DE2714656A1 - PHASE SYNCHRONIZATION CIRCUIT - Google Patents

Description

27U656

It 3852

SONY CORPORATION Tokyo / Japan

Phase synchronization circuit

The invention relates generally to a phase lock circuit and in particular such a circuit comprising a display device and a device for changing the frequency of a signal which is output by a tunable oscillator.

Phase synchronization circuits are used in various electronic devices. As an an example a stereo demodulator of an FM receiver can be specified will. Here, the phase synchronization circuit consists of an arrangement that is a switching circuit supplies a stereo composite signal to a circuit for generating a pilot signal from the stereo composite signal, a tunable oscillator, a circuit for comparing the phase of the output signal of the oscillator (if necessary a frequency-divided signal is included) with that of the pilot signal and a circle for Output of an output signal from the phase comparison circuit to the tunable oscillator as a control signal. The signal of the tunable oscillator is dependent on the output signal of the Phase comparison circuit (the signal contains necessary

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if a frequency-divided signal) is given on the circuit as a switching signal. From the circuit are separated left and right stereo signals emitted.

In the above known demodulator circuit, the relationship between the deviation of the phase or frequency of the switching signal supplied to the circuit and the separation of the composite stereo signal is such that when the phase or frequency of the ^{composite signal is 1, the} composite stereo signal has a low level , is shifted, the separation is quickly deteriorated. If the gain of the phase lock circuit is infinite, even if the free running frequency of the tunable oscillator deviates from its normal frequency of e.g. 76 kHz, which is four times the frequency of the pilot signal, the oscillation frequency of the tunable oscillator is locked to 76 kHz and also synchronized with the pilot signal. Therefore, there is no deviation in the phase and frequency of the switching signal. However, since the gain of the phase synchronizing circuit cannot be made infinite, if the free-running frequency of the tunable oscillator deviates from 76 kHz, the oscillation frequency also deviates. This means that the deviation of the DC voltage of a filter caused by the deviation of the oscillation frequency by which the free-running frequency of the oscillator is compensated, and the circuit becomes so stable that the oscillation frequency of the oscillator is deviated. If the oscillation frequency of the oscillator deviates, the switching frequency is changed. This worsens the separation of the left and right stereo signals of the circuit.

In order to avoid this disadvantage, the free-running frequency of the oscillator is used in the manufacture of a receiver set to a normal frequency or 76 kHz,

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to get an optimal separation of the signals. The free-swinging one However, the frequency of the oscillator changes with time, environment, etc. As the distortion factor and the nonlinear crosstalk depend in the same way on the switching frequency, they too are deteriorated.

The invention is based on the object of a phase synchronization circuit to create at which the phase difference between one. Reference signal and one to be compared Signal is known to have a simple structure and means for eliminating the phase difference suitable for use in an FM stereo receiver and which has an adjusting device to adjust the oscillation frequency of the tunable oscillator of the of a reference signal is always in agreement To make secular variations and circumstances the same.

The invention creates a phase synchronization circuit, Consists of a tunable oscillator and a phase comparator to compare the phase of an output signal, generated by the tunable oscillator with the phase of a reference signal and for generating a control signal as a function of the phase difference between these, a circuit for transmitting the control signal to the tunable oscillator, a display device to display the phase difference between the output signal of the tunable oscillator and the Reference signal, and a circle to change the frequency the output signal of the tunable oscillator.

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

Figure 1 is a block diagram of an FM stereo receiver with an exemplary phase synchronization circuit the invention,

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FIGS. 2A to 2E show the course of signals to explain the phase synchronization circuit,

3 shows a diagram from which the ¹ Ausgangssiqnal a filter in Fig. 1 shows, the order is based a signal to be compared to the frequency and phase difference of a Bezugseignais and, and

FIG. 4 is a block diagram of a practical example a phase comparator and a filter for forming the phase synchronization circuit.

In Fig. 1, 1 denotes a channel selector ηit the elements of an FM receiver from its antenna tuning circle to FM demodulator. A stereo signal mix is used for stereo reception issued by the receiver 1 and then fed to a circuit 2 for stereo demodulator.

