JP6175538B2 - Endoscope system - Google Patents

Description

  The present invention relates to an endoscope system that performs narrow-band light observation using a complementary color imaging device.

  In recent medical treatments, diagnosis and the like using an endoscope system including a light source device, an electronic endoscope, and a processor device are widely performed. The light source device generates illumination light and irradiates the specimen. The electronic endoscope is irradiated with illumination light, and the inside of the specimen is imaged by an image sensor to generate an image signal. The processor device performs image processing on the imaging signal generated by the electronic endoscope and generates an observation image for display on the monitor.

  As an observation method used in an endoscope system, in addition to normal light observation using ordinary light (white light) having a wide wavelength range as illumination light, special light (narrow band light) having a narrow wavelength range is used as illumination light. Narrow-band light observation is known. The narrow-band light observation can be displayed with improved visibility of the state of blood vessel running on the surface of the mucosa, which is easily buried with optical information obtained in the case of white light, for example. For this reason, in narrow-band light observation, attention can be paid to the superficial blood vessel even during blood vessel running, and the degree of progression of the lesioned part, the depth of the depth direction, and the like can be determined according to the form of the superficial blood vessel.

  In this narrow-band light observation, two narrow-band lights (blue narrow-band light having a center wavelength near 415 nm and green narrow-band light having a center wavelength near 540 nm) that are easily absorbed by hemoglobin in blood are used. Yes. As an imaging method in narrowband light observation, in addition to a surface sequential method of alternately illuminating blue narrowband light and green narrowband light and using a monochrome imaging device for each narrowband light irradiation, A simultaneous method is known in which blue narrow-band light and green narrow-band light are simultaneously irradiated and imaged with a simultaneous imaging device having a color filter (see Patent Documents 1 and 2). The simultaneous method has a lower resolution than the frame sequential method, but has the advantage that the image is less likely to be blurred and the configuration of the endoscope system is simplified.

  The simultaneous image sensor includes a primary color image sensor having a primary color filter and a complementary color image sensor having a complementary color filter. The primary color image sensor is inferior in sensitivity to the complementary color image sensor, but has excellent color reproducibility, and is therefore used in an endoscope system that places importance on color. On the other hand, the complementary color image pickup device is used in an endoscope system in which sensitivity is important because it has a high sensitivity although color reproducibility is inferior to a primary color image pickup device. Therefore, since the primary color image sensor and the complementary color image sensor are each pros and cons, future endoscope systems will be used in a primary color endoscope incorporating a primary color image sensor and a complementary color image sensor incorporating a complementary color image sensor. There is a need for an endoscope system that can be connected to both endoscopes.

  Patent Documents 1 and 2 show complementary color checkered color difference line sequential systems having four types of pixels of magenta (Mg), green (G), cyan (Cy), and yellow (Ye) as complementary color imaging devices. Has been. In this complementary color checkered color difference line sequential method, pixel signals of two adjacent rows are mixed (added) and read by field reading. Specifically, it is read out by four combinations of Mg pixel and Cy pixel, G pixel and Ye pixel, Mg pixel and Ye pixel, G pixel and Cy pixel. This complementary checkered color difference line sequential method has an advantage that Y / C signals and RGB signals can be easily generated simply by performing addition / subtraction based on the signals of four types of mixed pixels.

Japanese Patent No. 4009626 Japanese Patent No. 4847250

  When performing narrow-band light observation with the endoscope system described above, in the primary color imaging device, blue narrow-band light and green narrow-band light are individually captured by blue (B) pixels and green (G) pixels, respectively. Therefore, an image having good color separation and excellent visibility of the superficial blood vessel (contrast between the superficial blood vessel and the mucous membrane) can be obtained. On the other hand, in the complementary color imaging device, blue narrow-band light and green narrow-band light are sensed simultaneously by each mixed pixel (that is, color mixing occurs), so color separation is poor and surface blood vessels are scattered light. There is a problem that the visibility of the superficial blood vessels decreases due to blurring due to the influence of the above.

  In relation to this problem, in Patent Documents 1 and 2, it is possible to reduce color mixing by changing a coefficient in matrix calculation for converting a Y / C signal into an RGB signal according to the characteristics of the color filter. Have been described. However, this matrix operation is performed in a signal processing circuit that performs an operation based on each mixed pixel signal. When each mixed pixel signal is input to the signal processing circuit, the blue narrow band light component and the green narrow signal are already generated. Since the signal is mixed with the band light component, the matrix calculation does not fundamentally improve the color separation property and the visibility of the surface blood vessels.

  An object of the present invention is to provide an endoscope system capable of improving color separation and surface blood vessel visibility in narrowband light observation using a complementary color imaging device.

In order to achieve the above object, an endoscope system according to the present invention includes a complementary color image pickup device in which an image pickup device having a pixel to which any one of cyan, magenta, yellow, and green color filter segments is attached. The arranged complementary color endoscope and the complementary color endoscope can be detachably connected, and the first narrowband light having the center wavelength in the blue or violet wavelength range and the center in the green wavelength range. When a complementary color endoscope is connected to a light source device that generates a second narrowband light having a wavelength and a light source device, the light quantity of the first narrowband light with respect to the light quantity of the second narrowband light A control unit that sets a first light amount ratio, which is a light amount ratio, to a value larger than 1.

In addition to the complementary color type endoscope, a primary color type endoscope in which a primary color image pickup device is arranged can be detachably connected to the light source device, and the control unit determines the first light quantity ratio based on the primary color type endoscope. It is preferable to set a value larger than a second light amount ratio that is a light amount ratio of the light amount of the first narrowband light to the light amount of the second narrowband light set when the mirror is connected.

It is preferable that the irradiation unit simultaneously irradiates the first narrowband light and the second narrowband light.

The complementary color imaging device reads out the first mixed pixel and the second mixed pixel that are sensitive to both the first narrowband light and the second narrowband light, and is an image based on the first narrowband light. A signal processing unit that uses the signal value of the first mixed pixel for conversion and uses the signal value of the second mixed pixel for imaging based on the second narrowband light, and the control unit sets the first light quantity ratio to the first It is preferable to set the signal value of the second mixed pixel to be larger than the signal value of the mixed pixel.

It is preferable that the image display apparatus further includes an R channel, a G channel, and a B channel, and a signal corresponding to the first narrowband light is allocated to the G channel and the B channel.

  The light source device has a plurality of LED light sources, and the control unit preferably sets the first light quantity ratio by controlling the light emission intensity and / or the light emission time of the plurality of LED light sources.

  According to the present invention, color separability and surface blood vessel visibility are improved.

