JPH09166493A - Image pick-up device and method therefor and light reception device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To generate an image signal from electromagnetic waves in a plurality of wavelength bands with one image pick-up device. SOLUTION: Infrared rays and visible rays are successively extracted by a chopper 10 and are converted into image signals by an image pick-up element 12. A timing signal is generated by a timing generation part 19 from the position information of the chopper 10 detected by a sensor 14 and the image signals of visible rays or infrared rays are extracted and outputted from a signal outputted from the image pick-up element 12 in synchronization with the signal by an extraction part 13a.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image pickup device, an image pickup method, and a light receiving device, and more particularly to an image pickup device, an image pickup method, and a light receiving device for extracting image signals of different wavelength bands from an inputted electromagnetic wave.

[0002]

2. Description of the Related Art An image pickup device is a device for converting a two-dimensional intensity distribution of an electromagnetic wave (light) incident on a light receiving portion into a corresponding electric signal. This image pickup device is usually designed to have particularly high sensitivity to electromagnetic waves in a predetermined wavelength band. For example, in an image pickup device such as a video camera,
It is designed to have high sensitivity to electromagnetic waves in the visible wavelength range (0.3 to 0.8 μm).

Electromagnetic waves are classified according to their characteristics, and are called infrared rays, visible rays, ultraviolet rays, X-rays, and γ-rays in order of increasing wavelength. Conventionally, an image pickup device having sensitivity only to visible light rays, such as the above-mentioned video camera, has been generally used, but in recent years, an image pickup device having sensitivity to infrared rays, ultraviolet rays, or X-rays is gradually increasing. It tends to generalize.

[0004]

However, the above-mentioned image pickup device having sensitivity to infrared rays, visible rays, ultraviolet rays, or X-rays generally has sensitivity only to each wavelength band, For example, there has been no image pickup device having sensitivity to both visible light and infrared light. Therefore, in order to obtain two-dimensional information from a plurality of types of electromagnetic waves (over a wide wavelength band), there is a problem that a plurality of image pickup devices are required.

Further, in an image pickup device in a wavelength band other than the visible band, the image information obtained by this is different from the information that can be confirmed by the photographer with the naked eye, so it is determined whether or not the image pickup device properly captures the subject. It becomes necessary to make it visible to the photographer. Therefore, conventionally, a visible band image pickup device is attached to an invisible band image pickup device to check whether or not a subject is properly captured.

Therefore, the conventional device has a problem that the shape becomes large. Further, since these two imaging devices have different optical systems, there is a problem in that their visual fields are displaced, and as a result, it is difficult to accurately adjust their positions.

The present invention has been made in view of such a situation, and one image pickup apparatus is capable of obtaining image information of a plurality of different types of electromagnetic waves (wide wavelength bands). This is for miniaturization and for enabling accurate imaging of a subject that radiates (or reflects) electromagnetic waves outside the visible band.

[0008]

According to a first aspect of the present invention, there is provided an image pickup device, which includes an extracting means for selectively extracting an electromagnetic wave in a predetermined wavelength band from an input electromagnetic wave, and an electromagnetic wave extracted by the extracting means. And an output unit for outputting the image signal converted by the converting unit.

According to a sixth aspect of the image pickup method, an electromagnetic wave in a predetermined wavelength band is selectively extracted from an input electromagnetic wave,
It is characterized in that the extracted electromagnetic wave is converted into a corresponding image signal and the converted image signal is output.

According to a seventh aspect of the present invention, in a light receiving device having a plurality of types of light receiving elements each having sensitivity to electromagnetic waves in different wavelength bands, at least one of the plurality of types of light receiving elements is , And is sensitive to wavelength bands other than the visible region.

An image pickup apparatus according to claim 8 is provided with a converting means for converting an inputted electromagnetic wave into a corresponding image signal, and an outputting means for outputting the image signal converted by the converting means, the converting means comprising: It has a plurality of types of light receiving elements that are respectively sensitive to electromagnetic waves in a plurality of different wavelength bands, and at least one of the plurality of types of light receiving elements is sensitive to wavelength bands other than the visible region. Characterize.

