JP2018143003A - Imaging device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To lengthen irradiation time of illumination light of a specific reference color and obtain a suitable color image.SOLUTION: The imaging device include: a control unit for controlling an illumination unit capable of irradiating illumination light of a plurality of colors including one specific color and another nonspecific color; and a processing unit for generating an image by photographing by an imaging unit during a unit imaging period. The control unit controls an illumination unit so that irradiation time of the nonspecific color and a part of irradiation time of illumination light of the specific color of 1 overlap.SELECTED DRAWING: Figure 2

Description

  The present invention relates to an imaging apparatus, an endoscope apparatus, and a control method for an imaging apparatus that independently capture a plurality of color images in a time division manner and obtain a color image from the captured plurality of color images.

  Conventionally, as this type of endoscope imaging device (endoscope device), an endoscope main body (endoscope) having an insertion portion to be inserted into a body cavity, and a hand side of the endoscope main body, A light source device that supplies illumination light, an imaging unit that is connected to the proximal side of the endoscope main body and has a function for imaging, a signal processing circuit that performs signal processing on the imaging unit, and an image that is output from the signal processing circuit A color TV monitor that displays a signal is known (see Patent Document 1). In this endoscope imaging apparatus, red, green, and blue illumination lights are sequentially emitted from a light source device, and color images of respective reference colors are sequentially taken into a frame memory in synchronization with the illumination by an imaging unit. Then, a color image is generated from the captured color image of each reference color and displayed on a color TV monitor.

JP-A-8-36138

By the way, in an endoscope imaging apparatus adopting such a color imaging method (so-called time sequential color imaging method), as shown in FIG. 3, the illumination unit is synchronized with the imaging unit, and in the blanking period of the imaging unit, Illumination light of each reference color is irradiated. That is, each color image is exposed in each blanking period, and each color image is scanned (read) in the most recent scanning period.
However, in such a configuration, the blanking period becomes the irradiation time of the illumination light of each reference color, so that the irradiation time becomes extremely short. Therefore, there has been a problem that all light sources of the reference color must use a high response speed (for example, an LED light source). That is, the usable light source is extremely limited. Further, since the irradiation time is extremely short, there is a problem that a very high light emission intensity (luminance) is required instantaneously for a specific reference color (hereinafter referred to as a specific reference color). For example, in a configuration using a HARP (High-gain Avalanche Rushing Amorphous Photoconductor) film in the imaging unit, the red light receiving sensitivity is remarkably lowered as shown in FIG. For this reason, irradiation with red illumination light requires a high amount of light emission to compensate for light reception sensitivity. However, since this is covered by an extremely short irradiation period, a very high light emission intensity is required instantaneously. End up. If illumination light is irradiated with a very high light emission intensity instantaneously with a light source, the light source may be damaged or may be deteriorated due to heat generation even if it does not reach the light source. In particular, when an LED light source is used as a light source having a high response speed, the LED light source is likely to be damaged due to its low heat dissipation performance compared to other light sources.
On the other hand, as shown in FIG. 5, in order to lengthen the irradiation time of the illumination light of the specific reference color (red in the example), the irradiation time of the illumination light of the specific reference color is set outside the blanking period (within the scanning period). It is also possible to extend up to. However, in such a configuration, since the exposure time varies depending on the scanning row, unnecessary gradation occurs in the color image. As a result, depending on the scanning row, the exposure (charge accumulation) associated with the current illumination is performed even after the readout, and may be carried over to the next scanning period. As a result, a color image in which the color components of the two reference colors are mixed is obtained. In addition, the removal process is extremely complicated because the mixing ratio varies depending on the scanning row in order to remove unnecessary color components. As a result, there is a problem that the color components of the respective reference colors cannot be obtained accurately and a suitable color image cannot be obtained.

  It is an object of the present invention to provide an imaging apparatus, an endoscope apparatus, and an imaging apparatus control method capable of extending the irradiation time of illumination light of a specific reference color and obtaining a suitable color image. Yes.

