JP3064303B2 - Color signal reproduction circuit - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a color signal reproducing circuit of a video device such as a television receiver.

[Summary of the Invention]

The present invention relates to a color signal reproducing circuit applied to a television receiver or the like, which separates carrier color signals separated from an input video signal into two types of band-pass signals having different pass bandwidths.
The color signal is selectively supplied to the color signal processing circuit via a filter so that a good color signal corresponding to the input signal can be reproduced.

[Conventional technology]

Conventionally, when a color signal is reproduced from a composite video signal obtained by receiving a broadcast signal in a television receiver, a chroma signal is multiplexed with a luminance signal and frequency interleaved and transmitted. As shown in Japanese Patent No. 39794, after extracting a signal transmitted by a chrominance subcarrier frequency by supplying a composite video signal to a comb filter, a band-pass filter extracts a signal of a predetermined band centered on the chrominance subcarrier frequency. A signal is extracted, and a chroma signal extracted by the filter is supplied to a color signal processing circuit to reproduce the color signal. That is, the frequency allocation of the NTSC composite video signal is shown in FIG.
The luminance signal Y has a band up to 4.08 MHz, and the chrominance subcarrier f _c
There is a 3.58 MHz, + 500 kHz to this color subcarrier f _c, -
The chroma signal C is distributed in a 1500 KHz band. In the broadcast signal of the NTSC system, the sound subcarrier frequency f _a is selected to be 4.5 MHz. For this reason, if a band-pass filter that extracts a signal in a band of +500 kHz and −1500 KHz at a center frequency of 3.58 MHz is used as a band-pass filter for extracting a color signal, the chroma signal c can be extracted well. However, in practice, it is difficult to manufacture a band-pass filter having such characteristics satisfactorily, and a band-pass filter that extracts a band with a center frequency of 3.58 MHz and ± 500 kHz has been used.

Note that the upper pass band of the band pass filter + 50
If 0 kHz is extended, the audio signal transmitted by the 4.5 MHz audio sub-carrier f _a is included in the signal passed through the filter, so that a ± 500 kHz band pass filter is used.

[Problems to be solved by the invention]

On the other hand, in recent years, the performance of video tape recorders (VTRs) and video disk players has been improved, and there is a video tape recorder that reproduces a video signal having a bandwidth of, for example, about 6 MHz, which is wider than the signal band up to 4.08 MHz. However, when a color signal is reproduced from such a wideband video signal by using the above-mentioned 3.58 MHz, ± 500 kHz band-pass filter, it is not possible to extract all the transmitted chroma signals, so the wideband There is a disadvantage that the converted signal is not utilized in the received image.

In view of this point, an object of the present invention is to enable optimal color signal reproduction according to an input signal.

[Means for solving the problem]

The chrominance signal reproducing circuit of the present invention, for example, as shown in FIG. 1, converts a carrier chrominance signal separated from an input video signal into first and second band-pass filters (4) and (5) having different pass bands, respectively. ), And the output signals of the first and second band pass filters (4) and (5) are supplied to a color signal processing circuit (7) via a changeover switch (6) to convert the color signals. In addition to the reproduction, the CPU (10) detects the high-frequency video signal component of the input video signal above the audio signal carrier, and switches the changeover switch (6) according to the detection.

[Operation] According to this configuration, a signal in an optimal band according to the color signal band of the input signal is supplied to the color signal processing circuit, and a high-resolution color signal can be obtained by a wideband signal when a wideband signal is used. In the case of a narrow band signal, a chrominance signal can be obtained satisfactorily without interference with signals in other bands.

〔Example〕

Hereinafter, an embodiment of the color signal reproducing circuit of the present invention will be described with reference to FIG.

In FIG. 1, (1) indicates a video signal input terminal,
At this input terminal (1), a composite video signal obtained by demodulating a television broadcast signal received by the tuner and a baseband composite video signal obtained at an external input terminal and reproduced from a VTR are obtained. The composite video signal obtained at the input terminal (1) is supplied to a comb filter (2), which separates the composite video signal into a luminance signal Y and a chroma signal C multiplexed by frequency interleaving in the comb filter (2). Then, the luminance signal Y is supplied from a terminal (3) to a subsequent luminance signal processing circuit (not shown). Further, the separated chroma signal C is supplied to a wide-band band-pass filter (4) and a narrow-band band-pass filter (5). In this case, the band-pass filter for wide band (4) is a filter for passing a signal in a band of ± 1500 kHz with a center frequency of 3.58 MHz, and the band-pass filter for narrow band (5) has a center frequency of 3 .
This filter allows signals in the band of ± 500 kHz at 58 kHz to pass.

