JP3591256B2 - Luminance signal processing circuit for color video camera - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a signal processing circuit of a color video camera, and more particularly to a luminance signal processing circuit including luminance correction.
[0002]
[Prior art]
A color video camera using a solid-state imaging device, particularly a CCD solid-state imaging device, is mainly used. The basic processing process is a process of detecting an image image as a charge stored in a photoelectric conversion element by a solid-state imaging device, and converting a digital signal obtained by quantizing a charge amount into an analog image signal by a low-pass filter or the like. Is included.
[0003]
On the other hand, the actual resolution is determined by the number of pixels of the CCD solid-state imaging device. However, after the sampling and restoration processes, generation of a false signal due to an essentially high spatial frequency component is inevitable.
[0004]
[Problems to be solved by the invention]
FIG. 3 shows an example of a conventional color filter array. Here, a color array composed of W (white), Gr (green), Cy (cyan), and Ye (yellow) is used, and these four pixels are used as a basic unit. In FIG. 3, Px represents the pixel pitch in the horizontal direction, and Py represents the pixel pitch in the vertical direction.
[0005]
Here, in the horizontal direction, a luminance resolution corresponding to a spatial frequency of 1 / Px can be expected. However, for example, due to the difference in the intensity of output signals of a pair of pixels on which light incident through a pair of color filters composed of W and Gr is formed , fs is set as a carrier frequency and the following false signal is generated. Occurs.
[0006]
(Π / 2) · (W-Gr) sin (2π · fs · t)
An object of the present invention is to reduce such a false signal.
[0007]
[Means for Solving the Problems]
In order to achieve the above object, the present invention (claim 1) provides an analog imaging signal from a solid-state imaging device having a plurality of lines formed by repeating a pair of pixels having a pair of color filters having different colors from each other. Analog / digital conversion means for converting to a digital video signal;
A vertical filter for extracting a vertical high-frequency component from the digital video signal,
First coring processing means for performing coring processing on the high frequency component in the vertical direction;
Main signal generation means for generating a main signal by extracting a low frequency component from the digital video signal,
Pixel separating means that apart min the output signal T1 and the other output signal T2 of one of the pixels of said pair from said digital video signal,
A low-pass filter that forms each raw and low frequency components T1L and low frequency components T2L from the other output signal T2 Metropolitan and said one of the output signals T1,
Moiré processing means for converting the one output signal T1 and the other output signal T2 into a converted signal T1 ′ and a converted signal T2 ′ so as to have the same output value and suppressing moiré ;
A horizontal filter that extracts high-frequency components in the horizontal direction from the moiré-processed signal;
Second coring processing means for performing coring processing on the high-frequency component in the horizontal direction;
The vertical high-frequency component from the first coring processing unit, the main signal from the main signal generation unit, and the horizontal high-frequency component from the second coring processing unit adding to at least provided with a color video camera for luminance signal processing circuit and a luminance signal generation means for generating a luminance signal,
In the moiré processing circuit, for each pixel of each line,
T1 ′ = T1 · (T1L + T2L) / (2 · T1L)
T2 ′ = T2 · (T1L + T2L) / (2 · T2L)
By performing the above-mentioned conversion to reduce a false signal caused by a difference between the output signals of the pair of pixels, and to provide a luminance signal processing circuit for a color video camera.
