arrangement according to claim 1, characterized in that a low-pass filter between the phase comparator and the voltage controlled oscillator is connected. 5. Circuit arrangement according to claim 1, characterized in that that the frequency of the reference signal generator is equal to an IF frequency. 409809/1002