It is an external view of an endoscope system. It is a block diagram which shows the internal structure of an endoscope system. It is a graph which shows the emission spectrum of purple narrow-band light. It is a graph which shows the emission spectrum of normal light. It is a figure explaining the structure of a multiplexing part. It is a graph which shows the emission spectrum of green narrow-band light. It is a schematic diagram which shows a complementary color system color separation filter. It is a schematic diagram which shows a primary color system color separation filter. It is a figure which shows the drive timing of the light source and complementary color type image pick-up element at the time of narrow band light observation mode. It is a figure which shows the output signal from a complementary color type image pick-up element. It is a graph which illustrates the spectral sensitivity characteristic of a complementary color system image sensor. It is a graph which illustrates the spectral sensitivity characteristic of the 1st-the 4th mixed pixel. It is a graph which illustrates the spectral attenuation characteristic of a light guide. It is a figure which shows the drive timing of the light source and complementary color type image sensor in a calibration mode. It is a block diagram which shows the structure of the 1st process part for complementary colors. It is a graph which illustrates each ratio of the main components in the 1st and 2nd mixed pixel signal, and the sum of both. It is a flowchart explaining the effect | action of an endoscope system. It is a graph which shows the emission spectrum of blue narrow-band light. It is a schematic diagram which shows the modification of a light source device. It is a schematic diagram which shows the structure of a rotary filter. It is a graph which illustrates the transmission characteristic of the filter part for the 1st narrow band. It is a graph which illustrates the transmission characteristic of the filter part for the 2nd narrow band. It is a schematic diagram which shows the modification of a complementary color type | system | group color separation filter.

  In FIG. 1, an endoscope system 10 includes a light source device 11, a processor device 12, and an electronic endoscope (hereinafter simply referred to as an endoscope) 13 that can be detachably connected to the light source device 11 and the processor device 12. It is configured. The light source device 11 generates illumination light and supplies it to the endoscope 13. The endoscope 13 is inserted into the body cavity or the like of the specimen to image the inside of the body cavity. The processor device 12 controls the imaging of the endoscope 13 and performs signal processing on the imaging signal acquired by the endoscope 13.

  An image display device 14 and an input device 15 are connected to the processor device 12. The image display device 14 is a liquid crystal monitor or the like, and displays a sample image representing an image in the sample generated by the processor device 12. The input device 15 includes a keyboard and a mouse, and inputs various information to the processor device 12.

  The endoscope 13 includes a complementary color endoscope 13a including a complementary color imaging device 28 (see FIG. 2) and a primary color endoscope 13b including a primary color imaging device 29 (see FIG. 2). The light source device 11 and the processor device 12 can be connected. The complementary color endoscope 13a and the primary color endoscope 13b have the same configuration except for the image sensor, and the insertion portion 16, the operation portion 17, the universal cable 18, the light guide connector 19a, and the signal connector 19b. It is comprised by.

  The insertion portion 16 is elongated and inserted into the body cavity of the specimen. The operation unit 17 is connected to the rear end of the insertion unit 16 and is provided with a scope switch, a bending operation dial, and the like. The scope switch includes a mode switch 17a for switching the observation mode.

  The universal cable 18 extends from the operation unit 17. The light guide connector 19 a and the signal connector 19 b are provided at the end of the universal cable 18. The light guide connector 19a is detachably connected to the light source device 11. The signal connector 19b is detachably connected to the processor device 12.

  The endoscope system 10 has a normal light observation mode and a narrow-band light observation mode as observation modes. In the normal light observation mode, imaging is performed by irradiating the specimen with normal light (white light) whose wavelength range extends from the blue band to the red band, and a normal light image is generated. In the narrowband light observation mode, imaging is performed by irradiating the specimen with narrowband light (purple narrowband light Vn and green narrowband light Gn, which will be described later) having a narrow wavelength range, and a narrowband light image is generated. The normal light observation mode and the narrow-band light observation mode are possible when either the complementary color endoscope 13a or the primary color endoscope 13b is used.

  The normal light observation mode and the narrowband light observation mode can be switched by the mode switch 17a described above, but are provided on a foot switch (not shown) that can be connected to the processor device 12 or on the front panel of the processor device 12. It may be possible to switch between the buttons, the input device 15 and the like.

  In FIG. 2, the light source device 11 includes a plurality of LED (Light Emitting Diode) light sources 20, a light source control unit 21, and a multiplexing unit 24. The LED light source 20 includes a purple LED (V-LED) 20a and a white LED (WL-LED) 20b. As shown in FIG. 3, the V-LED 20 a generates purple narrowband light Vn having a wavelength range of 380 to 440 nm. As shown in FIG. 4, the WL-LED 20 b generates white light WL in a wide wavelength range. The light source control unit 21 performs light emission control of the V-LED 20a and the WL-LED 20b.

  As illustrated in FIG. 5, the multiplexing unit 24 includes a dichroic mirror 22 and first to third lenses 23 a to 23 c. The first and second lenses 23a and 23b are disposed corresponding to the LEDs 20a and 20b, respectively, and condense the light emitted from the LEDs 20a and 20b into parallel light. The V-LED 20a and the WL-LED 20b are disposed so that their optical axes are orthogonal to each other, and a dichroic mirror 22 is disposed at the intersection of the optical axes.

  The dichroic mirror 22 has an optical characteristic of transmitting light in a wavelength region of, for example, 530 nm or more and less than 550 nm and reflecting light in a wavelength region of less than 530 nm or 550 nm or more. Therefore, the purple narrow band light Vn is reflected by the dichroic mirror 22 and collected by the third lens 23c. One part of the white light WL passes through the dichroic mirror 22, and as shown in FIG. 6, is converted into green narrowband light Gn in the wavelength range of 530 to 550 nm and is condensed by the third lens 23c.

  In the narrow-band light observation mode, the V-LED 20a and the WL-LED 20b are turned on at the same time, and the purple narrow-band light Vn and the green narrow-band light Gn are combined by the dichroic mirror 22 and condensed by the third lens 23c. Incident on the guide 27.

  In the normal light observation mode, the dichroic mirror 22 is moved outside the optical axis of the WL-LED 20b by a moving mechanism (not shown). Accordingly, in the normal light observation mode, the white light WL is directly incident on the third lens 23 c and supplied to the light guide 27. In the normal light observation mode, the dichroic mirror 22 is retracted, and the purple narrow-band light Vn emitted from the V-LED 20a does not enter the third lens 23c even if it is reflected by the dichroic mirror 22, so the V-LED 20a is turned on / off. Any of non-lighting may be sufficient.

  The purple narrow band light Vn has a center wavelength of about 405 nm, and has a high hemoglobin absorption coefficient in the visible light region. The green narrow band light Gn has a center wavelength of about 540 nm, and has a high hemoglobin absorption coefficient in the green light wavelength region. Further, the green narrow band light Gn has a characteristic that the reflectance at the mucous membrane is higher than that of the purple narrow band light Vn.

  An illumination window and an observation window are provided adjacent to each other at the distal end of the insertion portion 16 of the endoscope 13, an illumination lens 25 is attached to the illumination window, and an objective lens 26 is attached to the observation window. Yes. A light guide 27 is inserted into the endoscope 13, and one end of the light guide 27 faces the illumination lens 25. The other end of the light guide 27 is disposed on the light guide connector 19 a and is inserted into the light source device 11.