[0008]
Further, according to the present invention (claim 2), an analog imaging signal from a solid-state imaging device having a plurality of lines formed by repeating a pair of pixels having a pair of color filters having different colors is converted into a digital video signal. Analog / digital conversion means;
A vertical filter for extracting a vertical high-frequency component from the digital video signal,
First coring processing means for performing coring processing on the high frequency component in the vertical direction;
Main signal generation means for generating a main signal by extracting a low frequency component from the digital video signal,
Pixel separating means that apart min the output signal T1 and the other output signal T2 of one of the pixels of said pair from said digital video signal,
A low-pass filter that forms each raw and low frequency components T1L and low frequency components T2L from the other output signal T2 Metropolitan and said one of the output signals T1,
Moiré processing means for converting the one output signal T1 and the other output signal T2 into a converted signal T1 ′ and a converted signal T2 ′ so as to have the same output value and suppressing moiré ;
A horizontal filter that extracts high-frequency components in the horizontal direction from the moiré-processed signal;
Second coring processing means for performing coring processing on the high-frequency component in the horizontal direction;
The vertical high-frequency component from the first coring processing unit, the main signal from the main signal generation unit, and the horizontal high-frequency component from the second coring processing unit adding to at least provided with a color video camera for luminance signal processing circuit and a luminance signal generation means for generating a luminance signal,
In the moiré processing circuit, for each pixel of each line,
T1 ′ = 2 · T1 · T2L / (T1L + T2L)
T2 ′ = 2 · T2 · T1L / (T1L + T2L)
By performing the above-mentioned conversion to reduce a false signal caused by a difference between the output signals of the pair of pixels, and to provide a luminance signal processing circuit for a color video camera.
[0009]
Further, the present invention (claim 3) provides a luminance signal processing circuit for a color video camera, wherein the solid-state image pickup device according to claim 1 or 2 is a CCD solid-state image pickup device.
[0010]
Further, according to the present invention (claim 4), in the above claim 1 or claim 2 , the combination of the pair of color filters is a combination of a filter having a transparent or nearly transparent spectrum and a green filter. A luminance signal processing circuit for a color video camera is provided.
[0011]
Further, according to the present invention (claim 5), the color filter according to claim 1 or 2 , wherein the combination of the pair of color filters is a combination of a magenta filter and a green filter. Provided is a luminance signal processing circuit for a video camera.
[0012]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings by way of preferred examples.
[0013]
FIG. 1 is a schematic configuration diagram of an embodiment in which the circuit of the present invention is employed in a color video camera. In FIG. 1, for the sake of simplicity, components generally provided in a color video camera such as a lens optical system, a recording system on a recording medium, various signal processing systems, and an operation system are omitted. ing.
[0014]
First, the overall schematic configuration will be described.
[0015]
In FIG. 1, light from a subject or the like through a lens optical system (not shown) and a color filter of a complementary color system is incident on a solid-state image pickup device (hereinafter, referred to as a CCD 1) to form an image. In the CCD 1, incident light is photoelectrically converted, and the obtained image signal is supplied to a correlated double sampling circuit (CDS) 2.
[0016]
In the correlated double sampling circuit 2, which is one of the noise reduction method except the CCD random noise (shot noise of the signal and the dark current), I circuit der performing so-called correlated double sampling processing, specific Performs processing to suppress reset noise by subtracting the level of the field through period from the signal period level. The output of the correlated double sampling circuit 2 is sent to an analog / digital (A / D) converter 3.
[0017]
The analog / digital converter 3 includes a sample and hold circuit on the input side, and samples the analog image signal sampled and held by the sample and hold circuit via the correlated double sampling circuit 2 at a predetermined sample frequency. And converts it into a digital signal (hereinafter, referred to as a digital video signal). The digital video signal output from the analog / digital converter 3 is sent to a vertical filter circuit 4, a main signal processing circuit 6, and a pixel separation circuit 8.
[0018]
The vertical filter circuit 4 includes a vertical band-pass filter (V-BPF) for extracting a predetermined vertical frequency band component from the digital video signal, and a vertical high-pass filter (V) for extracting a vertical high-frequency band component from the digital video signal. -HPF) and extracts a vertical contour component from a digital video signal. Incidentally, the vertical band-pass filter and a vertical high-pass filter are both digital filter of the cyclic (IIR) or nonrecursive (FIR), the vertical high-pass filter is set the filter coefficients of the 5-tap Invite example embodiment, the vertical band-pass filter Is set, for example, with a 3-tap filter coefficient. The output signal from the vertical filter circuit 4, that is, the vertical contour component extracted from the digital video signal is sent to the coring processing circuit 5.
