JP2658052B2 - Solid-state imaging device - Google Patents

Description

The present invention relates to a solid-state imaging device suitable for being applied to a so-called single-panel color camera.

[Summary of the Invention]

The present invention is a solid-state imaging device suitable for application to a so-called single-chip color camera, and includes a solid-state imaging device and a first color-difference signal forming device that forms a color-difference signal from pixel signals of horizontal lines obtained by the solid-state imaging device Means and a second color difference signal forming means for forming a color difference signal from a pixel signal of a vertical line obtained by the solid-state imaging device, and a space corresponding to a pixel pitch in a horizontal line direction is formed on a light receiving surface of the solid-state imaging device. When the subject light including the frequency in the horizontal line direction is not incident, a composite video signal is obtained from the color difference signal formed by the first color difference signal forming means, and the pixel pitch in the horizontal line direction on the light receiving surface of the solid-state imaging device. When a subject light including a spatial frequency corresponding to the horizontal line direction is incident, a composite video signal is obtained from the color difference signal formed by the second color difference signal forming means. Thus, even if the input bandwidth of the optical low-pass filter is increased, it is possible to suppress the generation of a false color signal due to subject light including a spatial frequency corresponding to the pixel pitch in the horizontal line direction in the horizontal line direction. Thus, the horizontal resolution can be improved.

[Conventional technology]

2. Description of the Related Art Heretofore, there has been known a solid-state imaging device that obtains an NTSC signal using one solid-state imaging device. In such a solid-state imaging device, for example, a color filter array as shown in FIG. 3 is used. This color filter array is generally called a Bayer type color filter array,
Corresponding to each pixel of the solid-state imaging device first horizontal line L ₁ and the second horizontal line L ₂ to the G (green), R (red), arranged color filters G ... R, also, and the third horizontal line fourth horizontal line B (blue), G, B ... arranged color filters G, fifth horizontal line L ₅ after the fourth horizontal line from the first horizontal line L ₁
Those formed by repeating the sequence of L _4. In such a solid-state imaging device, pixel signals of odd lines are read in the first field, pixel signals of even lines are read in the second field, and G and R signals and B and G signals obtained for each horizontal line are read. , A GR color difference signal and a BG color difference signal are obtained, respectively, and an NTSC signal is formed from the GR color difference signal, the BG color difference signal and a luminance signal (hereinafter referred to as a Y signal). I do it. In this case, when subject light having a spatial frequency corresponding to the pixel pitch, that is, the pitch of the color filter array is incident, a false color signal is generated, which causes so-called moire. Therefore, in such a conventional solid-state imaging device, an optical low-pass filter (hereinafter, referred to as an optical LPF) including, for example, a crystal filter using birefringence is arranged in front of the color filter array, and corresponds to a pixel pitch. The spatial frequency signal is optically removed so that a false color signal is not generated.

[Problems to be solved by the invention]

However, in such a conventional solid-state imaging device,
Since the incident frequency is optically limited using the optical LPF, the horizontal resolution is also limited by the input bandwidth of the optical LPF, and there is a disadvantage that the horizontal resolution cannot be improved.

In view of the above, an object of the present invention is to provide a solid-state imaging device capable of suppressing generation of a false color signal and improving horizontal resolution.

[Means for solving the problem]

As shown in FIG. 1, for example, a solid-state imaging device according to the present invention includes a solid-state imaging device (1) and a first device that forms a color difference signal from pixel signals of horizontal lines obtained by the solid-state imaging device (1). Color difference signal forming means (2) and solid-state imaging device (1)
And a second color difference signal forming means (3) for forming a color difference signal from the pixel signal of the vertical line obtained at the same time. The spatial frequency corresponding to the pixel pitch in the horizontal line direction is provided on the light receiving surface of the solid-state imaging device (1). Is not incident on the object light, the first color difference signal forming means (2)
A composite video signal is obtained from the color difference signal formed by the following equation, and when subject light including a spatial frequency corresponding to a pixel pitch in the horizontal line direction in the horizontal line direction is incident on the light receiving surface of the solid-state imaging device (1). The composite video signal is obtained from the color difference signal formed by the second color difference signal forming means (3).

