DE4006059A1 - VIDEO INTERFACE PROCESSING CIRCUIT - Google Patents

Abstract

An IF signal is separated into a video component and a color and sound component through first and second band- pass filters 3 and 4, amplified by first and second amplifying circuits 5 and 10 then detected in first and second detecting circuits 7 and 11. The gains of both amplifying circuits are controlled by an AGC voltage derived from the output of the first detecting circuit 7. As the video component and the color and sound component are separated from each other they will not interfere in the amplifying stage 1. The color picture quality, the cross color obstruction and the color and sound beat obstruction may all be improved. The buzz component of the sound may be reduced. Other advantages are described. <IMAGE>

Description

The invention relates Video intermediate frequency processing circuits that are for TV receiver or video tape recorder can be used and in particular a video intermediate frequency Processing circuit to serve from a Video signal component to make a high band that in-phase distortion of a color signal component improve and the hum of a sound signal component too reduce.

To describe the state of the art: Usually be in an intercarrier system that is one of the Signal receiving systems in television receivers and the like is a video carrier component, a color carrier component and a sound component, whose frequencies by means of of a tuner have been implemented using the same Intermediate frequency processing circuit amplified and demodulates which is a kind of a common passband Has. Therefore, in the intercarrier system Intermediate frequency processing circuit simplified but the video signal and the sound signal likely to interfere with each other. As Countermeasures will lower the audio signal level than that Video signal level made or it becomes a sound trap according to the beat frequency between the video  and sound carriers are provided to prevent the Sound signal mixes into the video signal.

Fig. 4 is a block diagram indicating a known video intermediate frequency processing circuit.

In Fig. 4, a television signal from an antenna 21 is converted into an intermediate frequency signal (hereinafter referred to as an IF signal) by means of a tuner 22 and then a video intermediate frequency amplifier circuit 24 (hereinafter referred to as a VIF circuit) via an image area. Acoustic wave filter 23 (hereinafter referred to as a PSF filter) and has a predetermined band characteristic. The signal, the intermediate frequency of which has been amplified by the VIF circuit 24 , is fed to a video demodulator circuit 26 (hereinafter referred to as DET circuit), which is a tank circuit 25 for synchronous demodulation to achieve a video demodulator output (composite video output) ) on an output terminal 28 . An AVR circuit 27 (automatic gain control) generates an AVR voltage that is proportional to the amplitude of the IF signal based on the video demodulator output and controls the gain of the VIF circuit to make the video demodulator output constant is provided between the aforementioned DET circuit 26 and the VIF circuit 24 .

With the above configuration, the band characteristic of the PSF circuit shown in FIG. 5 (a) is formed. That is, the response of the color carrier component C and the video carrier component P are 6 dB lower than the response within the pass band and the response of the sound carrier component S corresponds to a characteristic curve which is approximately 18 dB lower. The band characteristic of the composite video output, which is kept at the output terminal 28 , is shown in FIG. 5 (b), the response of the color carrier component C being less than that of the video carrier component P. The composite video output has separated the color component C by means of a ribbon filter (not shown) which has a ribbon characteristic as shown in FIG. 5 (c). In Fig. 5 (c), the hatched part represents a stray component in the color signal, for example a high band component of a luminance signal, which enters the color band. In this case, in Fig. 5, the abscissa represents the respective relative relationships frequency of a video carrier component P, a color carrier component C and a sound carrier component is S.

In a known circuit which is as above is formed, the following result listed problems.

First of all, since the ink carrier component by 6 dB is reduced, the video tape is not stretched enough and that Video carrier component is reduced in tape. Secondly, since the sound carrier component is reduced by about 18 dB, the buzzer sound is mixed with the Video carrier component increases and especially that Sound quality is at the time of an upset worsened. Third, the beat occurs as a result of Color carrier and sound carrier components in the video tape and appears as a color and Sound beating disability. Fourth, the in-phase Distortion of the ink component is large and that Litter component in the ribbon is also large.

The invention is based on the object To create video intermediate frequency processing circuit which is used to feed a video component of a high band provide a tone buzz, a color and decrease Reduce tone beat disorder, in-phase To improve distortion of a color component and a Improve disability by interspersing in the paint.