The imaging apparatus of the present invention includes a control unit that controls an illumination unit that can irradiate a subject with illumination light of n (n ≧ 3) colors including one specific reference color and a plurality of non-specific reference colors, and a unit imaging period. And a processing unit that generates a color image of the subject based on n color images corresponding to n colors captured by the imaging unit in a time-sharing manner, and the control unit is configured to control each non-specific reference color in the unit imaging period. The illumination unit is controlled to overlap with the illumination time of illumination light of a specific reference color having an illumination light irradiation time of 1.
Another imaging device of the present invention includes a control unit that controls an illumination unit that can irradiate a subject with illumination light of n (n ≧ 3) colors including one specific reference color and a plurality of non-specific reference colors, and a unit. A processing unit that generates a color image of a subject based on n color images corresponding to n colors captured by the imaging unit in a time-division manner during the imaging period, and the control unit illuminates a specific reference color during the unit imaging period The illumination unit is controlled so as to continuously irradiate light and irradiate illumination light of a plurality of non-specific reference colors in (n−1) blanking periods within the unit imaging period.

  In this case, the imaging unit preferably includes a photoelectric conversion film that receives reflected light from the subject, and an electron source unit that reads a light image accumulated on the photoelectric conversion film.

  In this case, it is preferable that the illumination light of the specific reference color has a lower light receiving sensitivity in the imaging unit than the plurality of non-specific reference colors.

An image pickup apparatus control method according to the present invention includes an illumination unit capable of irradiating a subject with illumination light of n (n ≧ 3) colors including one specific reference color and a plurality of non-specific reference colors, and imaging in a unit imaging period. And a processing unit that generates a color image of a subject based on n color images corresponding to n colors captured in a time-sharing manner. The illumination unit is controlled such that the illumination time of the reference color illumination light overlaps with the illumination time of the specific reference color illumination light of one.
According to another imaging apparatus control method of the present invention, an illumination unit capable of irradiating a subject with illumination light of n (n ≧ 3) colors composed of one specific reference color and a plurality of non-specific reference colors, and a unit imaging period And a processing unit that generates a color image of a subject based on n color images corresponding to n colors captured by the imaging unit in a time-sharing manner. The illumination unit is controlled to continuously irradiate color illumination light and irradiate illumination light of a plurality of non-specific reference colors in (n-1) blanking periods within a unit imaging period. To do.

According to these configurations, a color image of only the color component of the specific reference color is captured in one scanning period, and the color component of the specific reference color and each non-specific reference in (n−1) scanning periods. A color image in which color components of colors are mixed is captured. Although the irradiation of the specific reference color is extended outside the blanking period, the exposure time is continuously varied over the entire imaging period, so that there is no difference in the exposure time depending on the scanning row (see FIG. 6). . Further, since the color component of the specific reference color is common to all color images, the color component of the specific reference color can be easily removed from other color images by using the captured color image of the specific reference color. it can. As a result, a color image (color component) of each reference color can be obtained with high accuracy. Therefore, it is possible to obtain a suitable color image while extending the irradiation time of the illumination light of the specific reference color.
Therefore, usable light sources are not extremely limited, and damage to the light sources can be prevented. In addition, since the light emission intensity of the light source can be reduced, the life of the imaging unit can be extended, and the maximum supply current value of the drive circuit can be reduced, which simplifies the entire device and reduces power consumption. It contributes to electric power. Furthermore, since the peak luminance value for a subject (for example, a body organ) can be significantly reduced, light damage to the subject can be suppressed, and it can be used for applications where light damage is a concern.

  In the above-described imaging device, it is preferable that the illumination light of the specific reference color irradiates light in a wavelength region based on spectral sensitivity characteristics in the human retina.

  According to this configuration, it is possible to obtain a color image that matches the human retina in the specific reference color.

  In this case, the illumination unit preferably includes a first light source that emits illumination light of a specific reference color, and the first light source is preferably a white light source covered with a color filter.

  According to this structure, compared with the case where an LED light source is used, a 1st light source can be made cheap and heat dissipation can be improved. Moreover, the wavelength range of illumination light can be widened. As the white light source, a phosphor light source, an incandescent light source, or the like that excites the phosphor to emit light is assumed.