(Operation)

According to the present invention, when subject light included in the horizontal line direction having a spatial frequency corresponding to the pixel pitch in the horizontal line direction is incident on the light receiving surface of the solid-state imaging device (1),
Since the composite video signal is obtained by the color difference signal obtained from the pixel signal of the vertical line, even if the input bandwidth of the optical LPF is expanded, the spatial frequency corresponding to the pixel pitch in the horizontal line direction is changed to the horizontal line. It is possible to prevent the generation of a false color signal due to the incidence of subject light included in the direction. Therefore, according to the present invention, the input bandwidth of the optical LPF can be increased, and the horizontal resolution can be improved.

〔Example〕

Hereinafter, an embodiment of the solid-state imaging device according to the present invention will be described with reference to FIGS. 1 and 2.

In FIG. 1, (1) shows a solid-state image pickup device which adopts reading of two rows simultaneously and reads signals of all pixels for each field. In this example, this solid-state image pickup device (1) For example, the color coding of the color filter array of the HE98241 manufactured by Hitachi, which is a MOS type solid-state imaging device, is changed to achieve the color coding shown in FIG. That is, the solid-state image sensor HE98241 has a color filter array composed of W (white), Cy (cyan), G (green), and Ye (yellow) on its light-receiving surface. In place of the color filter array, as shown in FIG. 2, odd-numbered horizontal lines L ₁ , L ₃ ,.
G ... R color filters (hereinafter, G in odd-numbered horizontal lines are referred to as G _A ), and B, G, B ... G color filters (hereinafter, referred to as G) in even-numbered horizontal lines L ₂ , L ₄ ,. the G in the even-numbered horizontal lines is provided the color filter array (4) comprising arranged) of G _B, an output terminal (5) (6)
(7) G _A signal from each odd-numbered horizontal lines (8), R signal, B signals from the even-numbered horizontal lines, to as it is possible to obtain a G _B signals.

In this example, the _GA signal obtained at the output terminal (5) of the solid-state imaging device (1) is converted into an inverting input terminal of one of the operational amplifiers (9) constituting the first color difference signal forming means (2). And the solid-state imaging device (1)
The R signal obtained at the output terminal (6) of the operational amplifier (9)
The supply to the non-inverting input terminal, to give the R-G _A signal on the output side of the operational amplifier (9), the one fixed contact of one of the switch the R-G _A signal (10) (10A) Supply.

The B signal obtained at the output terminal (7) of the solid-state imaging device (1) is supplied to the non-inverting input terminal of the other operational amplifier (11) constituting the first color difference signal forming means (2). the G _B signals obtained at the output terminal (8) of the solid-state imaging device (1) is supplied to the inverting input terminal of the operational amplifier (11), to obtain a B-G _B signal at the output side of the operational amplifier (11) and supplies the B-G _B signals to the other one of the fixed contact of the changeover switch (12) (12A).

In this example, the R signal obtained at the output terminal (6) of the solid-state imaging device (1) is supplied to the non-inverting input terminal of one of the operational amplifiers (13) constituting the second color difference signal forming means (3). Supply and the solid-state imaging device (1)
G _B signals an operational amplifier obtained at the output terminal (8) (13)
And the supplied to the inverting input terminal, to give the R-G _B signal at the output side of the operational amplifier (13), supplied to the other to a fixed contact of the R-G _B signal one changeover switch (10) (10B) I do.

Also obtained at the output terminal (5) of the solid-state imaging device (1).
The G _A signal is supplied to the inverting input terminal of the other operational amplifier (14) constituting the second color difference signal forming means, and the B signal obtained at the output terminal (7) of the solid-state imaging device (1) is calculated. is supplied to the non-inverting input terminal of the amplifier (14), to obtain a B-G _a signal on the output side of the operational amplifier (14), the B-
Supplies G _A signal to the other fixed contact of the other changeover switch (12) (12B).