In Fig. 1, 10 denotes a phase synchronizing circuit, which generates a switching signal for circuit 2. A voltage controlled, tunable oscillator 11 generates a Schwingungssignsl, its free-swinging Frequency is e.g. four times that of the reference signal or pilot signal, namely 76 kHz. The oscillation signal of the oscillator 11 becomes a Flip-flop 12 is supplied, which divides the input signal into a square-wave signal with a finer frequency of 38 kHz. That Rectangular signal becomes α ^ "of the flip-flop 12 one another flip-flop 13 trains vt, which is the input signal divides into a square wave signal with a frequency of 19 kHz. The square-wave signal of the flip-flop 13 is fed to a phase comparator 14, which also has a stereo signal is supplied from the FM receiver 1. The phase of the The square wave signal of the flip-flop 13 becomes with the phase of the pilot signal in the stereo signal mixture of the FM receiver 1 compared by the phase comparator 14. The compared output signal is fed to a filter 15 for integration fed. The filter 15 generates a DC voltage whose

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Polarity and level of the phase difference between the square wave signal and corresponds to the pilot signal. This DC voltage is fed to the oscillator 11 as a control signal.

Thus, the oscillation signal of the oscillator 11 is synchronized in phase with the pilot signal, and the square wave signal of the flip-flop 12 is synchronous with the pilot signal. The square wave of the flip-flop 12 v; ird dem Circuit 12 is supplied as a control signal. The circuit 12 thus performs the Schaltderrodulatior and generates stereo signals of the left and right channels at outputs 3L and 3R.

The phase relationship between the pilot signal Sp and the square-wave signal S of the flip-flop 3 in the phase synchronization circuit 10 of FIG. 1 will now be compared. When the oscillation frequency of the oscillator 11 is four times that of the pilot signal S, the frequency of the square wave signal S of the flip-flop 13 is equal to that of the pilot signal S. As shown in FIGS. 2P and 2B, the square-wave signal S leads the pilot signal S in phase by 90 ° and is stable in this state. The phase comparator 14 alternately generates a positive signal with a 1/4 period and a negative signal with a 1/4 period as output signals, as FIG. 2D shows. When the output signals of the phase comparator 14 are integrated by the filter 15, the integrated output signal is zero.

However, if the phase of the signal S leads that of the pilot signal S by more than 90 °, the output signal becomes of the phase comparator 14 is large in the positive period compared to the negative period, as Fig. 2C shows. The integrated output signal of the filter 15 thus becomes positive. When the phase of the

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Signal S, compared to that of the pilot signal S by more than Is delayed by 90 °, the output signal of the comparator 14 in the negative period compared to the positive Period large as shown in Fig. 2D. This becomes the output signal of the filter 15 negative.

The filter 15 therefore generates a direct voltage V, the polarity and level of which change in an N-shape as a function of a deviation Δ _{f in} the phase or frequency between the pilot signal S and the signal S, as shown in FIG. The hysteresis width of the N characteristic is determined by the gain of the phase synchronization circuit 10.

With regard to the previous process, the invention is intended to provide a correct switching signal for a reference signal be generated.

An example of the invention will now be described with reference to FIG. where the same reference numerals as in Fig. 1 denote the same elements.

In the example of Fig. 4, the phase comparator 14 consists of a push-pull circuit and has a transistor 20 as a constant current source, a first pair of transistors 21 and 22 in a differential circuit, a transistor 21 as a constant current source, a second pair of transistors 23 and 24 in a differential circuit, a transistor 22 as a constant current source and a third pair of transistors 25 and 26 in a differential circuit. That Stereo signal mixture of the FM receiver 1 is the bases of the transistors 21 and 22 and the square wave signal S. of the flip-flop 13 wirfl the bases of the transistors 24 and 25 and the bases of the transistors 23 and 26 supplied. The phase compared output signals of Fig. 2C to 2E are between the collectors of the transistors

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23, 25 and output between the collectors of the transistors 24, 26. The filter 15, which consists of a condenser and the series connection of a capacitor 32 and a resistor 33 in parallel with deir capacitor 31, is connected between the collectors of the transistors 2 4 and 2 5. The DC voltage V of Fig. 3 is from output to the filter 15 and then fed to the oscillator 11.