  An endoscope apparatus according to the present invention includes the above-described imaging apparatus, and a lens barrel unit that is provided in the imaging apparatus and incorporates a lens optical system.

  According to this configuration, a small and highly accurate endoscope apparatus can be provided by using an imaging apparatus that can obtain a highly accurate color image with a long-life and simple configuration.

It is the schematic diagram which showed the structure of the endoscope system which concerns on this embodiment. It is a time chart which showed image pick-up operation by an endoscope system. It is explanatory drawing which showed the conventional color imaging system. It is the figure which showed the spectral sensitivity characteristic at the time of using a HARP film | membrane. It is explanatory drawing which showed the color imaging system of the modification. It is explanatory drawing which showed the color imaging system of this invention.

  Hereinafter, an imaging apparatus, an endoscope apparatus, and an imaging apparatus control method according to an embodiment of the present invention will be described with reference to the accompanying drawings. In the present embodiment, an endoscope system (endoscope device) to which an imaging device is applied is exemplified. This endoscope system performs color imaging of a subject such as an organ as a lesion by a time sequential imaging method. In particular, the endoscope system realizes high-precision color imaging using a HARP film by illumination control and image processing (signal processing).

  As shown in FIG. 1, the endoscope system SY includes an endoscope main body 11 that images a subject A, and a signal processing unit (image processing unit) that processes the imaging result of the subject A by the endoscope main body 11. 12 and a monitor 13 for displaying the image-processed imaging result in color.

  The endoscope main body 11 includes a lens barrel portion 21 that is inserted into the body, an imaging unit 22 that is connected to the base end of the lens barrel portion 21 and images the subject A via the lens barrel portion 21, and a lens barrel portion. An illumination unit 23 that irradiates the subject A with illumination light via 21 and illuminates the illumination light, and an illumination control unit 24 that controls the illumination unit 23 are provided. Note that the imaging apparatus described in the claims is configured by each unit (the signal processing unit 12, the monitor 13, the imaging unit 22, the illumination unit 23, and the illumination control unit 24) excluding the lens barrel unit 21.

  The lens barrel portion 21 includes a cylindrical body 31 made of a rigid cylindrical member, and a lens optical system 32 built in the cylindrical body 31. The lens optical system 32 guides the illumination light from the illumination unit 23 to the subject A, guides the reflection from the subject A to the imaging unit 22, and transmits the optical image of the subject A to the imaging surface of the image sensor 51 of the imaging unit 22. Form an image.

  The illumination unit 23 includes a red light source (first light source) 41 that emits red (R: specific reference color) illumination light, a green light source 42 that emits green (G: non-specific reference color) illumination light, and blue A blue light source 43 that irradiates illumination light of (B: non-specific reference color) and an illumination optical system 44 that guides the illumination light of each of the light sources 41, 42, 43 to the lens barrel portion 21 are provided. The illumination optical system 44 may be configured to guide the illumination light of each of the light sources 41, 42, and 43 coaxially with two half mirrors, for example, The structure which guides illumination light on the same axis | shaft may be sufficient.

  The red light source 41 is configured by a white phosphor light source (fluorescent lamp) covered with a color filter. Further, as the red light source 41, a light source whose red illumination light has a wavelength range based on spectral sensitivity characteristics in the human retina is used. Specifically, the red light source 41 emits light in a wavelength region in which yellow and orange are mixed with red. On the other hand, the green light source 42 and the blue light source 43 are configured by LED light sources that are light emitting diodes. As will be described in detail later, during the imaging operation, the red light source 41 continuously emits red illumination light, and the green light source 42 and the blue light source 43 emit green and blue illumination light in pulses to illuminate the subject A. .

  The imaging unit 22 includes a single image sensor 51 that images the subject A via the lens barrel unit 21 and a sensor control unit 52 that controls the image sensor 51.