  The illumination lens 25 is incident on the light guide 27 from the light source device 11, collects the light emitted from the light guide 27, and irradiates the sample. The objective lens 26 collects the reflected light from the biological tissue of the specimen and forms an optical image. At the imaging position of the objective lens 26, an image pickup device that picks up an optical image and generates an image pickup signal (in the case of the complementary color type endoscope 13a, the complementary color type image pickup device 28, in the case of the primary color type endoscope 13b). A primary color image sensor 29) is arranged. The complementary color image sensor 28 and the primary color image sensor 29 are CCD (Charge Coupled Device) image sensors.

  A complementary color system color separation filter 28 a that optically separates an optical image for each pixel is provided on the imaging surface of the complementary color image sensor 28. As shown in FIG. 7, the complementary color separation filter 28a has four color filter segments of magenta (Mg), green (G), cyan (Cy), and yellow (Ye). Are attached in pixel units. Therefore, the complementary color image sensor 28 has four kinds of pixels of Mg, G, Cy, and Ye, and odd-numbered columns are arranged in the order of Mg pixels, Cy pixels, Mg pixels, Ye pixels,. , G pixel, Ye pixel, G pixel, Cy pixel,..., Mg pixels and G pixels are alternately arranged in odd rows, and Cy pixels and Ye pixels are alternately arranged in even rows. Has been placed. This color filter array is called a complementary color checkered color difference line sequential method.

  A primary color separation filter 29 a is provided on the imaging surface of the primary color imaging device 29. As shown in FIG. 8, the primary color separation filter 29a has three types of color filter segments, red (R), green (G), and blue (B). Each color filter segment is attached in units of pixels. It has been. Therefore, the primary color image pickup device 29 has three types of pixels of R, G, and B, G pixels and B pixels are alternately arranged in odd columns, and R pixels and G pixels are alternately arranged in even columns. G pixels and R pixels are alternately arranged in odd rows, and B pixels and G pixels are alternately arranged in even rows. This color filter array is called a primary color Bayer system.

  The endoscope 13 is provided with an information storage unit 30 composed of a nonvolatile memory such as a flash memory. The information storage unit 30 stores unique information (color filter array of the image sensor and the number of pixels) and the like of the endoscope 13.

  The processor device 12 includes a control unit 31, an imaging control unit 32, a correlated double sampling (CDS) circuit 33, an A / D conversion circuit 34, a brightness detection circuit 35, a dimming circuit 36, and signal processing. Unit 37 and channel allocation unit 38.

  The control unit 31 controls each unit in the processor device 12 and the light source device 11. When the endoscope 13 is connected to the light source device 11 and the processor device 12, the control unit 31 reads the unique information of the endoscope 13 from the information storage unit 30, and the connected endoscope 13 It is determined whether the endoscope 13a or the primary color endoscope 13b. The imaging control unit 32 drives the imaging device (the complementary color imaging device 28 or the primary color imaging device 29) according to the type of the endoscope 13 determined by the control unit 31.

  In the case of the complementary color imaging device 28, the imaging control unit 32 drives the complementary color imaging device 28 by the field readout method in accordance with the light emission timing of the light source device 11. Specifically, in the field readout method, at the time of each readout of the odd field and the even field, two pixels adjacent in the column direction are mixed (added) and read out (see FIG. 7). . This mixing of pixel signals is performed in a horizontal transfer path (not shown) of the CCD image sensor. FIG. 9 shows the drive timing in the narrow-band light observation mode. The drive timing in the normal light observation mode is the same as in the narrow-band light observation mode except that the illumination light is white light WL.

  With this field readout method, the complementary color image sensor 28 has mixed pixel signals (hereinafter referred to as first mixed pixel signals) of Mg pixels and Cy pixels as shown in FIG. 10 in each of the odd field and the even field. ) M1, a mixed pixel signal of G pixel and Ye pixel (hereinafter referred to as a second mixed pixel signal) M2, a mixed pixel signal of Mg pixel and Ye pixel (hereinafter referred to as a third mixed pixel signal) M3, A mixed pixel signal (hereinafter referred to as a fourth mixed pixel signal) M4 of the G pixel and the Cy pixel is output.

  Since each pixel of the complementary color image sensor 28 has, for example, the spectral sensitivity characteristic shown in FIG. 11 according to the color filter segment, each mixed pixel has the spectral sensitivity characteristic shown in FIG. 12, for example. According to this spectral sensitivity characteristic, among the first to fourth mixed pixels, the first mixed pixel (Mg + Cy) is the most sensitive to the purple narrowband light Vn (center wavelength 405 nm), and the second mixed pixel (G + Ye). ) Is the most sensitive to the green narrowband light Gn (center wavelength 540 nm). However, the first mixed pixel (Mg + Cy) has high sensitivity to the green narrowband light Gn, and the second mixed pixel (G + Ye) has some sensitivity to the purple narrowband light Vn. doing.

  In the narrowband light observation mode, the purple narrowband light Vn is imaged based on the first mixed pixel signal M1, and the green narrowband light Gn is imaged based on the second mixed pixel signal M2. On the other hand, in the normal light observation mode, imaging is performed using all of the first to fourth mixed pixel signals M1 to M4.

  In the case of the primary color imaging device 29, the imaging control unit 32 drives the primary color imaging device 29 by a known progressive readout method in accordance with the light emission timing of the light source device 11. In this progressive readout method, pixel signals are individually read out one frame at a time without mixing pixel signals.

  Signals output from the complementary color image sensor 28 and the primary color image sensor 29 are input to the CDS circuit 33. The CDS circuit 33 performs correlated double sampling on the input signal to remove noise components generated by the CCD image sensor. The signal from which the noise component has been removed by the CDS circuit 33 is input to the A / D conversion circuit 34 and also to the brightness detection circuit 35. The A / D conversion circuit 34 converts the signal input from the CDS circuit 33 into a digital signal and inputs the digital signal to the signal processing unit 37.

  The brightness detection circuit 35 detects brightness (average luminance of the signal) based on the signal input from the CDS circuit 33. The light control circuit 36 generates a light control signal that is a difference between the brightness signal detected by the brightness detection circuit 35 and the reference brightness (target value of light control). This dimming signal is input to the light source control unit 21. The light source control unit 21 adjusts the light emission amount of the LED light source 20 so that the reference brightness is obtained.

  The control unit 31 receives a mode switching signal that is generated when the mode switch 17a of the endoscope 13 is operated, and based on the received mode switching signal, the light emission method of the light source device 11 and the signal processing unit 37. Switch the signal processing method.

  In the narrow-band light observation mode, the control unit 31 controls the light source control unit 21 according to the type of the endoscope 13 based on the unique information read from the information storage unit 30, and the V-LED 20a and the WL-LED 20b. Change the emission intensity. Specifically, in the case of the primary color endoscope 13b, the control unit 31 has approximately the light amounts of the purple narrow band light Vn and the green narrow band light Gn emitted from the primary color endoscope 13b into the specimen. The light source control unit 21 is controlled to be equal.