The output signal of the broadband band-pass filter (4) is connected to the first fixed contact (6a) of the changeover switch (6).
And the output signal of the band-pass filter for narrow band (5) is supplied to the second fixed contact (6b) of the changeover switch (6).
To supply. The changeover switch (6) is controlled by a central control unit (hereinafter referred to as a CPU) (10), which will be described later, to supply a signal obtained at a movable contact (6m) to a chroma decoder (7). The chroma decoder (7) reproduces a color difference signal from the supplied chroma signal, and supplies the reproduced color difference signal from a terminal (8) to a subsequent circuit.

In the figure, reference numeral (9) denotes a band-pass filter for detecting a high frequency band. The band-pass filter (9) converts a composite video signal obtained at an input terminal (1) from an audio signal carrier.
A signal near 5 MHz where a wideband video signal exists above f _a is extracted. Then, the signal extracted by the band pulse filter (9) is supplied to the CPU (10).
The CPU (10) detects the signal extracted by the filter (9), and when any signal is detected, connects the movable contact (6m) of the changeover switch (6) to the first fixed setting (6a). Is performed, and when no signal in the 5 MHz band is detected, control is performed to connect the movable contact (6m) of the changeover switch (6) to the second fixed contact (6b). In this case, the CPU (1
The detection of the output signal of the band pass filter (9) by (0) is performed at regular intervals.

Next, the operation of reproducing a color signal by this circuit will be described. For example, it is assumed that a baseband video signal having a bandwidth of 4.08 MHz such as a video signal based on a broadcast signal received by a tuner is obtained at a terminal (1). . Since the composite video signal at this time is a signal whose luminance signal Y is up to 4.08 MHz, as shown in FIG. 3, signals such as video signals exist in the 5 MHz band extracted by the band-pass filter (9). Without CPU (10)
Determines that there is no signal. At this time, the CPU (10) sets the movable contact (6m) of the changeover switch (6) to the second fixed contact (6b).
Therefore, the chroma signal C separated by the comb filter (2) is supplied to the chroma decoder (7) via the narrow band band-pass filter (5).

When a wideband video signal having a bandwidth of about 6 MHz reproduced from a VTR or a video disc player is obtained at the terminal (1), a luminance signal Y exists in the 5MHz band extracted by the band-pass filter (9). The CPU (10) determines that there is a signal. At this time, the CPU (10) connects the movable contact (6m) of the changeover switch (6) to the first fixed contact (6a), so that the chroma signal C separated by the comb filter (2) is used for a wide band. Band pass filter (4)
To the chroma decoder (7).

As described above, according to the circuit of this example, the band-pass filters (4) and (5) are switched according to the bandwidth of the input video signal, so that an optimal chroma signal can be extracted according to the input signal. That is, when a broadband signal having a bandwidth of about 6 MHz reproduced from a VTR or the like is input, the CPU (10) determines this, and outputs the output signal of the wideband bandpass filter (4) to the chroma decoder (7). since to be supplied, the signal of 3.58 MHz ± 1500 kHz is extracted by the filter (4) is supplied to a chroma decoder (7), the chroma signal C transmitted by the color subcarrier f _c can be substantially the entire band extraction Thus, good color reproduction with high resolution by a wide band chroma signal can be performed. In this case, the audio signal is not multiplexed in the baseband composite video signal reproduced from the VTR or the like and supplied to the external input terminal, and the audio signal is supplied to another audio input terminal. Therefore, even if the chroma signal is extracted in a wide band of 3.58 MHz ± 1500 kHz, the extracted signal does not include an audio signal, and a good chroma signal without noise can be obtained.

When a video signal having a bandwidth of 4.08 MHz received by the tuner is input, the CPU (10) discriminates this and outputs the output signal of the narrow-band band-pass filter (5) to the chroma decoder (7). 3.58
MHz ± 500 kHz of the signal is extracted by the filter (5) is supplied to a chroma decoder (7), the chroma signal C transmitted by the color subcarrier f _c is extracted in a state of separating the band of audio subcarrier f _a Thus, good color reproduction without noise due to only the chroma signal can be performed.