An image pickup method according to a tenth aspect of the present invention has a plurality of types of light receiving elements each having sensitivity to electromagnetic waves in a plurality of different wavelength bands, and at least one of the plurality of types of light receiving elements is visible. A light receiving device having sensitivity to a wavelength band other than the region is provided, the input electromagnetic wave is converted into a corresponding image signal by the light receiving device, and the converted image signal is output.

[0013]

1 is a block diagram showing a configuration example of an image pickup apparatus of the present invention. In this figure, the chopper 10 (extracting means) is configured to transmit only the electromagnetic waves of a predetermined wavelength band among the inputted electromagnetic waves. The details of the chopper 10 will be described later. The lens 11 transmits the electromagnetic wave transmitted through the chopper 10 to the image sensor 1
2 (conversion means) to converge on a predetermined area. The image pickup device 12 converts the electromagnetic wave converged by the lens 11 into a corresponding electric signal and outputs it as an image signal.

The image processing unit 13 controls the image pickup device 12 and, for example, AGC (Auto Gain Cont) for the output signal from the image pickup device 12 so that the output signal becomes constant.
rol) processing is performed. Also, the extraction unit 1
3a (output means) synchronizes with the timing signal output from the timing generation unit 19 to extract an image of visible light and an image of infrared, and converts these into a signal that can be input to a television receiver or the like. , Is designed to output.

The sensor 14 is adapted to convert an electromagnetic wave periodically shielded by the chopper 10 into a corresponding electric signal. The reference signal generator 15 generates a reference signal that serves as a reference for controlling the angular velocity of the chopper 10, and supplies the reference signal to the comparator 16. The comparison unit 16 uses the sensor 1
4 and the reference signal supplied from the reference signal generator 15 are compared in phase to generate a control signal corresponding to the phase difference. The drive unit 17 drives the motor 18 based on the control signal supplied from the comparison unit 16. Motor 1
8 is adapted to rotate the chopper 10 by the electric power supplied from the drive unit 17. The timing generator 19 generates a timing signal for switching and outputting a visible light image or an infrared image according to a signal supplied from the sensor 14.

FIG. 2 is a view showing a part of the cross section of the image pickup device 12. The light receiving unit 30 is a PtSi / P-Si Schottky barrier diode (hereinafter referred to as PtSiSBD).
And converts incident electromagnetic waves into corresponding charges. The guard ring 31 reduces the leak current leaking from the light receiving unit 30 to the outside, and improves the sensitivity of the light receiving unit 30.

The charge transfer path diffusion region 32 transfers the charges obtained in the light receiving section 30 by changing the depth of the depletion layer. The charge transfer electrode 33 is
It is adapted to transmit a control signal for transferring charges. The surface protection film 35 is formed in order to protect the element from a shock or the like. The thermal oxide film 36 prevents the elements formed on the P-type silicon (P-Si) substrate 34 from electrically interfering with each other.

The PtSiSBD constituting the light receiving section 30 is
Since the band gap is as narrow as about 0.22 eV, it is sensitive to wavelength bands below the infrared band. Therefore, PtSi
The SBD is generally used to detect infrared rays. In addition, PtSiSBD reduces the dark current,
In order to improve the S / N ratio, it is cooled to near the liquid nitrogen temperature. Further, in order to prevent the influence of visible light and the like, infrared rays are generally incident from the back surface of the P-type silicon substrate 34 (downward in FIG. 2).

However, as shown in FIG. 2, it is possible to detect not only infrared rays but also visible rays and ultraviolet rays by making the light incident from the surface of the P-type silicon substrate 34 (upper side in FIG. 2). Becomes Since the image pickup device 12 of the present embodiment has a structure in which light is incident from the surface of the P-type silicon substrate 34, it is possible to detect electromagnetic waves in the infrared to ultraviolet bands.

FIG. 3 is a diagram showing an example of the configuration of the chopper 10. The visible light transmitting unit 50 transmits only visible light of the incident electromagnetic waves. The light shielding unit 51 shields at least electromagnetic waves in the infrared and visible light wavelength bands. Further, the infrared transmitting unit 52 is configured to transmit only electromagnetic waves in the infrared band.

