JP2000059798A - Near-infrared light/visible light shared image-pickup device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To utilize effectively both the sensitivity of a near infrared light region and the sensitivity of a visible light region in an image-pickup device, in an image-pickup unit with a solid-state image-pickup element having the sensitivity of both the near infrared ray and the visible light as an image-pickup device. SOLUTION: In an image-pickup unit with a solid-state image-pickup element 11, having sensitivity of an infrared light and a visible light as an image-pickup device, the unit is equipped with an infrared-ray filter 2 which mounts a color filter 1 transmitting a near-infrared light and an adjustment means 4 which adjusts the position of the infrared-ray filter 2 between a position, where an incident light passes the infrared-ray filter 2 and a position where it does not pass through.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image pickup apparatus using a solid-state image pickup device as an image pickup device, and more particularly, to an image pickup apparatus which can be used for both near infrared light photographing and visible light photographing.

[0002]

2. Description of the Related Art A high-sensitivity black-and-white camera using a CCD image sensor having sensitivity in the near-infrared light region as an image pickup device has been known.

FIG. 3 is a block diagram showing an example of the configuration of an imaging system of such a CCD camera for infrared light.
Since the CCD 11 has sensitivity not only in the near-infrared light region but also in the visible light region, a visible light cut filter 13 for preventing visible light from entering the CCD 11 is provided between the CCD 11 and the photographing lens 12. (For example, in the case where the infrared light CCD camera is used only at night, the visible light cut filter 13 may not be necessarily provided).

[0004] Near-infrared light from an object is
Then, by entering the imaging area of the CCD 11 through the visible light cut filter 13, a signal charge is obtained in each pixel on the imaging area.

The CCD 11 is driven by a drive circuit 14 at a timing at which a drive timing pulse is generated from a timing generator 15 synchronized with a synchronization signal generator 16. As a result, the CCD 11 converts the signal charges obtained for each pixel into a signal voltage and outputs the signal voltage.

The output signal of the CCD 11 is sent to a signal processing unit 17.
Sent to In the signal processing unit 17, the output signal is correlated double-sampled by the CDS circuit 171 and AGC
Automatic gain adjustment in the circuit 172 and γ in the γ correction circuit 173
Correction, Sync. By performing well-known processing such as addition of a synchronization signal in the circuit 174, a monochrome video signal is generated.

[0007]

Although the CCD 11 has sensitivity not only in the near-infrared light region but also in the visible light region, the conventional CCD camera for infrared light uses the CCD 1
Since the visible light incident on 1 was blocked by the visible light cut filter 13, the sensitivity of the CCD 11 in the visible light region was not effectively utilized. In addition, visible light cut filter 1
Even if no 3 is provided, near-infrared light is CC together with visible light.
Since the light enters D11, it cannot be used as a CCD camera for visible light.

On the other hand, a conventional CCD camera for visible light using a CCD image pickup device as an image pickup device also uses a CCD image pickup device having sensitivity not only in the visible light region but also in the near infrared light region. However, in the conventional visible light CCD camera, near-infrared light is blocked by an IR (infrared) cut filter, so that the sensitivity of the CCD image pickup device in the near-infrared light region has not been effectively utilized.

Therefore, an object of the present invention is to provide a solid-state imaging device having sensitivity to both near-infrared light and visible light as an imaging device. It is to utilize both of them effectively.

[0010]

According to the present invention, a near-infrared light /
The visible light shared imaging device is an imaging device using a solid-state imaging device having sensitivity to near-infrared light and visible light as an imaging device, and a color filter that transmits near-infrared light is mounted on the solid-state imaging device. An infrared cut filter, and switching means for switching the position of the infrared cut filter between a position at which light incident on the solid-state imaging device passes through the infrared cut filter and a position at which light does not pass through the infrared cut filter. Features.

According to this imaging apparatus, when the position of the infrared cut filter is switched to a position at which the incident light to the solid-state image pickup device does not pass through the infrared cut filter by the switching means at night, the near filter transmitted through the color filter can be used. When infrared light is incident on the solid-state imaging device, signal charges are obtained in each pixel on the imaging region. Therefore, a video signal can be generated based on the output signal of the solid-state imaging device that has converted the signal charge into a signal voltage.

On the other hand, when the position of the infrared cut filter is switched to a position where the incident light to the solid-state image sensor passes through the infrared cut filter by the switching means during the daytime, the near infrared light is blocked by the infrared cut filter. Then, when the visible light transmitted through the infrared cut filter and the color filter is incident on the solid-state imaging device, a signal charge is obtained in each pixel on the imaging region. Therefore, a video signal can be generated based on the output signal of the solid-state imaging device that has converted the signal charge into a signal voltage.