  On the other hand, in the case of the complementary color endoscope 13a, the control unit 31 has a light amount ratio Z of the light amount of the purple narrow band light Vn to the light amount of the green narrow band light Gn emitted from the complementary color endoscope 13a into the specimen. However, the light source controller 21 is controlled so as to satisfy the expression (1). This light quantity ratio Z is at least larger than in the case of the primary color endoscope 13b (Z = 1).

Here, S ₁ is the first mixed pixel signals M1v obtained when only the independent irradiating violet narrowband light Vn. S ₂ is the second mixed pixel signals M2g obtained when only the independent irradiation green narrowband light Gn. Z _i is a ratio (X _i / Y _i ) of the light amount X _i of the purple narrow band light Vn to the light amount Y _i of the green narrow band light Gn at the time of independent irradiation.

  As will be described in detail later, the expression (1) is used for imaging based on the green narrowband light Gn while increasing the light quantity of the purple narrowband light Vn simultaneously irradiated to the specimen from the light quantity of the green narrowband light Gn. This is the condition of the light quantity ratio Z that makes the signal value of the two mixed pixels higher than the signal value used for imaging the first mixed pixel based on the purple narrowband light Vn. As a result, the color separation is improved as described later, and the visibility of the superficial blood vessels (the contrast between the superficial blood vessels and the mucous membrane) is improved.

In particular, the light quantity ratio Z is preferably set to the optimum light quantity ratio Z ₀ represented by the formula (2). The optimum quantity ratio Z ₀ is the median of the range defined by formula (1).

S ₁ is violet narrowband light first mixed pixel signal value average value of M1v plurality of at independent irradiation of Vn (for example, the average value of all of the first mixed pixel signal values M1v between odd and even fields) It is preferable to do. Likewise, S _2, the green narrow-band light Gn second mixed pixel signal value average of M2g plurality of at independent irradiation (e.g., the average of all second mixed pixel signal values M2g between odd and even fields Value).

This optimal light quantity ratio Z ₀ is obtained by changing the purple narrow band light Vn and the green narrow band light Gn from the light source device 11 to a predetermined light quantity ratio Z _i (for example, Z _i = 1), each of which is irradiated independently (time-division irradiation), the first and second mixed pixel signals M1v and M2g are obtained from the complementary color image sensor 28, and the calculation is performed based on Expression (2). It is done. The optimum quantity ratio Z ₀ obtained at the manufacturing stage as is stored in the information storage unit 30 of the complementary color type endoscope 13a.

When the complementary color endoscope 13a is connected to the light source device 11 and the processor device 12 and the narrowband light observation mode is selected by the mode changeover switch 17a, the control unit 31 stores information on the complementary color endoscope 13a. and reads out the optimum light quantity ratio Z ₀ stored in the storage unit 30, controls the light source control unit 21, violet narrowband light Vn and green narrow-band light quantity ratio Z satisfying the equation (1) from the complementary color endoscope 13a The light intensity is set by modulating the intensity of the V-LED 20a and the WL-LED 20b so that the light Gn is emitted.

  The light guide 27 described above has a spectral attenuation characteristic as shown in FIG. 13, and the attenuation rate of propagating light is high in a short wavelength region of about 440 nm or less. For this reason, the purple narrowband light Vn is attenuated more than the green narrowband light Gn in the light guide 27 of the complementary color endoscope 13a after being emitted from the light source device 11. Therefore, the light emission intensity ratio of the V-LED 20a and the WL-LED 20b does not match the light quantity ratio Z of the purple narrowband light Vn and the green narrowband light Gn emitted from the complementary color endoscope 13a. Considering the spectral attenuation factor of the light guide 27, the emission intensity of the V-LED 20a and the WL-LED 20b is set. For example, the relationship between the emission intensity ratio of the V-LED 20a and the WL-LED 20b and the light quantity ratio Z of the purple narrowband light Vn and the green narrowband light Gn emitted from the complementary color endoscope 13a is measured in advance and tabulated. The V-LED 20a and the WL-LED 20b may be controlled based on this table.

Further, the endoscope system 10 includes a calibration mode that allows to re-calculate the optimal quantity ratio Z ₀ after completion as a product. This calibration mode can be selected by operating the input device 15 or the like. In this calibration mode, the control unit 31 turns on the V-LED 20a and the WL-LED 20b of the light source device 11 individually to generate purple narrowband light Vn and green narrowband light Gn as shown in FIG. Divided irradiation is performed, and the complementary color image sensor 28 is driven in accordance with each irradiation timing.

The light amount ratio Z _i between the purple narrow band light Vn and the green narrow band light Gn used in this calibration mode may be the light amount ratio Z set in the light source control unit 21. The control unit 31 includes an optimum light amount ratio calculation unit 39. Optimum light intensity ratio calculation unit 39 performs calculation according to equation (2), to calculate the optimum light quantity ratio Z _0.

  The signal processing unit 37 includes a selector 40, a first complementary color processing unit 41, a second complementary color processing unit 42, a first primary color processing unit 43, a second primary color processing unit 44, and a calibration process. Part 45. The selector 40 selects any one of the processing units 41 to 45 according to the type of the endoscope 13 and the observation mode determined by the control unit 31.

The calibration processing unit 45 is selected in the calibration mode described above. A signal output from the complementary color image sensor 28 in the calibration mode is input to the signal processing unit 37 via the CDS circuit 33 and the A / D conversion circuit 34, and is sent to the calibration processing unit 45 by the selector 40. The calibration processing unit 45 extracts the first and second mixed pixel signals M1v and M2g from the input signal, obtains an average value of each signal value, and calculates an optimal light amount ratio in the control unit 31. Input to the unit 39. The optimum light amount ratio calculation unit 39 calculates the optimum light amount ratio Z ₀ based on the equation (2) using the signal value input from the calibration processing unit 45.

The optimum control unit 31, the calibration is performed, which erases the optimum quantity ratio Z _0, which is stored in the information storage unit 30 of the complementary color type endoscope 13a, calculated by the optimum light amount ratio calculating section 39 rewriting the light quantity ratio _{Z 0.}

  The first processing unit for complementary color 41 is selected when the type of the endoscope 13 is a complementary color type and the observation mode is the normal light observation mode. The first to fourth mixed pixel signals M <b> 1 to M <b> 4 (see FIG. 10) are input from the complementary color imaging device 28 to the first processing unit 41 for complementary colors. The first complementary color processing unit 41 performs a well-known Y / C conversion used in the complementary color checkered color difference line sequential method to generate the luminance signal Y and the color difference signals Cr and Cb, and further performs the matrix calculation to the luminance signal Y and the color difference. Signals Cr and Cb are converted into RGB signals. The RGB signals are sent to the channel assignment unit 38. Specifically, the luminance signal Y and the color difference signals Cr and Cb are added and subtracted between the first mixed pixel signal M1 and the second mixed pixel signal M2 adjacent in the row direction, and the third mixed pixel signal M3 adjacent in the row direction. And the fourth mixed pixel signal M4.