[0019]
The coring processing circuit 5 performs a so-called coring process for suppressing a noise component included in a contour component of a video and improving a signal-to-noise ratio (S / N). The signal subjected to the coring processing by the coring processing circuit 5 is sent to a γ (gamma) front contour compensation circuit 12 and a γ rear contour compensation circuit 14 described later.
[0020]
On the other hand, the digital video signal output from the main signal processing circuit 6 (hereinafter, referred to as main signal) is sequentially supplied to the vertical low-pass filter (V-LPF) 7a and a horizontal low-pass filter (H-LPF) 7b.
[0021]
The vertical low-pass filter 7a and the horizontal low-pass filter 7b add a contour component, that is, a high frequency component to the main signal in the γ front contour compensating circuit 12 in the subsequent stage. Is removed. The vertical low-pass filter 7a is a digital filter of the cyclic or non-cyclic, in which for example the filter coefficients of the 5 taps that have been set. The main signal from which high frequency components have been removed by the vertical low-pass filter 7a and the horizontal low-pass filter 7b is supplied to the γ front contour compensation circuit 12.
[0022]
Next, the pixel separation circuit 8 converts the digital video signal supplied from the analog / digital converter 3 into a W (white) , Gr (green), Cy (cyan), and Ye (yellow) complementary color filter array. Since these signals are sequentially supplied, the signals of the pixels respectively corresponding to W, G, Cy, and Ye are separated from these sequentially supplied signals. Further, in the pixel separation circuit 8, (as the complementary color signals in other words missing portion is present) in order to interpolate the portion corresponding to the pixel omission by performing the pixel separation, for example of pixels in the horizontal direction It is also possible to perform interpolation. The signal output from the pixel separating circuit 8 and the signal from which the high frequency component has been removed through the horizontal low-pass filter 8a are supplied to the moiré processing circuit 9 to the moiré processing circuit 9.
[0023]
The moire processing circuit 9, as will be described later, is also a signal conversion circuit for converting W supplied from the pixel separation circuit 8, G, Cy, and each level balance of the complementary color signals of Ye in so that, W, A moiré process is performed to suppress the moiré by balancing the levels of the G, Cy, and Ye complementary color signals . The output signal from the moiré processing circuit 9 is supplied to a horizontal high-pass filter (H-HPF) 10. Also, from the said moire processing circuit 9, to that control signal yf1 used in the coring processing circuit 5 is also output.
[0024]
The horizontal high-pass filter 10 extracts a high frequency band component from the supplied signal. That is, the horizontal high-pass filter 10 outputs a high frequency component in the horizontal direction after the moiré processing. An output signal from the horizontal high-pass filter 10 is supplied to a coring processing circuit 11.
[0025]
The coring processing circuit 11 has substantially the same configuration as the coring processing circuit 5, and suppresses a noise component included in a high-frequency component of a signal supplied from the horizontal high-pass filter 10, A coring process for improving a signal-to-noise ratio (S / N) is performed. The high frequency component in the horizontal direction after the moiré processing subjected to the coring processing by the coring processing circuit 11 is sent to the γ front contour compensation circuit 12.
[0026]
The γ front contour compensation circuit 12 is obtained by the vertical contour components obtained by the vertical filter circuit 4 and the coring processing circuit 5, and by the main signal processing circuit 6, the vertical low-pass filter 7a, and the horizontal low-pass filter 7b. A luminance signal is formed by mixing the main signal from which the high-frequency component has been removed and the horizontal high-frequency component after the moiré processing and the coring processing obtained by the configuration from the pixel separation circuit 8 to the coring processing circuit 11. At the same time, contour compensation of the luminance signal is performed. The video signal subjected to the contour compensation by the γ front contour compensation circuit 12 is supplied to a gamma processing circuit 13.
[0027]
The gamma processing circuit 13 performs a γ (gamma) correction process for correcting a gamma characteristic of a CRT (cathode ray tube) to be used as a display device, using a digital video signal supplied from the γ front contour compensation circuit 12. Apply to The video signal subjected to the gamma correction processing by the gamma processing circuit 13 is sent to the γ rear contour compensation circuit 14 and the horizontal aperture control circuit 16.