As described above, this imaging apparatus effectively utilizes both the sensitivity in the near-infrared light region and the sensitivity in the visible light region of the solid-state imaging device, and is used for photographing with near-infrared light and for using visible light. It can be shared for shooting.

As an example, the image pickup apparatus is further provided with a signal processing circuit for generating a luminance signal and a color difference signal from an output signal of the solid-state image pickup device. A black-and-white image is obtained from the luminance signal generated by the signal processing circuit, and when visible light is incident on the solid-state imaging device, a color image is obtained from the luminance signal and the color difference signal generated by the signal processing circuit. It is suitable. This makes it possible to share the imaging device for capturing a black-and-white image with near-infrared light and for capturing a color image with visible light.

[0015]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG.
1 is a block diagram illustrating an example of a configuration of an imaging system of a visible light shared CCD camera. This camera is C for infrared light shown in FIG.
The present invention is applied to a CD camera, and portions corresponding to those in FIG.

In this CCD camera, G (green) primary color filters, Ye (yellow), Cy (cyan), M
A color filter 1 in which g (magenta) complementary color filters are arranged in a color-difference line-sequential manner is mounted on the CCD 11 (for example, OCC in a photoresist process of the CCD 11).
F (on-chip color filter)).

FIG. 2 shows an example of the spectral characteristics of these complementary color filters. As shown in the figure, these complementary color filters include, for example, 7
The transmittance in the wavelength region of 00 nm to 1000 nm is
Those having a transmittance as high as the transmittance in the wavelength region of the original complementary color are used.

Returning to FIG. 1, the CCD 11 and the photographing lens 12
Are not provided with a visible light cut filter, and an IR cut filter 2 and an optical low-pass filter 3
Are provided. IR cut filter 2 of these
Can be switched between the following two positions p1 and p2 by the operation of the switching mechanism 4 based on the operation of an operation button (not shown) provided on the housing of the camera.

Position p1: As shown by a two-dot chain line in the figure, a position distant from the optical axis of the taking lens 12, that is, a position where incident light to the CCD 11 passing through the taking lens 12 does not pass through the IR cut filter 2. Position p2: As shown by a solid line in the figure, a position on the optical axis of the photographing lens 12, that is, a position where incident light to the CCD 11 passing through the photographing lens 12 passes through the IR cut filter 2.

More specifically, for example, the IR cut filter 2 is configured in the shape of a diaphragm blade in an optical diaphragm device of a general camera, and the switching mechanism 4 is configured as a diaphragm blade opening / closing mechanism in the optical diaphragm device. It is preferred to do so. As a result, the switching mechanism 4 as the opening / closing mechanism completely opens the IR cut filter 2 as the diaphragm blade, thereby switching the position of the IR cut filter 2 to the position p1, while the switching mechanism 4 completely switches the IR cut filter 2 to the position p1. Since the position of the IR cut filter 2 is switched to the position p2 by closing, the position of the IR cut filter 2 can be easily switched by a simple mechanism.

The output signal of the CCD 11 is sent to the signal processing section 5. The signal processing unit 5 is a group of circuits for performing well-known processing for generating a color video signal. The output signal is correlated double sampling by the CDS circuit 51, automatic gain adjustment by the AGC circuit 52, and color separation circuit. Processing and synchronization such as color separation at 53, primary color separation at the process and matrix circuit 54, white balance, white clipping, knee processing, .gamma. Correction, generation of luminance signal Y and color difference signals RY and BY After performing the synchronization processing in the circuit 55, a composite color video signal of, for example, the NTSC system is generated by the processing in the color encoder 56.

Next, the method of use and operation of the camera will be described. At night, the operation button is operated to switch the position of the IR cut filter 2 to the position p1 (C
When the light is switched to a position where the light incident on the CD 11 does not pass through the IR cut filter 2), near-infrared light transmitted through the optical low-pass filter 3 and the color filter 1 enters the CCD 11, so that each pixel on the imaging area is Since a signal charge is obtained, a signal obtained by converting the near-infrared light signal charge into a signal voltage is output from the CCD 11.

Accordingly, at this time, a black-and-white image similar to that obtained by a normal CCD camera for infrared light is obtained from the luminance signal of the composite color video signal generated by the signal processing section 5.