  The complementary color second processing unit 42 is selected when the type of the endoscope 13 is a complementary color type and the observation mode is the narrow-band light observation mode. As illustrated in FIG. 15, the complementary color second processing unit 42 includes a signal extraction unit 46, an interpolation processing unit 47, and a color mixture correction unit 48.

  The signal extraction unit 46 extracts only the first and second mixed pixel signals M1 and M2 from the first to fourth mixed pixel signals M1 to M4 input from the complementary color image sensor 28 and inputs them to the interpolation processing unit 47. To do. The interpolation processing unit 47 performs a known pixel interpolation process, and generates two signals of the first and second mixed pixel signals M1 and M2 for the position of each mixed pixel. The color mixture correction unit 48 performs color mixture correction processing using Expression (3).

Here, _{K 1} is the ratio of the second mixed pixel signals M2V for the first mixed pixel signals M1V obtained when only the independent irradiating violet narrowband light Vn (M2v / M1v). K ₂ is the ratio of the first mixed pixel signals M1g for the second mixed pixel signals M2g obtained when only the independent irradiation green narrowband light Gn (M1g / M2g).

The color mixture correcting unit 48 calculates the correction coefficients K ₁ and K ₂ using the first mixed pixel signals M1v and M1g and the second mixed pixel signals M2g and M2v obtained in the calibration mode described above. The color mixture correcting unit 48 continues to hold the calculated correction coefficients K ₁ and K ₂ until calibration is performed again.

Further, the correction coefficients K ₁ and K ₂ are obtained at the manufacturing stage and stored in the information storage unit 30 of the complementary color endoscope 13a. The complementary color endoscope 13a is stored in the light source device 11 and the processor device 12. When connected, the control unit 31 may acquire the information from the information storage unit 30. Further, when calibration is performed, the correction coefficients K ₁ and K ₂ stored in the information storage unit 30 of the complementary color endoscope 13a are deleted, and the correction coefficient K ₁ calculated by the color mixture correction unit 48 is deleted. , K ₂ is preferable.

  The color mixture correction processing of Expression (3) reduces the color mixture components (the green narrowband light Gn component in the first mixed pixel signal M1 and the purple narrowband light Vn component in the second mixed pixel signal M2). The first and second mixed pixel signals M <b> 1 ′ and M <b> 2 ′ after color mixture correction are sent to the channel allocation unit 38.

  The primary color first processing unit 43 is selected when the type of the endoscope 13 is a primary color type and the observation mode is the normal light observation mode. RGB signals are input from the primary color image sensor 29 to the primary color first processing unit 43. This RGB signal is obtained by assigning one of R, G, and B signals to one pixel. The first primary color processing unit 43 performs a known pixel interpolation process, and generates three signals R, G, and B for each pixel. The RGB signal after this pixel interpolation processing is sent to the channel allocation unit 38.

  The primary color second processing unit 44 is selected when the type of the endoscope 13 is the primary color type and the observation mode is the narrow-band light observation mode. RGB signals are input from the primary color image sensor 29 to the second primary color processing unit 44. The primary color second processing unit 44 extracts the B signal and the G signal that are sensitive to the purple narrowband light Vn and the green narrowband light Gn, and similarly performs the pixel interpolation process, thereby performing the B signal and the G signal for each pixel. Is generated. The B signal and G signal are sent to the channel allocation unit 38.

  When the observation mode is the normal light observation mode, the channel allocating unit 38 receives RGB signals regardless of the type of the endoscope 13, so that the R, G, and B signals are respectively input to the image display device 14. Assigned to each channel of Rch, Gch, and Bch. As a result, a normal image on which an image of the specimen illuminated with the normal light is displayed is displayed on the image display device 14.

  Further, when the type of the endoscope 13 is a complementary color type and the observation mode is a narrow band light observation mode, the channel allocation unit 38 receives the first and second input from the second processing unit for complementary color 42. The mixed pixel signals M1 ′ and M2 ′ are assigned to each channel of the image display device 14 and displayed as shown in Expression (4).

  As a result, a special image in which an image of the specimen illuminated by the purple narrow band light Vn and the green narrow band light Gn is displayed on the image display device 14 is displayed. In the expression (4), the first mixed pixel signal M1 ′ corresponding to the purple narrowband light Vn is displayed by being assigned to two channels, so that the special image is a surface blood vessel (capillary blood vessel, etc.) near the living body surface layer, etc. The structure is easily visible. Note that the first and second mixed pixel signals M1 'and M2' may be weighted with a coefficient other than "1" and "0" and assigned to the channel.

  Furthermore, when the type of the endoscope 13 is the primary color type and the observation mode is the narrow-band light observation mode, the channel allocation unit 38 receives the B signal and the G signal input from the primary color second processing unit 44. Is assigned to each channel of the image display device 14 and displayed as shown in equation (5).

  As a result, a special image in which an image of the specimen illuminated by the purple narrow band light Vn and the green narrow band light Gn is displayed on the image display device 14 is displayed. This special image is an image in which the structure of a surface blood vessel or the like in the vicinity of the living body surface is easily visible. Similarly, the B signal and the G signal may be weighted with a coefficient other than “1” and “0” and assigned to the channel.

Next, a method for deriving Equation (1) that defines the range of the light amount ratio Z will be described. The light amounts of the purple narrowband light Vn and the green narrowband light Gn that are simultaneously irradiated into the specimen from the complementary color endoscope 13a are “X” and “Y”, respectively, and the purple narrowband light of the first mixed pixel (Mg + Cy). The average sensitivity to Vn is “a ₁ ”, the average sensitivity to the green narrowband light Gn of the first mixed pixel (Mg + Cy) is “b ₁ ”, and the second mixed pixel (G + Ye) is to the green narrowband light Gn. When the average sensitivity is “a ₂ ” and the average sensitivity of the second mixed pixel (G + Ye) with respect to the purple narrowband light Vn is “b ₂ ”, the first and second mixed pixel signals M1 and M2 are It is represented by (6). The average sensitivity is an average of the sensitivity in the wavelength region of each narrow band light.

Further, using these sensitivities a ₁ , b ₁ , a ₂ , and b ₂ , correction coefficients K ₁ and K ₂ used in the above-described color mixture correction processing are expressed by equations (7) and (8).

  When the color mixture correction represented by Expression (3) is performed on the first and second mixed pixel signals M1 and M2 represented by Expression (6), the first and second mixed pixel signals M1 after color mixture correction are performed. ', M2' is expressed by equations (9) and (10).