To achieve this object, the invention relates to a Video intermediate frequency processing circuit in which an intermediate frequency signal, the frequency of which by means of a Was implemented by a band filter with a tuner predetermined band characteristic and then is amplified and demodulated.

The video intermediate frequency processing circuit is characterized in that it comprises:
a first band filter which has a predetermined video band characteristic including a color band and passes a video carrier component whose frequency has been converted by means of a tuner;
a second band filter, which has a predetermined color and sound band characteristic and passes a color and sound carrier component whose frequency has been converted by the tuner;
a first video intermediate frequency amplifier circuit formed by a balanced input amplifier and amplifying the video carrier component from the first band filter;
a second video intermediate frequency amplifier circuit formed by a balanced input amplifier and amplifying the color and sound carrier components from the second band filter;
a first demodulator circuit that demodulates the video carrier component from the first video intermediate frequency amplifier circuit;
a second demodulator circuit that demodulates the color and carrier components from the second video intermediate frequency amplifier circuit; and
an AFR circuit that generates an AFR voltage based on the output of the first demodulator circuit and controls the gains of the first video intermediate frequency amplifier circuit and the second video intermediate frequency amplifier circuit.

The drawings show:

Fig. 1 is a block diagram of a video intermediate frequency processing circuit according to an embodiment of the invention,

Fig. 2 circuit diagrams for explaining an amplifier with balanced input, which is used in the video intermediate frequency amplifier circuit according to Fig. 1 and an amplifier having an unbalanced input,

Fig. 3 explanatory diagram for explaining the band characteristics in the essential parts of Fig. 1,

Fig. 4 is a block diagram indicating a known video intermediate frequency processing circuit, and

Fig. 5 are explanatory diagrams for explaining the band characteristics in the essential parts of FIG. 4.

It is more preferred to the single description References referred.

Fig. 1 is a block diagram of a video intermediate frequency processing circuit according to an embodiment of the invention.

In this circuit diagram, a television signal from an antenna 1 is converted in frequency by a tuner 2 and is input as an IF signal into a first picture area acoustic wave filter 3 (which is subsequently referred to as a PSF-1 circuit) so that the video signals are processed. and simultaneously into a second image area acoustic wave filter 4 (hereinafter referred to as PSF-2 circuit) for processing the color and sound signals.

The band characteristics of the PSF-1 circuit 3 and the PSF-2 circuit 4 are shown in Figs. 3 (a) and (b), respectively. The IF signal is passed through the PSF-1 circuit 3 enters a Videodemodulatorschaltung 7 (which is hereinafter referred to as DET-1 circuit) and a tank circuit 6 comprises for the purpose of synchronous demodulation of a first video intermediate frequency - amplifier circuit 5 (hereinafter referred to as VIF-1 circuit) so that a video modulation output (composite video output) is obtained at its output terminal 8 . An AVR circuit 9 , which generates an AVR voltage proportional to the amplitude of the IF signal and controls the gain of the VIF-1 circuit 5 , is provided between the aforementioned DET switch 7 and the VIF-1 circuit 5 . On the other hand, the IF signal which has passed through the PSF-2 circuit 4 passes into a demodulator circuit 11 (hereinafter referred to as DET-2 circuit) via a second video intermediate frequency amplifier circuit 10 (which is subsequently referred to as VIF-2 Circuit is called), so that a color and tone demodulator output is obtained at its output terminal 12 . The AVR voltage of the aforementioned AVR circuit 9 is also used to control the gain of the VIF-2 circuit 10 .