Here, the switching of one of the changeover switches (10) is controlled by an absolute value circuit (15) to be described later.
When the switching signal is not supplied from the 5), one fixed contact of the movable contact of the (10C) is R-G _A signal is supplied (10
Also connected to the A), when the switching signal is supplied from the absolute value circuit (15), only while the switching signal is supplied, the movable set of (10C) is R-G _B signals are supplied the manner may be connected to the other fixed contact (10B), also obtained on the movable contact (10C) in this manner R-G _a signal or R
Forming a -G _B signal so as to supply to the encoder (16) to form an NTSC signal.

Also controlled by the other of the switch (12) the absolute value circuit (15), when the switching signal from the absolute value circuit (15) is not supplied, the movable contact of the (12C) is B-G _B signals are supplied Even when connected to one of the fixed contacts (12A), when the switching signal is supplied from the absolute value circuit (15), the movable setting (12) is performed only during the period when the switching signal is supplied.
The C) to as B-G _A signal may be connected to the other fixed contact to be supplied (12B), also the movable contact in this way (12
Forming a B-G _B signals or B-G _A signal obtained C) so as to supply to the encoder (16).

In this example, a Y signal is formed as is well known in the art, and this Y signal is transmitted via a terminal (17) to an encoder (16).
To supply. Here the encoder (16) is also constructed as known conventionally, R-G _A signal, the NTSC signal is formed from the B-G _B signals and Y signal, as obtained at the output terminal of the斯Ru NTSC signal (18) To In the case where the encoder (16) constructed in this manner, R-G _A signal and B-G _B in the encoder (16)
In place of the signal, the R-G _B signal and B-G _A signal is supplied, NT these R-G _B signal and B-G _A signal and Y signal
This is where the SC signal is formed.

In the present example, to obtain a G _A + B signal by adding a G _A and B signals obtained at the output terminal (5) and (7) of the solid-state imaging device (1) at one adder (19), The G _A + B signal is supplied to the non-inverting input terminal of the operational amplifier (21), and the R signal and the G _B signal obtained at the output terminals (6) and (8) of the solid-state imaging device (1) are converted to the other signals. adder (21) adding at and supplied to the inverting input terminal of the operational amplifier (20), the output side of the operational amplifier (20) (G _a + B) -
To such obtain (R + G _B) signal. Here, when subject light including a spatial frequency corresponding to the pixel pitch in the horizontal line direction in the horizontal line direction is incident on the light receiving surface of the solid-state imaging device (1), the pixel signal of the horizontal line is output at a frequency corresponding to this. In this case, a positive or negative voltage can be obtained at the output side of the operational amplifier (20). Therefore, when the output side of the operational amplifier (20) is connected to the input side of the absolute value circuit (15), and the frequency signal corresponding to the pixel pitch in the horizontal line direction is output from the solid-state imaging device (1), A positive voltage is obtained at the output side of the absolute value circuit (15), and this positive voltage can be supplied as a switching signal to the control terminals of one and the other changeover switches (10) and (12). As described above, the switching control of one and the other switches (10) and (12) is controlled by the absolute value circuit (1).
5) to be able to do it. That is, when the switch signal is not supplied to the one and the other switch (10) and (12), the one and the other switch (10)
When the movable contacts (10C) and (12C) of (12) and (12C) are connected to the fixed contacts (10A) and (10C), respectively, and the switching signal is supplied, only during the period when the switching signal is supplied ,
The movable contact (10C) and (12C) are each connected to the other fixed contact (10
Connect to (B) and (12B).