[0028]
The horizontal aperture control circuit 16 performs horizontal (and vertical) aperture correction on the video signal subjected to the gamma correction processing in the gamma processing circuit 13, and outputs the video signal after the aperture correction to the coring processing circuit 15. Supply.
[0029]
The coring processing circuit 15 also has substantially the same configuration as the coring processing circuit 11 and the coring processing circuit 5, and suppresses a noise component included in a high frequency band component of a video signal, and performs signal-to-noise processing. A coring process for improving the ratio (S / N) is performed. The output signal of the coring circuit 1 5 is sent to a contour compensating circuit 14 after gamma.
[0030]
The post-gamma contour compensating circuit 14 includes a vertical contour component obtained by the vertical filter circuit 4 and the coring processing circuit 5, a video signal after gamma correction processing from the gamma processing circuit 13, a horizontal aperture control circuit 16, The signal after the horizontal aperture correction obtained by the coring processing circuit 15 is mixed to perform contour compensation of the luminance signal after the gamma correction processing.
[0031]
The output signal of the post-γ contour compensating circuit 14 is output as a digital video signal of the color video camera of the present embodiment or is recorded on a recording medium. The video camera of the present embodiment has the above configuration.
[0032]
Next, processing of digital video signals sequentially supplied from the pixel separation circuit 8 will be described. Here, features that are essential parts of the present invention are included.
[0033]
As shown in FIG. 3, the color filter array of the CCD 1 used in this camera has a color arrangement in which four pixels of W , Gr, Cy, and Ye are defined as one unit. In FIG. 3 , Px represents the pixel pitch in the horizontal direction, and Py represents the pixel pitch in the vertical direction.
[0034]
In the CCD 1, as shown in FIG. 2, the electric charges stored in the photoelectric conversion elements 18 provided in each pixel are transferred to the vertical CCD 19 for all pixels, and are read out by the horizontal CCD 20 line by line. . In addition, there are an interleaving method for reading out every other row, a method using two horizontal CCDs, and the like, and all of them can perform exactly the same processing.
[0035]
Therefore, signals of a series of W, Gr, W, Gr... And a series of Cy, Ye, Cy, Ye.
[0036]
Here, in the horizontal direction, generally, a luminance resolution corresponding to a spatial frequency of 1 / Px can be expected. However, after passing through the horizontal low-pass filter 8a , the signal S on the WGr line contains a false signal due to the difference between the intensities of the W signal and the Gr signal, and the following is obtained using fs as the carrier frequency.
[0037]
(Equation 1)
S = (W + Gr) / 2 + (π / 2) · (W−Gr) sin (2π · fs · t)
... (1)
Here, the first term is an original luminance signal, and the second term is a false signal due to a folded component. Then, the following conversion is performed for each pixel of each input line.
[0038]
W ′ = 2 · W · GrL / (WL + GrL)
Gr ′ = 2 · Gr · WL / (WL + GrL)
Cy ′ = 2 · Cy · YeL / (CyL + YeL)
Ye '= 2 · Ye · CyL / (CyL + YeL)
Here, WL, GrL, CyL and YeL are low frequency components of the output signals W, Gr, Cy and Ye from the CCD, respectively. Specifically, it is obtained from several pixels before and after the target pixel, for example, 5-15 pixels, via the horizontal low-pass filter 8a. This conversion is performed inside the moiré processing circuit 9.
[0039]
By performing such conversion, a low-frequency component SwL and a high-frequency component SwH of W of the WGr line signal obtained from the converted W ′, Gr ′, Cy ′, and Ye ′ are as follows: Looks like.
[0040]
SwL = 2 · W · GrL / (WL + GrL)
SwH = 2 · W · GrL / (WL−GrL)
On the other hand, the component Sg r L in the low frequency region and the component Sg r H in the high frequency region of Gr of the signal on the WGr line are as follows.