The light-shielding portion 51 is provided for accurately reading out an infrared or visible light image signal.
That is, in this embodiment, the chopper 10 is rotationally driven by the motor 18, but it is difficult to accurately control the angular velocity of the rotation. Therefore, when the light shielding unit 51 is not provided, for example, visible light is incident during sampling of the infrared signal, and the image signal of the visible light is superimposed on the output signal. However,
When the light shielding portion 51 is provided between the visible light transmitting portion 50 and the infrared light transmitting portion 52, a period in which the electromagnetic wave is completely interrupted occurs in this region, so that some rotation error can be absorbed.

Next, the operation of the above embodiment will be described.

The electromagnetic wave is incident on the chopper 10 rotating at a constant angular velocity. The chopper 10 has a lens 11
Infrared rays or visible rays contained in the electromagnetic waves are transmitted or the electromagnetic waves are shielded according to the region located in front of the electromagnetic waves. The lens 11 focuses the electromagnetic waves (infrared rays or visible rays) that have passed through the chopper 10 onto a predetermined area on the image sensor 12. The image pickup device 12 converts the electromagnetic wave converged in a predetermined area into a corresponding image signal, and the image processing unit 13
Output in synchronization with the control signal from.

Now, in front of the lens 11, the infrared transmitting portion 5 is provided.
2 is located. In this case, of the incident electromagnetic waves, only infrared rays are transmitted through the infrared transmitting portion 52 of the chopper 10.
And is converged by the lens 11 into a predetermined area on the image sensor 12. Light receiving unit 30 that constitutes the image pickup device 12
Accumulates a charge corresponding to the intensity of the incident infrared radiation. Then, when the chopper 10 is rotated by the motor 18 and the light shielding portion 51 moves in front of the lens 11 and the incidence of electromagnetic waves is interrupted, the electric charge accumulated in the light receiving portion 30 is moved to the charge transfer path diffusion region 32. . The charges are sequentially moved in the charge transfer path diffusion region 32 in accordance with the control signal, finally converted into a corresponding voltage by the MOS-FET or the like, and output to the image processing unit 13.

Next, the lens 1 is rotated by the rotation of the motor 18.
If the visible light transmitting portion 50 moves to the front of 1, only visible light of the incident electromagnetic waves is converged on a predetermined region on the image sensor 12. The light receiving unit 30 accumulates electric charges corresponding to the intensity of incident visible light. Then, when the chopper 10 further rotates and the light shielding portion 51 moves to the front of the lens 11, the charges accumulated in the light receiving portion 30 are moved to the charge transfer path diffusion region 32 and converted into a predetermined signal, It is transferred to the image processing unit 13.

The image processor 13 performs AGC processing or the like on the image signal output from the image sensor 12. The extraction unit 13a separates and extracts an image signal corresponding to visible light and an image signal corresponding to infrared from the image signal that has been subjected to AGC processing and the like in synchronization with the timing signal supplied from the timing generation unit 19. . And these signals
For example, NTSC (National Television System Commi)
ttee) format signal and output.

The sensor 14 changes the electromagnetic wave shielded by the chopper 10 to the corresponding electrical signal ("L" when the light shielding portion 51 is located in front of the sensor 14 and "H" otherwise). Signal) and supplies it to the comparison unit 16 and the timing generation unit 19. The comparison unit 16
The phase of the reference signal supplied from the reference signal generator 15 and the phase of the signal supplied from the sensor 14 are compared, and a control signal corresponding to the phase difference is generated and output to the drive unit 17. The drive unit 17 is based on the control signal output from the comparison unit 16,
Electric power is supplied to the motor 18 and driven so as to have a constant angular velocity. As a result, the chopper 10 is rotated at a predetermined angular velocity according to the reference signal generated by the reference signal generator 15.

The timing generator 19 differentiates the signal supplied from the sensor 14 to detect the boundary portion between the light shielding portion 51 and the visible light transmitting portion 50 or the infrared light transmitting portion 52,
Based on this, a signal (timing signal) for specifying the region of the chopper 10 currently located in front of the lens 11 is generated and output to the image processing unit 13.

The extraction unit 13a of the image processing unit 13 extracts and outputs the visible light image signal and the infrared image signal in synchronization with the timing signal supplied from the timing generation unit 19.

According to the above embodiment, it is possible to generate an image signal from visible rays and infrared rays contained in an input electromagnetic wave, extract each image signal, and output these separately.