In the solid-state imaging device of this example configured as described above,
When the pixel signal of the horizontal line does not include a frequency signal corresponding to the pixel pitch in the horizontal line direction, no switching signal is output to the output side of the absolute value circuit (15), and one and the other of the switching switches ( Since no switching signal is supplied to 10) and (12), one and the other changeover switches (10) and (12) respectively change their movable contacts (10C) and (12C) to one fixed contact (10A) and (10A). 12A). Therefore, in this case, R-G _A signal obtained from the pixel signals of the horizontal lines, B-G _B signals and Y signal are supplied to the encoder (16), which are the output terminals (18) R-G _A
Signal, it is possible to obtain an NTSC signal formed from B-G _B signals and Y signal.

On the other hand, when the horizontal line pixel signal includes a frequency signal corresponding to the pixel pitch in the horizontal line direction, a switching signal consisting of a positive voltage is output to the output side of the absolute value circuit (15), and this switching is performed. The signal is supplied to one and the other changeover switches (10) and (12), and the one and the other changeover switches (10) and (12) respectively have their movable contacts (10
C) and (12C) are to be connected to the other fixed contacts (10B) and (12B). Therefore, in this case, R-G _B signals obtained from the pixel signals of the vertical line, since B-G _A signal and the Y signal is supplied to the encoder (16), the output terminal (18) R-G _B signal, it is possible to obtain an NTSC signal formed from B-G _a signal and the Y signal.

In the solid-state imaging device of such a present example, when not contain frequency signal corresponding to the horizontal line direction of the pixel pitch in the pixel signals of the horizontal lines, R-G _A signal obtained from the pixel signals of the horizontal lines in a and B-G _B signals and Y signal
Give the NTSC signal, if it contains a frequency signal corresponding to the horizontal line direction of the pixel pitch in the pixel signals of the horizontal lines, and the R-G _B signal and B-G _A signal obtained from the pixel signals of the vertical line Since the NTSC signal is obtained with the Y signal, even if the input bandwidth of the optical LPF is expanded, the subject light including the spatial frequency corresponding to the pixel pitch in the horizontal line direction in the horizontal line direction is not affected. Even if the light enters, the generation of the false color signal due to the subject light can be suppressed.

Therefore, according to the solid-state imaging device of this example, there is an advantage that the input bandwidth of the optical LPF can be expanded, and the horizontal resolution can be improved accordingly.

It should be noted that the present invention is not limited to the above-described embodiment, and it goes without saying that various other configurations can be adopted without departing from the gist of the present invention.

〔The invention's effect〕

According to the present invention, even if the input bandwidth of the optical LPF is enlarged, the subject light including the spatial frequency corresponding to the pixel pitch in the horizontal line direction in the horizontal lie direction is incident, whereby the false color signal is generated. Since it is possible to suppress the occurrence of, the input bandwidth of the optical LPF can be expanded, and there is an advantage that the horizontal resolution can be improved accordingly.

[Brief description of the drawings]

FIG. 1 is a configuration diagram showing one embodiment of the solid-state imaging device of the present invention,
FIG. 2 is a diagram showing an example of a color filter array used in the solid-state imaging device of FIG. 1, and FIG. 3 is a diagram showing an example of a color filter array used in a conventional solid-state imaging device. . (1) is a solid-state image sensor, (2) is first color difference signal forming means, and (3) is second color difference signal forming means.

Claims (1)

(57) [Claims] 1. A solid-state imaging device, first color-difference signal forming means for forming a color-difference signal from horizontal-line pixel signals obtained by the solid-state imaging device, and a vertical-line pixel signal obtained by the solid-state imaging device A second color-difference signal forming means for forming a color-difference signal, wherein when subject light including a spatial frequency corresponding to a pixel pitch in the horizontal line direction in the horizontal line direction is not incident on the light receiving surface of the solid-state imaging device; Is
A composite image signal is obtained from the color difference signal formed by the first color difference signal forming means, and a subject light including a spatial frequency corresponding to a pixel pitch in the horizontal line direction on the light receiving surface of the solid-state imaging device in the horizontal line direction. When is incident,
A solid-state imaging device wherein a composite video signal is obtained from a color difference signal formed by the second color difference signal forming means.