A measuring instrument 51, the zero point of which is in the middle, is between the outputs of the filter 15 or parallel to the Capacitor 31 is connected, and the oscillator 11 has a setting circuit for the free-running frequency, which is from the parallel connection of a resistor 41 and a capacitor 42 consists. In the example shown is an adjusting resistor 52 connected in series with the resistor 41.

In the circuit structure described above, if the free-running frequency of the oscillator 11 and thus its oscillation frequency differ, the polarity and the level of the DC voltage V is changed depending on the deviation as in FIG. 3. The DC voltage V is fed to the measuring instrument 51, which measures the magnitude and magnitude of the deviation of the oscillation frequency, i. the switching frequency of the circuit 2 indicates. Therefore, if the setting resistor 52 is set so that the When reading on the meter 51 is zero, the deviation of the free-running frequency and the oscillation frequency of the oscillator 11 can be eliminated and it occurs thus there is no deviation in the switching frequency. Through this the separation, the distortion factor, the non-linear crosstalk etc. of the stereophonic signals that at the terminals 3L and 3R can be optimized.

As described above, according to the invention, even if there is a secular, environmental change or deviation

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the frequency of the pilot signal occurs, the phase lock circuit 10 work optimally, and thus the Stereo demodulation can be carried out optimally. The arrangement of the measuring instrument 51 and the setting resistor are sufficient for this 52 in addition to the known circuit arrangement, so that the phase synchronization circuit is very simple in structure and therefore cheap.

The above description has been made for the case that the invention is based on a phase synchronization circuit. to the Stereo demodulation is applied, but it can also be applied to a phase lock circuit of a regulated Turntable can be used in which the rotation of the turntable to a signal z.E. a crystal oscillator is synchronized, and also to a phase synchronization circuit the demodulator of a 4-channel stereo playback device with a so-called carrier system.

It is also possible to use the DC voltage ν of the filter 15 to the measuring instrument 51 via an amplifier or a display element such as a light emitting diode instead of the measuring instrument 51 to use.

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Claims (6)

27H656 claims 1., phase synchronization circuit, consisting of a tunable oscillator, a ¹ phase comparator for comparing the phase between the output 5 gnsl of the tunable oscillator and a reference signal and for generating a control signal depending on the phase difference between these, and a device to feed the control signal to the tunable oscillator, characterized by a Display device for displaying the phase difference between the output signal of the adjustable oscillator and deir. Bezuassignal, and. a device for changing the frequency of the output signal of the tunable oscillator. 2. Circuit according to claim 1, characterized by a Filter that goes between the phase comparator and the tunable Oscillator is switched, and in that the display device is connected to the filter. 3. Circuit according to claim 2, characterized in that the phase comparator of a first pair of transistors to which the reference signal is applied, a second Pair of transistors that go with one transistor of the first Pair of transistors connected, and a third pair of transistors connected to the. other transistor of the first pair of transistors are connected, there is that the output signal of the tunable oscillator the second and third. Pair of transistors is fed that the filter is between the second and third pair Transistors is switched, and that the display device consists of a measuring instrument with the Filter is connected. 4. A circuit according to claim 3, characterized in that the filter consists of at least one resistor and one 709841 / O930 27U656 ' Κ- There is a capacitor connected between one of the transistors of the second pair of transistors and one of the transistors of the third pair of transistors sinr ¹ . 5. A circuit according to claim 1, characterized by a Frequency divider between the tunable The oscillator and the phase comparator are connected to the frequency of the output signal of the tunable To share the oscillator. 6. A circuit according to claim 1, characterized by a device for generating an FM-Sterpoeignalaeni schs, a device for generating left and right stereo signals from the stereo signal mix and a frequency divider that is tunable between the. oscillator and the phase comparator is connected, and in that a pilot signal with a frequency "on 19 kHz in the phase comparator is fed to the stereo signal as a reference signal that the oscillator can be tuned generates a signal with a frequency of 76 kKz, and that the frequency divider divides the frequency of the signal of the tunable oscillator by four. 709841/0930