In the above embodiment, the reference signal generator 15 generates the reference signal having a predetermined cycle, but it may be changed to a predetermined value by manual operation or the like. Good. In that case, by setting the cycle of the reference signal to infinity (does not generate the reference signal) and stopping the chopper at a predetermined position, this embodiment can be used as an image pickup device dedicated to visible rays or infrared rays. . Further, if the reference signal is set so that the chopper 10 rotates 30 times per second, it becomes possible to easily generate an NTSC signal including 30 screens (frames) per second.

Further, in the above embodiment, the infrared image signal and the visible light image are separated by the extraction unit 13a,
I tried to output these as separate image signals,
This may be output without being separated, and may be appropriately separated by an external device.

FIG. 4 is a diagram showing a configuration example of an image pickup device to which the light receiving device of the present invention is applied. The light receiving units 70 to 72 are
Of the incident electromagnetic waves, only red (R), green (G), or blue (B) visible light rays are converted into electric charges corresponding to their intensities. The light receiving unit 73 is configured to convert only infrared rays (IR) into corresponding charges. Further, the charge transfer region 74 is adapted to take out the charges accumulated in the respective light receiving portions 70 to 73 to the outside.

In this figure, the first (top in the figure)
In this line, the light receiving portions 71 for green and the light receiving portions 72 for blue are alternately arranged. The second line is a light receiving portion 71 for green and a light receiving portion 70 for red.
And are alternately arranged. Only the light receiving portion 73 for infrared rays is arranged in the third line. In the fourth and subsequent lines, the same arrangement pattern as in the first to third lines is repeated.

The light receiving parts 70 to 7 for visible light
2 is composed of a pn junction diode and an on-chip color filter. That is, red, on the incident surface of the electromagnetic wave of the pn junction diode,
A green or blue on-chip color filter is arranged so that the light receiving units 70 to 72 have sensitivity to visible light of a predetermined color. Further, the light receiving portion 73 for infrared rays is formed of a pyroelectric body and detects the amount of change in the input infrared rays.

Next, the operation of the above embodiment will be described.

The incident electromagnetic waves are received by the light receiving portions 70 to 73.
Are converted into electric charges corresponding to the intensity of electromagnetic waves in a predetermined wavelength band. The charges accumulated in each of the light receiving units 70 to 73 are output to the outside via the charge transfer region 74 in synchronization with a control signal from a control unit (not shown).

Next, a case where the embodiment of FIG. 4 is applied to the embodiment shown in FIG. 1 will be described.

FIG. 5 shows the chopper 10 used in this case.
Shown in In this figure, the visible light transmitting portion 90 transmits only visible light of the incident electromagnetic waves, and the infrared transmitting portion 91 transmits only infrared light. Further, the light shielding portion 92 is configured to shield the incident electromagnetic wave.

In this embodiment, the reason for providing the light shielding portion 92 is to prevent the temperature of the element itself from being saturated because the light receiving portion 73 for infrared rays is a pyroelectric element.
This is because it is necessary to block the incident infrared rays at a constant cycle.

The rest of the configuration is the same as that of the above-mentioned case, and therefore its explanation is omitted.

Next, the operation of the above embodiment will be described.

The chopper 10 transmits infrared rays or visible rays contained in electromagnetic waves or shields electromagnetic waves, depending on a region located in front of the lens 11. Lens 1
1 focuses an electromagnetic wave (infrared ray or visible light ray) that has passed through the chopper 10 onto a predetermined area on the image sensor 12.
The image pickup device 12 converts the converged electromagnetic wave into a corresponding image signal and outputs it in synchronization with a control signal from the image processing unit 13.

Now, the infrared ray transmitting portion 9 is provided in front of the lens 11.
1 is located. In this case, of the incident electromagnetic waves, only infrared rays are transmitted through the infrared transmitting portion 91 of the chopper 10.
And is converged by the lens 11 into a predetermined area on the image sensor 12. Light receiving unit 70 that constitutes the image pickup device 12
Out of 73 to 73, the light receiving portion 73 having sensitivity to infrared rays is
The electric charge corresponding to the intensity of the incident infrared ray is accumulated.
This accumulated charge is transferred to the lens 11 by the visible light transmitting portion 90.
Before being transferred to the front of the charge transfer region 74. Since the light receiving units 70 to 72 have no sensitivity to infrared rays, no output is generated.