[0041]
Sg r L = 2 · Gr · WL / (WL + GrL)
Sg r H = −2 · Gr · WL / (WL−GrL)
Similarly, the component ScyL in the low frequency region and the component ScyH in the high frequency region of the Cy signal on the CyYe line are as follows.
[0042]
Sc y L = 2 · Cy · YeL / (CyL + YeL)
Sc y H = 2 · Cy · YeL / (CyL−YeL)
Further, component S ye H component S ye L and the high frequency range of the low frequency range of the Ye signals CyYe line becomes as follows.
[0043]
Sy e L = 2 · Ye · CyL / (CyL + YeL)
Sy e H = -2 ・ Ye ・ CyL / (CyL-YeL)
Therefore, it is understood that the aliasing component in the high frequency region has the same level in each pixel. Conventionally, the luminance component has been averaged by a low-pass filter. However, in the present invention, the above calculation is performed without adding in the horizontal direction.
[0044]
Since the spectral effect obtained by the above calculation is equivalent to a common spectral component of each pixel, that is, Gr spectral, the calculation result is a process in a frequency band (luminance band) which does not affect color reproduction.
[0045]
Further, the above-described effect is the same even when the following conversion is used.
[0046]
W ′ = W · (WL + GrL) / (2 · WL)
Gr ′ = Gr · (WL + GrL) / (2 · GrL)
Cy ′ = Cy · (CyL + YeL) / (2 · CyL)
Ye ′ = Ye · (CyL + YeL) / (2 · YeL)
Further, the same conversion as the above conversion may be performed in the vertical direction. That is, the difference in the vertical direction is equivalent to the difference in the horizontal direction, and the following conversion may be performed using Yw as the luminance of the WGr line and Yc as the luminance of the CyYe line.
[0047]
Yw '= Yw / (YwL + YcL)
Yc '= Yc / (YwL + YcL)
Again, the letter L has been added to indicate components in the low frequency range.
[0048]
As described above, the color arrangement having four pixels of W , Gr , Cy , and Ye as one unit has been described. However, the present invention is not limited to this, and the conversion is effective even with another type of filter. For example, the same processing is effective for a CCD solid-state imaging device having a color array in which four pixels of Mg (magenta) , Gr, Cy, and Ye as one unit as shown in FIG. In this case, the conversion process is as follows.
[0049]
Mg ′ = 2 · Mg · GrL / (MgL + GrL)
Gr ′ = 2 · Gr · MgL / (MgL + GrL)
Cy ′ = 2 · Cy · YeL / (CyL + YeL)
Ye '= 2 · Ye · CyL / (CyL + YeL)
Or Mg ′ = Mg · (MgL + GrL) / (2 · MgL)
Gr ′ = Gr · (MgL + GrL) / (2 · GrL)
Cy ′ = Cy · (CyL + YeL) / (2 · CyL)
Ye ′ = Ye · (CyL + YeL) / (2 · YeL)
[0050]
【The invention's effect】
As described above, according to the present invention, it is possible to greatly suppress a false signal generated in the luminance signal processing for a color video camera.
[Brief description of the drawings]
FIG. 1 is a block diagram of a system using a luminance signal processing circuit for a color video camera according to an embodiment of the present invention.
FIG. 2 is a view for explaining charge transfer in a CCD solid-state imaging device of a color video camera including a color video camera luminance signal processing circuit according to an embodiment of the present invention.
FIG. 3 is a diagram showing a color filter array of a CCD solid-state imaging device of a color video camera provided with a luminance signal processing circuit for a color video camera according to an embodiment of the present invention.
FIG. 4 is a diagram showing another example of a color filter array used in the CCD solid-state imaging device of the color video camera according to the embodiment of the present invention.