A balanced input amplifier shown in FIG. 2 (a) is used for both the above-mentioned VIF-1 circuit 5 and the VIF-2 circuit 10 . In Fig. 2 (a), the VIF amplifier comprises two transistors Q 1 and Q 2 which form a differential arrangement, a transistor Q 3 which forms a current source which is connected to the common emitter of transistors Q 1 and Q 2 , Resistors R 1 and R 2 , which lie between the respective collectors of transistors Q 1 and Q 2 , and a terminal 16 of a voltage source and a resistor R 3 , which lies between the emitter of transistor Q 3 and a reference potential point. A DC voltage source + Vcc is connected to terminal 16 . A signal from the PSF-1 circuit 3 or the PSF-2 circuit 4 is supplied to the input terminals 13 and 14 , which are connected to the base terminals of the transistors Q 1 and Q 2 . An AVR voltage is supplied to terminal 15 , which is connected to the base of transistor Q 3 . An amplifier signal is taken from the output terminals 17 and 18 connected to the collectors of the transistors Q 1 and Q 3 and supplied to the DET-1 circuit 7 or the DET-2 circuit 11 in the next stage. Many such amplifier circuits shown in FIG. 2 (a) can be connected in many stages so that an amplifier signal can be extracted and supplied to the DET-1 circuit 7 or the DET-2 circuit 11 in the next stage.

If such a balanced input amplifier is used, if an input signal is supplied between the base terminals of the two transistors Q 1 and Q 2 , the output signal will be the difference voltage between the collectors of the transistors Q 1 and Q 2 based on the difference between the Collector currents of the transistors Q 1 and Q 2 are emitted, and therefore, even if interference voltages penetrate from the outside, they are canceled among themselves between the collector outputs and there is no interference voltage in the output signal. If the collector currents of transistors Q 1 and Q 2 are changed by applying the AVR voltage to the base of transistor Q 3 , the gain can be easily controlled. In the circuit of FIG. 2 (a), a configuration with a symmetrical input by means of two transistors Q 1 and Q 2 was explained, but a double symmetrical configuration of the amplifier circuit using four transistors can also be used.

In contrast to the balanced input amplifier described above, an unbalanced input amplifier shown in Fig. 2 (b) is an amplifier having a transistor Q 4 and resistors R 4 and R 5 . Shown here is an amplifier type with grounded emitter where an input signal is applied to the base of transistor Q 4 and an output signal is taken from the collector and gain is controlled by controlling the collector current by supplying an AVR voltage to the base. However, a lack of training is that the ability to remove foreign influences is small.

Fig. 3 shows band characteristics in the respective parts of the circuit of Fig. 1. In Fig. 3, the ordinate represents the response (in dB) and the abscissa represents the relative relationships between the respective frequencies of a video carrier component P , a color carrier component C and one Sound carrier component S. FIG. 3 (a) shows a video tape characteristic of the PSF-1 circuit 3 listed above. This is a characteristic of a high-band type which extends to the band of the ink carrier component B compared to the characteristic of the PSF circuit shown in FIG. 5. In addition, the frequency response of a sound carrier component is zero. Fig. 3 (b) shows a band characteristic of the above-mentioned PSF-2 circuit 4 , which is a high band characteristic with an asymmetrical double vertex and comprises a band of the color carrier component C and the sound carrier component S. FIG. 3 (c) shows the frequency response on the output side of the DET-1 circuit 7 mentioned above, in which the video component is obtained as a high band depending on the characteristic of FIG. 3 (a). FIG. 3 (d) shows frequency responses on the output side of the DET-2 circuit 11 mentioned above, in which output characteristic curves, as indicated by dashed lines, are obtained as a function of the characteristic curve according to FIG. 3 (b). In Fig. 3 (d), the solid line represents ribbon components, the chain line represents tape components, and the hatched part represents stray components in the ribbon (e.g., high-band components of a luminance signal).

In the above embodiment, since the video carrier component and the color and sound carrier components are separated and processed in the PSF-1 circuit 3 and the PSF-2 circuit 4 and independent filters are formed, both components can be cut off from each other in their mutual influence , so that the video component can be obtained as a high band, the color and sound components can be separated and processed to have a high color image quality (the in-phase distortion can be reduced and the interference by color interference can be improved) and the component of the Buzzing that mixes with the sound component can be reduced.

Further, since the input system in the VIF stage is a symmetrical input education both in the video processing stage and in the color and sound processing stage as shown in Fig. 2 (a), the ability to improve a disability caused by one of external obstructing signal is caused to be improved. Further, since in the loop of the automatic gain control for the intermediate frequency, the video processing stage and the color and sound processing stage are controlled with the same AVR voltage, it is possible that the gain is made the same size by means of an AVR loop of the same type and it does not become Disadvantage caused by the separation process.