  Therefore, the light quantity X of the purple narrowband light Vn simultaneously irradiated on the specimen is increased from the light quantity Y of the green narrowband light Gn (X> Y), and the second mixed pixel used for imaging based on the green narrowband light Gn. Is set to be higher than the signal value M1 ′ of the first mixed pixel used for imaging based on the purple narrowband light Vn (M1 ′ <M2 ′). This condition is expressed by the equation (11).

A first mixing pixel signals M1v when independent irradiated only violet narrowband light Vn of quantity X _i, and the second mixed pixel signals M2g when only green narrowband light Gn light amount Y _i independent irradiation, respectively It is expressed by equations (12) and (13).

Applying these equations (12) and (13) to equation (11) yields the aforementioned equation (1). Referring to FIG. 12, since a ₁ ≈0.45 and a ₂ ≈0.98, when these values are substituted into Expression (11), the light quantity ratio Z defined by Expression (1) is 1 < in the range of Z <2.2, it is found that the optimum quantity ratio _{Z 0} is approximately 1.6.

FIG. 16 shows the ratio P1 (= a ₁ X / (a ₁ X + b ₁ Y)) of the purple narrowband light Vn occupying in the first mixed pixel signal M1 and the green narrow occupying in the second mixed pixel signal M2. The ratio P2 (= a ₂ Y / (a ₂ Y + b ₂ X)) of the component of the band light Gn and the sum (P1 + P2) of both are shown with respect to the light amount ratio Z (= X / Y). . Here, based on the spectral sensitivity characteristics of FIG. 12, a ₁ ≈0.45, a ₂ ≈0.98, b ₁ ≈0.53, and b ₂ ≈0.07.

  When the light quantity ratio Z is in the range of 1 <Z <2.2, the ratio P1 is increased while the ratio P1 is decreased as compared to the case of Z = 1, but the increase rate of the ratio P1 is a decrease of the ratio P2. Since it is larger than the ratio, the sum of both increases (the S / N ratio is improved). Therefore, in this range, the color separation between the purple narrowband light Vn component and the green narrowband light Gn component is improved, and the signal of the second mixed pixel used for imaging based on the green narrowband light Gn. The value M2 ′ increases from the signal value M1 ′ of the first mixed pixel used for imaging based on the purple narrowband light Vn. The purple narrow band light Vn is almost absorbed by hemoglobin in the superficial blood vessels, whereas the green narrow band light Gn is easily reflected by the mucous membrane or the like, so that M2 ′> M1 ′ is reflected by the mucosa or the like. The amount of light increases, and the visibility of the superficial blood vessels (the contrast between the superficial blood vessels and the mucous membrane) is improved.

  Next, the operation of the endoscope system 10 will be described along the flowchart shown in FIG. When the endoscope 13 is connected to the light source device 11 and the processor device 12 by the operator, the control unit 31 of the processor device 12 reads the unique information from the information storage unit 30 in the endoscope 13 and is connected. It is determined whether the endoscope 13 is a complementary color endoscope 13a or a primary color endoscope 13b. For example, in the case of the complementary color endoscope 13 a, the control unit 31 sets the light source device 11 and the processor device 12 to the normal light observation mode, and sends the complementary color first processing unit to the selector 40 in the signal processing unit 37. 41 is selected.

  In the normal light observation mode, the dichroic mirror 22 in the multiplexing unit 24 of the light source device 11 is retracted as described above, the WL-LED 20b is turned on, and normal light (white light) WL is generated. The light is supplied into the light guide 27 in the endoscope 13a. In addition, the complementary color imaging device 28 in the complementary color endoscope 13a is driven by the imaging control unit 32 in the field readout method and outputs the first to fourth mixed pixel signals M1 to M4. The first to fourth mixed pixel signals M1 to M4 are Y / C converted by the first processing unit for complementary color 41, converted to RGB signals, and displayed on the image display device 14 via the channel allocation unit 38. The As a result, a normal image captured under normal light is displayed on the image display device 14.

  The surgeon performs endoscopy by inserting the insertion portion 16 of the complementary color endoscope 13a into the body cavity of the patient. When it is desired to observe in more detail the running state of the surface blood vessels of the tissue to be examined such as an affected part in the body cavity, the mode switch 17a is operated by the operator. When the mode switch 17a is operated, the operation signal is detected by the control unit 31, and the light source device 11 and the processor device 12 are switched to the narrow-band light observation mode.

In the narrow-band light observation mode, the selector 40 selects the complementary color second processing unit 42 and changes the setting of the light source device 11. Specifically, the dichroic mirror 22 in the multiplexing unit 24 is disposed at the intersection of the optical axes of the V-LED 20a and the WL-LED 20b. At this time, the control unit 31 controls the light source control unit 21 based on the optimum quantity ratio Z ₀ contained in the unique information read from the information storage unit 30, the light quantity ratio Z that satisfies the above equation (1) The intensity ratio of the V-LED 20a and the WL-LED 20b is changed so that the purple narrowband light Vn and the green narrowband light Gn are emitted from the complementary color endoscope 13a.

  The V-LED 20a and the WL-LED 20b are turned on at the same time, and the combining unit 24 generates narrow band light in which the purple narrow band light Vn and the green narrow band light Gn are mixed, and the light in the complementary color endoscope 13a. It is supplied into the guide 27. The complementary color image sensor 28 is driven by the field readout method and outputs the first to fourth mixed pixel signals M1 to M4. In the complementary color second processing unit 42, the signal extraction unit 46 extracts the first and second mixed pixel signals M 1 and M 2 from the first to fourth mixed pixel signals M 1 to M 4, and the interpolation processing unit 47 performs pixel interpolation processing. Then, the color mixture correction unit 48 performs color mixture correction. The first and second mixed pixel signals M1 ′ and M2 ′ after the color mixture correction are assigned by the channel assigning unit 38 to the second mixed pixel signal M2 ′ to Rch and the first mixed pixel signal M1 ′ to Gch and Bch. It is displayed on the image display device 14. As a result, a special image picked up under narrowband light is displayed on the image display device 14.

  Since the purple narrowband light Vn can be transmitted from the surface of the specimen to the first transmission distance near the surface layer, the first image based on the purple narrowband light Vn includes a structure included in the first transmission distance such as a surface blood vessel. A lot of images are included. The first image is generated based on the first mixed pixel signal M1. On the other hand, since the green narrow band light Gn can be transmitted from the surface of the specimen to the second transmission distance in the vicinity of the middle deep layer, the second transmission distance such as the middle depth blood vessel is included in the second image based on the green narrow band light Gn. There are many images of structures included in. Further, the second image is excellent in visibility of the fine pattern of the mucous membrane. This second image is generated based on the second mixed pixel signal M2. A special image is a combination of the first image and the second image.

In the present embodiment, the light quantity ratio Z is set so as to satisfy the formula (1) based on the optimum light quantity ratio Z ₀ (preferably, Z = Z ₀ ). A special image with improved surface blood vessel visibility (contrast between surface blood vessels and mucous membranes) is obtained.