[Explanation of symbols]
Reference Signs List 1 solid-state imaging device 2 correlated double sampling circuit 3 digital converter 4 vertical filter circuit 5 coring processing circuit 6 main signal processing circuit 7a vertical low-pass filter 7b horizontal low-pass filter 8 pixel separation circuit 8a horizontal low-pass filter 9 moire processing circuit (signal Conversion circuit)
Reference Signs List 10 horizontal high-pass filter 11 coring processing circuit 12 front contour compensation circuit 13 gamma processing circuit 14 rear contour compensation circuit 15 coring processing circuit 16 horizontal aperture control circuit 18 photoelectric conversion element 19 vertical CCD
20 horizontal CCD

Claims (5)

Analog / digital conversion means for converting an analog imaging signal from a solid-state imaging device having a plurality of lines formed by repeating a pair of pixels having a pair of color filters having different colors from each other into a digital video signal;
A vertical filter for extracting a vertical high-frequency component from the digital video signal,
First coring processing means for performing coring processing on the high frequency component in the vertical direction;
Main signal generation means for generating a main signal by extracting a low frequency component from the digital video signal,
Pixel separating means that apart min the output signal T1 and the other output signal T2 of one of the pixels of said pair from said digital video signal,
A low-pass filter that forms each raw and low frequency components T1L and low frequency components T2L from the other output signal T2 Metropolitan and said one of the output signals T1,
Moiré processing means for converting the one output signal T1 and the other output signal T2 into a converted signal T1 ′ and a converted signal T2 ′ so as to have the same output value and suppressing moiré ;
A horizontal filter that extracts high-frequency components in the horizontal direction from the moiré-processed signal;
Second coring processing means for performing coring processing on the high-frequency component in the horizontal direction;
The vertical high-frequency component from the first coring processing unit, the main signal from the main signal generation unit, and the horizontal high-frequency component from the second coring processing unit adding to at least provided with a color video camera for luminance signal processing circuit and a luminance signal generation means for generating a luminance signal,
In the moiré processing circuit, for each pixel of each line,
T1 ′ = T1 · (T1L + T2L) / (2 · T1L)
T2 ′ = T2 · (T1L + T2L) / (2 · T2L)
A luminance signal processing circuit for a color video camera, characterized in that a false signal generated due to a difference between the output signals of the pair of pixels is reduced by performing the above conversion. Analog / digital conversion means for converting an analog imaging signal from a solid-state imaging device having a plurality of lines formed by repeating a pair of pixels having a pair of color filters having different colors from each other into a digital video signal;
A vertical filter for extracting a vertical high-frequency component from the digital video signal,
First coring processing means for performing coring processing on the high frequency component in the vertical direction;
Main signal generation means for generating a main signal by extracting a low frequency component from the digital video signal,
Pixel separating means that apart min the output signal T1 and the other output signal T2 of one of the pixels of said pair from said digital video signal,
A low-pass filter that forms each raw and low frequency components T1L and low frequency components T2L from the other output signal T2 Metropolitan and said one of the output signals T1,
Moiré processing means for converting the one output signal T1 and the other output signal T2 into a converted signal T1 ′ and a converted signal T2 ′ so as to have the same output value and suppressing moiré ;
A horizontal filter that extracts high-frequency components in the horizontal direction from the moiré-processed signal;
Second coring processing means for performing coring processing on the high-frequency component in the horizontal direction;
The vertical high-frequency component from the first coring processing unit, the main signal from the main signal generation unit, and the horizontal high-frequency component from the second coring processing unit adding to at least provided with a color video camera for luminance signal processing circuit and a luminance signal generation means for generating a luminance signal,
In the moiré processing circuit, for each pixel of each line,
T1 ′ = 2 · T1 · T2L / (T1L + T2L)
T2 ′ = 2 · T2 · T1L / (T1L + T2L)
A luminance signal processing circuit for a color video camera, characterized in that a false signal generated due to a difference between the output signals of the pair of pixels is reduced by performing the above conversion. 3. The luminance signal processing circuit for a color video camera according to claim 1, wherein the solid-state imaging device is a CCD solid-state imaging device. 3. The luminance signal processing circuit for a color video camera according to claim 1, wherein the combination of the pair of color filters is a combination of a filter having a transparent or nearly transparent spectrum and a green filter. . 3. The luminance signal processing circuit for a color video camera according to claim 1, wherein the combination of the pair of color filters is a combination of a magenta filter and a green filter.

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