Therefore, according to the invention, video devices such as TV receiver manufactured with high picture and sound quality will.

In the above embodiment, a Image area acoustic wave filter used to create a Video carrier component and a color and To separate the sound carrier component from each other, but the present invention is not limited to this and it can each band filter with the same band characteristic be used.

The invention is not based on the above Embodiment limited and can vary be modified without departing from the subject of the invention to deviate.

Claims (5)

1. Video intermediate frequency processing circuit in which an intermediate frequency signal, the frequency of which has been converted by means of a tuner, is passed through a band filter with a predetermined band characteristic and then amplified and demodulated, characterized in that it comprises:
a first band filter ( 3 ) which has a predetermined video band characteristic including a color band and passes a video carrier component whose frequency has been converted by means of a tuner ( 2 );
a second band filter ( 4 ) which has a predetermined color and tone band characteristic and passes a color and tone carrier component whose frequency has been converted by the tuner ( 2 );
a first video intermediate frequency amplifier circuit ( 5 ), which is formed by a balanced input amplifier and amplifies the video carrier component from the first band filter ( 3 );
a second video intermediate frequency amplifier circuit ( 10 ) which is formed by an amplifier with a symmetrical input and amplifies the color and sound carrier components from the second band filter ( 4 ),
a first demodulator circuit ( 7 ) which demodulates the video carrier component from the first video intermediate frequency amplifier circuit ( 5 ),
a second demodulator circuit ( 11 ) which demodulates the color and carrier components from the second video intermediate frequency amplifier circuit ( 10 ); and
an AFR circuit ( 9 ) which generates an AFR voltage based on the output of the first demodulator circuit ( 7 ) and controls the gains of the first video intermediate frequency amplifier circuit ( 5 ) and the second video intermediate frequency amplifier circuit ( 10 ). 2. Video intermediate frequency processing circuit according to claim 1, characterized in that the first band filter ( 3 ) is formed by an image acoustic wave filter. 3. Video intermediate frequency processing circuit according to claim 1, characterized in that the second band filter ( 4 ) is formed by an image acoustic wave filter. 4. Video intermediate frequency processing circuit according to claim 1, characterized in that in the first video intermediate frequency amplifier circuit ( 5 ) the respective emitters of a first and a second transistor ( Q 1 , Q 2 ) are connected to one another, that the respective collectors of the first and second Transistors ( Q 1 , Q 2 ) are each connected via a first and second load ( R 1 , R 2 ) to a direct current source (+ Vcc ), that a current source circuit ( Q 3 , R 3 ), which has a third transistor ( Q 3 ) contains, connected between the common emitter of the first and second transistors ( Q 1 , Q 2 ) and a reference potential point, that a signal from the first band filter ( 3 ) between the base connections of the first and second transistors ( Q 1 , Q 2 ) is input that an AVR voltage from the AVR circuit ( 9 ) is supplied to the base of the third transistor ( Q 3 ) and that an amplifier signal between the collectors of the first and second transistor ( Q 1 , Q 2 ) is removed. 5. Video intermediate frequency processing circuit according to claim 1, characterized in that in the second video intermediate frequency amplifier circuit ( 10 ) the respective emitters of a first and second transistor ( Q 1 , Q 2 ) are connected to one another, that the respective collectors of the first and second transistor ( Q 1 , Q 2 ) are connected to a DC voltage source (+ Vcc ) each via a first and second load ( R 1 , R 2 ), that a current source circuit ( Q 3 , R 3 ), which has a third transistor ( Q 3 ) has connected between the common emitter of the first and second transistors ( Q 1 , Q 2 ) and a reference potential point, that a signal from the second band filter ( 4 ) is input between the base connections of the first and second transistors ( Q 1 , Q 2 ) that an AVR voltage is introduced from the AVR circuit ( 9 ) to the base of the third transistor ( Q 3 ) and that an amplifier signal between the collectors of the first and second transistor ( Q 1 , Q 2 ) is discharged.