  The display of the special image is repeatedly performed until the mode changeover switch 17a is operated or an ending operation for ending the diagnosis is performed by the input device 15. When the mode switch 17a is operated, the normal light observation mode is restored, and when the end operation is performed, the operation is ended.

  On the other hand, when the control unit 31 determines that the primary color endoscope 13b is connected to the light source device 11 and the processor device 12, the light source device 11 and the processor device 12 are set to the normal light observation mode and the selector 40 is set. Thus, the primary color first processing unit 43 is selected. In this normal light observation mode, as in the complementary color type, normal light (white light) WL is generated by the light source device 11 and supplied into the light guide 27 of the primary color type endoscope 13b.

  In this case, the primary color image pickup device 29 is driven by a progressive reading method and outputs RGB signals. The RGB signals are subjected to pixel interpolation processing and the like by the first primary color processing unit 43 and are displayed on the image display device 14 via the channel allocation unit 38. As a result, a normal image captured under normal light is displayed on the image display device 14.

  Thereafter, when the operator operates the mode switch 17a, the light source device 11 and the processor device 12 are switched to the narrow-band light observation mode. In this narrow-band light observation mode, the primary color second processing unit 44 is selected by the selector 40, the setting of the light source device 11 is changed, and the dichroic mirror 22 in the multiplexing unit 24 is connected to the V-LED 20a and the WL- It arrange | positions at the intersection of the optical axis of LED20b. In this case, unlike the complementary color type, the emission intensity ratio of the V-LED 20a and the WL-LED 20b is set to be Z = 1. A narrow band light in which the purple narrow band light Vn and the green narrow band light Gn are mixed is generated and supplied into the light guide 27 of the primary color endoscope 13b.

  Similarly, the primary color imaging device 29 is driven by the progressive readout method and outputs RGB signals. From this RGB signal, only the B signal and the G signal are extracted by the second primary color processing unit 44, subjected to pixel interpolation processing and the like, and displayed on the image display device 14 via the channel allocation unit 38. As a result, a special image picked up under narrowband light is displayed on the image display device 14.

  As in the case of the complementary color type, the display of the special image is repeatedly performed until the mode changeover switch 17a is operated or the end operation is performed by the input device 15. When the mode switch 17a is operated, the normal light observation mode is restored, and when the end operation is performed, the operation is ended.

Further, when the light source device 11 and the complementary color type endoscope 13a to the processor unit 12 is connected, that the calibration is performed for recalculating the optimum light quantity ratio Z ₀ by the operation such as the input device 15 It is possible. This calibration is performed using a white plate or the like as an imaging target.

When the calibration is executed, the selector 40 selects the calibration processing unit 45, and the time division irradiation of the purple narrowband light Vn and the green narrowband light Gn is performed with the light amount ratio Z currently in use. The first mixed pixel signals M1v and M1g and the second mixed pixel signals M2g and M2v are output from the complementary color image sensor 28, and the calibration processing unit 45 obtains an average value of the signal values. Then, the light quantity ratio Z currently in use, the first and second mixed pixel signals M1V, optimum light quantity ratio Z ₀ the optimum light intensity ratio calculation unit 39 based on the respective average value of M2g is calculated. Control unit 31, and sets the optimum light quantity ratio Z ₀ which is calculated in the light source device 11, changed or erased optimum quantity ratio Z _0, which is stored in the information storage unit 30 in the complementary color type endoscope 13a.

The first mixed pixel signals M1v and M1g and the second mixed pixel signals M2g and M2v obtained by this calibration are used when calculating the correction coefficients K ₁ and K ₂ in the color mixture correction described above. The calculated correction coefficients K ₁ and K ₂ are written in the information storage unit 30 in the complementary color endoscope 13a and are used when the complementary color endoscope 13a is used next time.

  In the above embodiment, the light quantity ratio Z is set by controlling the light emission intensity of the V-LED 20a and the WL-LED 20b, but may be set by controlling each light emission time. Further, the light intensity ratio Z may be set by controlling both the light emission intensity and the light emission time.

  In each of the above embodiments, the V-LED 20a and the WL-LED 20b are used as the LED light source 20, but instead of the V-LED 20a, as shown in FIG. A blue LED that generates blue narrow band light Bn may be used. The center wavelength of the blue narrow band light Bn is in the range of about 410 nm to 420 nm, preferably about 415 nm.

  In addition, instead of the V-LED 20a and the WL-LED 20b, a plurality of LEDs having different emission wavelength ranges (for example, four LEDs) are provided, and normal light (white light) is generated by lighting all the plurality of LEDs. Alternatively, two narrowband lights may be generated by two of the plurality of LEDs. Further, other semiconductor light sources such as LD (Laser Diode) may be used instead of the LED.

  Further, in place of the light source device 11 of the above embodiment, a light source device having a lamp that emits light having a wide wavelength range such as white light and a narrow band filter may be used. In FIG. 19, the light source device 60 includes a lamp 61, an infrared cut filter 62, a diaphragm 63, a diaphragm driving unit 64, a rotary filter 65, a filter switching unit 66, and a condenser lens 67.

  The lamp 61 generates white light WL based on the control by the control unit 31 described above. The infrared cut filter 62 cuts an infrared component from the white light WL generated from the lamp 61 and makes it incident on the diaphragm 63. The aperture of the diaphragm 63 is adjusted by the diaphragm drive unit 64 to adjust the amount of light passing through the white light WL. The aperture driving unit 64 is controlled by the dimming circuit 36 described above.

  As shown in FIG. 20, the rotary filter 65 is provided with a first narrowband filter section 65a, a second narrowband filter section 65b, and an opening 65c. The filter switching unit 66 rotates the rotary filter 65 based on the control by the control unit 31, and on the optical axis of the white light WL, the first narrowband filter unit 65a, the narrowband filter unit 65b, and the opening 65c. Arrange one of the following.

  As shown in FIG. 21, the first narrowband filter section 65a includes a first characteristic section Va having a bandpass characteristic in the first narrowband (center wavelength 405 nm) and a second narrowband (center wavelength 540 nm). Is a bimodal filter including a second characteristic portion Ga having a bandpass characteristic. The transmittance of the first characteristic portion Va and the transmittance of the second characteristic portion Ga are substantially equal.

  The first narrowband filter unit 65a is arranged on the optical axis of the white light WL when the observation mode is the narrowband light observation mode and the type of the endoscope 13 is a primary color type. The white light WL passes through the first narrowband filter unit 65 a to become purple narrowband light Vn and green narrowband light Gn, and enters the light guide 27 through the condenser lens 67. Since the light guide 27 has the spectral attenuation characteristics shown in FIG. 13 described above, the light amounts of the purple narrow band light Vn and the green narrow band light Gn emitted from the light guide 27 are substantially equal in consideration of the spectral attenuation characteristics and the like. It is also preferable that the transmittance of the first characteristic portion Va is slightly higher than the transmittance of the second characteristic portion Ga.