Subsequently, when the chopper 10 is rotated by the motor 18 and the visible light transmitting portion 90 moves in front of the lens 11, the electromagnetic waves focused by the lens 11 are sensitive to the visible light red, green, or blue, respectively. Are converted into corresponding electric charges by the light receiving units 70 to 72 having the. Then, while the chopper 10 is further rotated and the light shielding portion 92 moves to the front of the lens 11 and the incidence of the electromagnetic wave is stopped, the charges accumulated in the light receiving portions 70 to 72 pass through the charge transfer region 74. Is output. The light receiving unit 7
3 has sensitivity not only to infrared rays but also to visible rays, so that electric charges are accumulated even when visible rays are incident, but before being transferred to the image processing unit 13, separation (not shown) is performed. Separated by department and discarded. Therefore, only the image signal corresponding to visible light is output.

The image signal output from the image sensor 12 is
After being input to the image processing unit 13 and subjected to predetermined processing such as AGC processing, the extraction unit 13a separates the infrared image signal and the visible light image signal into NT signals, respectively.
It will be output after being converted into an SC signal.

The other operations are the same as those in the above-mentioned case, and the description thereof will be omitted.

According to the above embodiment, it is possible to capture an infrared or visible light image using the same imaging device. In this case, as compared with the above-described embodiment to which the image pickup device shown in FIG. 2 is applied, an element having a particularly high sensitivity to electromagnetic waves in a predetermined wavelength band can be used for the light receiving units 70 to 73, so that the image pickup apparatus can be used. The sensitivity of can be improved. However, since the number of light receiving units 70 to 73 for a specific wavelength band is reduced, the resolution is reduced accordingly.

In this embodiment, the infrared light receiving section 7 is used.
As No. 3, a pyroelectric light receiving element having sensitivity to visible light was used, so that it was necessary to separate visible light from infrared light by the chopper 10. However, when each light receiving element has sensitivity only to a specific wavelength band, the chopper 10 can be omitted.

In the above two embodiments, the image pickup apparatus for two wavelength bands of infrared rays and visible rays has been described as an example, but it goes without saying that an image pickup apparatus for wavelength bands other than these can be constructed. Also, it goes without saying that the number of wavelength bands to be combined can be increased or decreased as necessary.

Further, in the above embodiment, the chopper 1
In 0, the transmission part and the light shielding part of each wavelength band have the same area. However, as shown in FIG. 6, for example, the area is determined according to the sensitivity of the image pickup device 12 to each wavelength band. May be.

In this figure, the transmission parts 100 to 104 are shown.
Is an optical filter that transmits electromagnetic waves in a specific wavelength band,
They are arranged so that the wavelengths that are transmitted become shorter. The light shielding unit 105 is configured to shield electromagnetic waves.
Further, the areas of the transmission parts 100 to 104 are set so as to be inversely proportional to the sensitivity of the image pickup device 12 with respect to the electromagnetic waves transmitted by them.

With the above structure, the sensitivity of the image pickup device 12 to the electromagnetic waves in each wavelength band becomes the same,
It is not necessary to amplify (attenuate) the signal output from the image sensor 12 according to the wavelength band, and the circuit can be simplified.

Further, the light receiving section 30 which constitutes the image pickup device 12
For example, a pyroelectric element (outputs a signal corresponding to the temperature change of the element itself caused by incident infrared rays)
In the case of using, it is necessary to periodically block the incident infrared rays and reset the temperature of the element in order to prevent the temperature of the element itself from being saturated. It is desirable that this reset be performed immediately before or after the signal is detected from the element in order to reduce the generation of noise.

Therefore, according to the above configuration, the light shielding portion 10
Since an optical filter having a long wavelength band (infrared ray) is arranged in the portion adjacent to 5, it is possible to suppress the generation of noise and reset the temperature of the element appropriately.

[0056]

According to the image pickup device of the first aspect and the image pickup method of the sixth aspect, the electromagnetic waves in a predetermined wavelength band are selectively extracted from the input electromagnetic waves, and the extracted electromagnetic waves are handled. Since the image signal is converted into an image signal to be output and the converted image signal is output, it is possible to generate an image signal of electromagnetic waves in a plurality of different wavelength bands with one imaging device.