  The image sensor 51 uses a HEED-HARP imaging plate (monochrome imaging plate) composed of a HARP film (photoelectric conversion film) 56 and a cold cathode array (electron source section) 57 of HEED (High-Efficiency Electron Emission Device) type. . The HARP film 56 receives the reflected light from the subject A on the imaging surface and accumulates the light image as an electric charge (exposure). The cold cathode array 57 is composed of a plurality of cold cathode electron sources arranged in a matrix, reads a light image (image) accumulated on the HARP film 56, and outputs it to the signal processing unit 12 as an imaging signal. In the image sensor 51 using this type of HARP film 56, red illumination light has extremely low light receiving sensitivity compared to other reference colors (green and blue). Moreover, it can be said that red illumination light has a higher importance in imaging compared to other reference colors for the purpose of imaging the inside of the body.

  Then, the sensor control unit 52 controls the image sensor 51 to capture three color images corresponding to the number of reference colors (three colors) in cooperation with the illumination control unit 24 in the unit imaging period. The captured three color images are sequentially output to the signal processing unit 12.

  The signal processing unit 12 processes the imaging signal (color image) from the imaging unit 22 and outputs a component color video signal (color image). The signal processing unit 12 includes a memory 61, and the memory 61 includes a first memory area, a second memory area, and a third memory area that individually store three color images. That is, the signal processing unit 12 generates a color image based on the three color images stored in each memory area.

  Here, an imaging operation by the endoscope system SY will be described with reference to the time chart of FIG. Here, each scanning period in the unit imaging period in the imaging unit 22 is sequentially referred to as a first scanning period, a second scanning period, and a third scanning period, and each blanking period in the unit imaging period in the imaging unit 22 is referred to as “scanning period”. These are referred to as a first blanking period, a second blanking period, and a third blanking period, respectively. The first blanking period is a blanking period immediately before the first scanning period, the second blanking period is a blanking period immediately before the second scanning period, and the third blanking period is the first blanking period. This is the blanking period immediately before the three scanning periods.

  As shown in FIG. 2, the illumination control unit 24 controls the illumination unit 23 to continuously irradiate red illumination light in the unit imaging period (continuous light emission), while in the second blanking period, Illumination light is irradiated (pulse light emission), and blue illumination light is irradiated (pulse light emission) in the third blanking period. That is, red and green illumination lights are simultaneously irradiated in the second blanking period, and red and blue illumination lights are simultaneously irradiated in the third blanking period.

  On the other hand, in the readout in the first scanning period, the imaging unit 22 captures a red color image composed only of the red color component. Further, in the reading in the second scanning period, a mixed color image in which the red color component and the green color component are mixed is captured. Further, in the readout in the third scanning period, a mixed color image in which the red color component and the blue color component are mixed is captured. The captured color image is output to the signal processing unit 12 as an imaging signal by the imaging unit 22 every time the imaging is performed.

  Then, the signal processing unit 12 stores the three color images output from the imaging unit 22 in each memory area of the memory 61, and based on the three color images for each frame, the color image is obtained. Generate. Specifically, first, three color images are read from each memory area. Next, a red color image is used to remove a red color component from the mixed color image by matrix calculation, and a green color image composed only of the green color component and a blue color composed only of the blue color component The color image is extracted. When the color image of each reference color is obtained, the color image of each reference color is synthesized to generate a color image. For example, the color image output in the sections t8 to t11 is generated based on the three color images captured in the first scanning period t2 to t4, the second scanning period t5 to t7, and the third scanning period t8 to t10. Is done. The color image generated here is output as a component color video signal to the monitor 13 and displayed sequentially.

  According to the configuration as described above, although the red irradiation is extended beyond the blanking period, the exposure time does not vary depending on the scanning row because the irradiation is continuously performed over the entire imaging period. (See FIG. 6). Also, since the red color component is common to all color images, the red color component can be easily removed from other color images by using the captured red color image. As a result, a color image (color component) of each reference color can be obtained with high accuracy. Therefore, it is possible to obtain a suitable color image while extending the irradiation time of the red illumination light. Therefore, the usable red light source 41 is not extremely limited, and damage to the red light source 41 can be prevented. Further, since the emission intensity of the red light source 41 can be reduced, the life of the imaging unit 22 can be extended, and the maximum supply current value of the drive circuit can be reduced, so that the entire system can be simplified. And contributes to lower power consumption. Furthermore, since the peak luminance value for the subject A can be significantly reduced, the optical damage of the subject A can be suppressed, and it can be used for applications where there is a concern about optical damage.