When a relatively narrow-band signal similar to the broadcast signal shown in FIG. 3 is input as a video signal reproduced from a VTR or the like, the CPU (10) transmits the narrow-band signal in the same manner as when receiving the broadcast signal. To the band pass filter (5).

In the above embodiment, the band pass filter is switched by detecting the bandwidth of the input signal.
The filter may be switched to a preset filter in conjunction with the switching of the input switch. That is, as shown in FIG. 2, the switching information of the input selector switch (11) is transmitted to the CPU (1).
0), and the CPU (1
0) switches the changeover switch (6). In this case, a plurality of, for example, four sets of external input terminals to be switched by the input changeover switch (11) are prepared, and a type display (label rewriting) for displaying an input source name for each input terminal is provided.
Is determined by the input switch (11) or the like. For example, four different types of display such as video 1, video 2, video 3, and video disc are performed on four sets of external input terminals, respectively. Then, the display type information is supplied from the input changeover switch (11) to the CPU (10). And the CPU (1
0) connects the movable contact (6m) of the changeover switch (6) to the first fixed contact (6a) when, for example, the external input terminal on which the video 1 and the video disc are displayed is selected.
Further, when the external input terminal on which the video 2 and the video 3 are displayed is selected, and when the received signal is received by the tuner, the movable contact (6m) of the changeover switch (6) is set to the second fixed contact (6b). To connect. The other parts are configured in the same manner as the circuit of FIG.

Then, a video device whose type is displayed is connected to each external input terminal. At this time, a VTR for reproducing a wideband video signal is connected to a terminal indicated as video 1 and a video signal of a relatively narrow band similar to a broadcast signal is connected to terminals indicated as videos 2 and 3. Connect the VTR to be played.

By doing so, the band pass filter (4) or (5) suitable for the input video signal is automatically selected, and optimal color signal processing suitable for the input signal is performed. In addition, the band pass filter for narrow band (5)
Can be used even when a wideband signal is input (the signal is slightly deteriorated). Therefore, even if a wideband signal is input to video 2 and video 3, there is no problem in use.

Further, the present invention is not limited to the above-described embodiment, but may take various other configurations.

〔The invention's effect〕

According to the present invention, the presence or absence of a high-frequency video signal component above the audio signal carrier of the input video signal is detected, and a band-pass filter that matches the detected bandwidth is automatically selected, and the input video signal is detected. There is an advantage that the color signal reproduction from the signal is appropriately performed for each input signal.

[Brief description of the drawings]

FIG. 1 is a block diagram showing one embodiment of a color signal reproducing circuit of the present invention, FIG. 2 is a block diagram showing another embodiment of the color signal reproducing circuit of the present invention, and FIG. 3 is frequency allocation of a video signal. FIG. (1) is a video signal input terminal, (4) is a broadband band
A pass filter, (5) is a band-pass filter for a narrow band, (6) is a changeover switch, (7) is a chroma decoder, and (10) is a CPU.

──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-58-90890 (JP, A) JP-A-60-22890 (JP, A) JP-A-1-136492 (JP, A) JP-A-1- 160291 (JP, A) JP-A-1-175484 (JP, A) JP-A-1-136492 (JP, A) JP-A-57-106370 (JP, U) JP-A-61-113486 (JP, U) 1-97693 (JP, U) (58) Field surveyed (Int. Cl. ⁷ , DB name) H04N 9/64

Claims (2)

(57) [Claims] 1. A carrier chrominance signal separated from an input video signal,
A changeover switch is used to pass one of the first bandpass filter or the second bandpass filter having a wider bandwidth than the first bandpass filter, and An output signal from one of the second band-pass filters is supplied to a chrominance signal processing circuit to reproduce the chrominance signal, and a third band-pass filter is used to reproduce the chrominance signal. Above, the high band video signal component of the input video signal is detected, and the changeover switch is controlled according to the detected output. For the video signal having the high band video signal component, the second band pass signal A color signal reproduction circuit for selecting a filter. 2. The apparatus according to claim 1, wherein the detection of the high-frequency video signal component of the input video signal is periodically performed at regular intervals.
A color signal reproduction circuit according to the item.