According to the light receiving device of the seventh aspect, in the light receiving device having a plurality of types of light receiving elements each having sensitivity to electromagnetic waves in a plurality of different wavelength bands, at least one of the plurality of types of light receiving elements is provided. Since the type has sensitivity to wavelength bands other than the visible region, it is possible to receive electromagnetic waves in a plurality of different wavelength bands with the same light receiving device and convert the electromagnetic waves into corresponding image signals. Further, if the sensitivity of the light receiving element is set to be high for a specific wavelength band, the sensitivity of the light receiving device can be improved.

An image pickup device according to claim 8 and claim 1
According to the imaging method described in 0, there are a plurality of types of light receiving elements each having sensitivity to electromagnetic waves in a plurality of different wavelength bands, and at least one of the plurality of types of light receiving elements is located outside the visible region. Since the light receiving device having sensitivity to the wavelength band is provided, the input electromagnetic wave is converted into the corresponding image signal by the light receiving device, and the converted image signal is output, one image pickup device is different. It is possible to generate an image signal from electromagnetic waves in a plurality of wavelength bands. Further, if the sensitivity of each light receiving element is set to be large for a specific wavelength band, the sensitivity of the image pickup device can be improved.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a configuration example of an image pickup apparatus of the present invention.

FIG. 2 is a diagram showing a cross section of the image sensor 12 of FIG.

FIG. 3 is a diagram showing a configuration example of a chopper 10 in FIG.

FIG. 4 is a diagram showing a configuration example of an image sensor to which the light receiving device of the present invention is applied.

FIG. 5 is a diagram showing another configuration example of the chopper 10 of FIG.

6 is a diagram showing still another configuration example of the chopper 10 of FIG.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 Chopper (extracting means) 11 Lens 12 Image sensor (converting means) 13 Image processing section 13a Extracting section (output means) 14 Sensor 15 Reference signal generating section 16 Comparison section 17 Driving section 18 Motor 19 Timing generating section 30 Light receiving section 70 to 73 Light receiving part

Claims (10)

[Claims] 1. An extracting unit for selectively extracting an electromagnetic wave in a predetermined wavelength band from an input electromagnetic wave; a converting unit for converting the electromagnetic wave extracted by the extracting unit into a corresponding image signal; An image pickup apparatus comprising: an output unit that outputs the image signal converted by the conversion unit. 2. The image pickup apparatus according to claim 1, wherein the extraction unit is composed of a plurality of optical filters having different transmission wavelength bands. 3. The image pickup apparatus according to claim 2, wherein the plurality of optical filters are arranged in a predetermined order, and electromagnetic waves in a predetermined wavelength band are extracted according to the order. 4. The image pickup apparatus according to claim 2, wherein the plurality of optical filters include at least one optical filter that shields the electromagnetic waves. 5. The optical filter for shielding electromagnetic waves is arranged immediately before or after the optical filter having the longest transmission wavelength in the plurality of optical filters. Imaging device. 6. An electromagnetic wave in a predetermined wavelength band is selectively extracted from the input electromagnetic wave, the extracted electromagnetic wave is converted into a corresponding image signal, and the converted image signal is output. A characteristic imaging method. 7. A light-receiving device having a plurality of types of light-receiving elements each having sensitivity to electromagnetic waves in a plurality of different wavelength bands, wherein at least one of the plurality of types of light-receiving elements has a wavelength band other than a visible region. A light-receiving device having sensitivity to. 8. A conversion means for converting an input electromagnetic wave into a corresponding image signal, and an output means for outputting the image signal converted by the conversion means, wherein the conversion means has a plurality of different wavelengths. A plurality of types of light receiving elements each having sensitivity to electromagnetic waves in a band, wherein at least one of the plurality of types of light receiving elements is sensitive to wavelength bands other than the visible region. Imaging device. 9. The image pickup apparatus according to claim 8, further comprising a shielding unit that shields the electromagnetic wave input to the conversion unit at a predetermined cycle. 10. A plurality of types of light receiving elements each having sensitivity to electromagnetic waves in a plurality of different wavelength bands,
At least one of the plurality of types of light-receiving elements is provided with a light-receiving device having sensitivity to a wavelength band other than the visible region, converts an input electromagnetic wave into a corresponding image signal by the light-receiving device, and is converted. And outputting the image signal.