  In addition, it emits light in the wavelength range based on the spectral sensitivity characteristics of the human retina as red illumination light. Specifically, it emits light in the wavelength range that mixes yellow and orange as auxiliary colors. A color image matched to the retina can be obtained. Particularly, in this type of endoscope system SY that images the inside of the body, the importance of red is high. Therefore, by matching the wavelength range of the red illumination light with the spectral sensitivity characteristics of the human retina, a highly accurate color image can be obtained as the endoscope system SY.

  Furthermore, by using a HARP-HEED imaging plate as the imaging unit 22, it is possible to provide an endoscope system SY that can obtain a highly accurate image.

  Furthermore, by using a white light source covered with a color filter as the red light source 41, the red light source 41 can be made cheaper and heat dissipation can be improved compared to the case where an LED light source is used. be able to. Moreover, the wavelength range of illumination light can be widened.

  In the present embodiment, the HEED type cold cathode array 57 is used in the image sensor 51, but a SPINDT type cold cathode array 57 may be used.

  In this embodiment, the cold cathode array 57 reads the optical image on the HARP film 56. However, an electron gun and a deflection mechanism (a so-called deflection electron gun) are used as the electron source unit, and an electron gun is used. Alternatively, the optical image on the HARP film 56 may be read by a deflection mechanism.

  Furthermore, in the present embodiment, a HARP-HEED imaging plate is used as the image sensor 51, but a CCD image sensor or a CMOS image sensor may be used as the image sensor 51. In these cases, since the blue illumination light has lower light receiving sensitivity than other reference colors, blue is used as the specific reference color. That is, in the imaging operation, the blue illumination light is continuously emitted in the unit imaging period, and the red and green illumination lights are respectively emitted in the two blanking periods in the unit imaging period.

  Furthermore, in this embodiment, the reference color having low light receiving sensitivity is set as the specific reference color. However, for the purpose of the imaging apparatus, the reference color having high importance or the reference color to be used with the light source having low response is specified. It may be a reference color.

  In the present embodiment, the illumination and imaging of the subject A are performed using three reference colors (RGB) of the three primary colors of light. However, the illumination of the subject A using four or more reference colors, A configuration for performing imaging may also be used.

  Furthermore, in this embodiment, the white phosphor light source covered with the color filter is used as the light source of the specific reference color (red light source 41), but an incandescent light source covered with the color filter may be used. As a result, an LED light source may be used as the light source.

  In the present embodiment, the illumination light of the specific reference color (red) is continuously emitted. However, if the illumination light is continuously irradiated in the unit imaging period, the specific reference color (red) is used. The illumination light may be configured to emit pulsed light.

  In the present embodiment, the illumination light is incident on the lens barrel 21 from the side to illuminate the subject A. However, the light sources 41, 42, and 43 are arranged around the image sensor 51, and coaxial illumination is performed. The subject A may be illuminated.

  In the present embodiment, the present invention is applied to the endoscope system SY of the rigid mirror using the rigid lens barrel portion 21. However, the endoscope system SY of the flexible mirror using the flexible lens barrel portion 21 is used. The present invention may be applied to.

  In the present embodiment, the present invention is applied to the endoscope system SY. However, the present invention may be applied to an imaging apparatus other than the endoscope. For example, the present invention may be applied to nighttime and deep sea imaging devices and microscope imaging devices.

  12: Signal processing unit, 21: Lens barrel unit, 22: Imaging unit, 23: Illumination unit, 24: Illumination control unit, 32: Lens optical system, 56: HARP film, 57: Cold cathode array, A: Subject, SY : Endoscope system

Claims (1)

A control unit that controls an illumination unit that can emit illumination light of a plurality of colors including one specific color and another non-specific color;
A processing unit that generates an image by imaging of the imaging unit in a unit imaging period,
The control unit is an imaging device that controls the illumination unit such that an irradiation time of the illumination light of the non-specific color overlaps with a part of the irradiation time of the illumination light of the specific color in the unit imaging period.

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