  As shown in FIG. 22, the second narrowband filter unit 65b includes a first characteristic unit Vb having a bandpass characteristic in the first narrowband, as in the first narrowband filter unit 65a, and a second narrowband filter unit 65b. Although it is a bimodal filter including a second characteristic part Gb having a bandpass characteristic in the band, the transmittance of the first characteristic part Vb and the transmittance of the second characteristic part Gb are large.

The second narrowband filter unit 65b is arranged on the optical axis of the white light WL when the observation mode is the narrowband light observation mode and the type of the endoscope 13 is a complementary color type. The white light WL is transmitted through the first narrowband filter unit 65a, so that the purple narrowband light Vn and the green narrow light having a predetermined light amount ratio corresponding to the ratio of the transmittances of the first and second characteristic units Vb and Gb. The band light Gn is incident on the light guide 27 through the condenser lens 67. The transmittance ratio between the first and second characteristic portions Vb and Gb is such that the light quantity ratio Z between the purple narrowband light Vn and the green narrowband light Gn emitted from the light guide 27 satisfies the formula (1) (preferably Z = Z ₀ ), the spectral attenuation characteristics of the light guide 27 are set in consideration.

  The opening 65c is disposed on the optical axis of the white light WL when the observation mode is the normal light observation mode. The opening 65c allows the incident white light WL to pass through without being limited in wavelength. The white light WL enters the light guide 27 through the condenser lens 67 and is emitted from the light guide 27 as normal light.

  Further, in the above embodiment, the complementary color image pickup device 28 having the complementary color checkered color difference line sequential type complementary color separation filter 28a shown in FIG. 7 is used, but the complementary color checkered color difference line sequential type complementary color system shown in FIG. A complementary color image sensor having a color separation filter may be used.

  In the above embodiment, the combination of the Mg pixel and the Cy pixel is the first mixed pixel, and the combination of the G pixel and the Ye pixel is the second mixed pixel. However, the combination of the mixed pixels is not limited to this, and can be changed as appropriate. You may do it.

In the above-described embodiment, in the calibration mode, the purple narrowband light Vn and the green narrowband light Gn are time-divisionally irradiated with the light amount ratio Z currently in use, and the light amount ratio Z is mixed with the first and second mixed light amounts. The optimum light amount ratio Z ₀ is calculated based on each signal value of the pixel, but instead, when the light amount ratio Z is changed stepwise, the purple narrow band light Vn and the green narrow band light Gn are used. By performing divided irradiation and determining the magnitude relationship between the signal value M1 ′ of the first mixed pixel and the signal value M2 ′ of the second mixed pixel obtained for each light quantity ratio Z, a range corresponding to Expression (1) is obtained. The optimum light quantity ratio Z ₀ corresponding to the expression (2) may be determined.

  In the above-described embodiment, the imaging control unit 32, the CDS circuit 33, the A / D conversion circuit 34, and the like are provided in the processor device 12, but these may be provided in the endoscope 13.

  In the above embodiment, the complementary color image sensor 28 and the primary color image sensor 29 are CCD image sensors. However, these may be CMOS image sensors. In the case of a CMOS image sensor, the imaging control unit 32, the CDS circuit 33, the A / D conversion circuit 34, etc. can be formed in a CMOS semiconductor substrate on which the image sensor is formed.

  In the above embodiment, the complementary color endoscope and the primary color endoscope can be connected to the light source device and the processor device, but only the complementary color endoscope may be connected.

  Moreover, in the said embodiment, although the light source device and the processor apparatus are comprised as a separate apparatus, these are good also as a single apparatus. Further, the light source device may be incorporated in the endoscope.

  Note that the “irradiation unit” in the claims refers to “light source device” and “optical member for guiding light from the light source device and irradiating the specimen (light guide, illumination lens, etc.) in this embodiment. It corresponds to the combination of "."

DESCRIPTION OF SYMBOLS 10 Endoscope system 11 Light source apparatus 12 Processor apparatus 13 Endoscope 13a Complementary color type | mold endoscope 13b Primary color type | mold endoscope 14 Image display apparatus 16 Insertion part 17 Operation part 17a Mode change switch 20 LED light source 24 Multiplexing part 27 Light Guide 28 Complementary color imaging device 28a Complementary color separation filter 29 Primary color imaging device 29a Primary color separation filter 37 Signal processor

Claims (5)

A complementary color endoscope in which a complementary color image pickup device in which an image pickup device having a pixel to which any of the color filter segments of cyan, magenta, yellow, and green is attached is arranged;
The complementary color endoscope can be detachably connected, and includes a first narrowband light having a center wavelength in a blue or violet wavelength range and a second narrowband light having a center wavelength in a green wavelength range. An irradiation unit having a light source device to generate;
When the complementary color endoscope is connected to the light source device, a first light amount ratio that is a light amount ratio of the light amount of the first narrowband light to the light amount of the second narrowband light is set to a value larger than 1. A control unit to be set;
Equipped with a,
In addition to the complementary color endoscope, a primary color endoscope in which a primary color image sensor is arranged can be detachably connected to the light source device.
The control unit is a second light amount ratio that is a light amount ratio of the light amount of the first narrowband light to a light amount of the second narrowband light that is set when the primary color endoscope is connected. An endoscope system that is set to a value larger than the light intensity ratio . A complementary color endoscope in which a complementary color image pickup device in which an image pickup device having a pixel to which any of the color filter segments of cyan, magenta, yellow, and green is attached is arranged;
The complementary color endoscope can be detachably connected, and includes a first narrowband light having a center wavelength in a blue or violet wavelength range and a second narrowband light having a center wavelength in a green wavelength range. An irradiation unit having a light source device to generate;
When the complementary color endoscope is connected to the light source device, a first light amount ratio that is a light amount ratio of the light amount of the first narrowband light to the light amount of the second narrowband light is set to a value larger than 1. A control unit to be set;
With
The complementary color imaging device reads out the first mixed pixel and the second mixed pixel that are sensitive to both the first narrowband light and the second narrowband light,
A signal processing unit that uses the signal value of the first mixed pixel for imaging based on the first narrowband light, and uses the signal value of the second mixed pixel for imaging based on the second narrowband light;
The said control part is an endoscope system which sets the said 1st light quantity ratio so that the signal value of a said 2nd mixing pixel may be larger than the signal value of a said 1st mixing pixel. The irradiation unit, the endoscope system according to the first narrowband light and the second narrow band light to 請 Motomeko 1 or 2 you simultaneous irradiation. An image display device having an R channel, a G channel, and a B channel;
The first signals corresponding to the narrow-band light endoscope system according to 請 Motomeko 1 to assign to the G channel and the B channel 3 any one. The light source device has a plurality of LED light sources,
Wherein the control unit, the endoscope system according to item 1 4 either from 請 Motomeko 1 to set the first light amount ratio by controlling the emission intensity and / or emission time of the plurality of LED light sources.

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