On the other hand, during the daytime, the operation button is operated to switch the position of the IR cut filter 2 by the switching mechanism 4 to the position p2.
When the light is switched to (the position where the light incident on the CCD 11 passes through the IR cut filter 2), the near infrared light is blocked by the IR cut filter 2 and the visible light transmitted through the IR cut filter 2, the optical low-pass filter 3 and the color filter 1. Is CC
Since the signal charge is obtained in each pixel on the imaging area by being incident on D11, a signal obtained by converting the optical signal charge by the visible light into a signal voltage is output from the CCD11.

Therefore, at this time, the composite color video signal generated by the signal processing section 5 is converted into an ordinary CCD for visible light.
A color image similar to that obtained by a camera is obtained.

As described above, this CCD camera is a CCD camera.
Efficiently utilizing both the sensitivity in the near-infrared light region and the sensitivity in the visible light region of 11 can be shared for shooting black-and-white images with near-infrared light and for shooting color images with visible light. it can.

In the above example, the color filters of the color difference line sequential system are mounted on the CCD. However, the present invention is not limited to this. Other suitable color filters of complementary colors or primary colors which have high transmittance in the near-infrared light region as shown in FIG. You may.

In the above example, the position of the IR cut filter 2 is switched between the positions p1 and p2. However, as another example, a visible light cut filter is also provided in addition to the IR cut filter 2, and these two filters are alternately switched between the positions p1 and p2 (at night, the visible light cut filter is shifted to the position p2). Switch, I during the day
The R-cut filter 2 may be switched to the position p2).

In the above example, a signal processing unit for generating a color video signal is provided. However, by providing a signal processing unit for generating a black and white video signal, a black and white image can be obtained even when photographing with visible light. You may do so.

In the above example, the present invention is applied to a camera using a CCD as an image pickup device. However, the present invention is applied to a camera using another appropriate solid-state image pickup device (for example, a CMOS sensor) as an image pickup device. The invention may be applied.

Further, the present invention may be applied to any video camera, digital still camera, or any other imaging device for capturing moving images or still images. In addition, the present invention is not limited to the above-described embodiments, and may take various other configurations without departing from the gist of the present invention.

[0032]

As described above, the near-infrared light /
According to the visible light shared imaging device, both the sensitivity in the near-infrared light region and the sensitivity in the visible light region of the solid-state imaging device are effectively utilized, and the imaging device for the near-infrared light and the imaging for the visible light are used. Can be shared.

Further, the image pickup apparatus is further provided with a signal processing circuit for generating a luminance signal and a color difference signal from an output signal of the solid-state image pickup device. When a black-and-white image is obtained from the luminance signal generated by the circuit and visible light is incident on the solid-state imaging device,
If a color image is obtained from the luminance signal and the color difference signal generated by the signal processing circuit, the imaging device can be used for both capturing a monochrome image using near-infrared light and capturing a color image using visible light. can do.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating an example of the configuration of an imaging system of a near-infrared light / visible light shared CCD camera according to the present invention.

FIG. 2 is a diagram illustrating an example of spectral characteristics of a complementary color filter.

FIG. 3 is a block diagram illustrating an example of a configuration of a conventional imaging system of a CCD camera for infrared light.

[Explanation of symbols]

1 color filter, 2 IR cut filter, 3
Optical low-pass filter, 4 switching mechanism, 5 signal processing unit, 11 CCD, 12 photographing lens, 14
Drive circuit, 15 Timing generator, 16 Synchronous signal generator

 ────────────────────────────────────────────────── ─── Continuing on the front page (72) Inventor: Manabu Ishibashi 6-35, Kita-Shinagawa, Shinagawa-ku, Tokyo Sony Corporation F-term (reference) 2H083 AA04 AA34 AA51 5C022 AA15 AB13 AC42 AC55 AC74 5C065 AA01 AA06 BB07 CC01 DD02 DD17 EE05 EE08 EE12 EE14 EE16 EE20 GG11 GG15

Claims (2)

[Claims] 1. An imaging apparatus using a solid-state imaging device having sensitivity to near-infrared light and visible light as an imaging device, wherein a color filter that transmits near-infrared light is mounted on the solid-state imaging device. An outer cut filter, and a switching unit that switches a position of the infrared cut filter between a position at which light incident on the solid-state imaging device passes through the infrared cut filter and a position at which light does not pass. Near-infrared light / visible light shared imaging device. 2. The near-infrared light / visible light shared imaging device according to claim 1, further comprising: a signal processing circuit that generates a luminance signal and a color difference signal from an output signal of the solid-state imaging device. When near-infrared light is incident on the image sensor, a black-and-white image is obtained from the luminance signal generated by the signal processing circuit,
A near-infrared light / visible light shared imaging device, wherein when visible light is incident on the solid-state imaging device, a color image is obtained from a luminance signal and a color difference signal generated by the signal processing circuit.