WO2006120795A1 - 生体観測装置 - Google Patents
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- WO2006120795A1 WO2006120795A1 PCT/JP2006/304388 JP2006304388W WO2006120795A1 WO 2006120795 A1 WO2006120795 A1 WO 2006120795A1 JP 2006304388 W JP2006304388 W JP 2006304388W WO 2006120795 A1 WO2006120795 A1 WO 2006120795A1
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Definitions
- the present invention relates to a living body observation apparatus that uses a color image signal obtained by imaging a living body to generate a pseudo narrowband filter by signal processing and displays it as a spectral image on a monitor.
- endoscope apparatuses that irradiate illumination light and obtain an endoscopic image in a body cavity have been widely used.
- an electronic endoscope having an imaging unit that guides illumination light from a light source device into a body cavity using a light guide or the like and images a subject using the returned light is used by a video processor.
- a video processor By processing the imaging signal of the imaging means force, an endoscopic image is displayed on the observation monitor and an observation site such as an affected part is observed.
- one method is to emit white light in the visible light region with a light source device, for example, through a rotary filter such as RGB, and so on.
- a color image is obtained by irradiating the subject with light and simultaneously processing the return light from the surface sequential light with a video processor.
- another method is to place a color chip in front of the imaging surface of the imaging means of the endoscope and use the light source device to emit white light in the visible light region. The color light is obtained by separating the return light of the white light for each color component with a color chip and processing the image with a video processor.
- a living tissue has different light absorption characteristics and scattering characteristics depending on the wavelength of the irradiated light.
- Japanese Patent Application Laid-Open No. 2002-95635 discloses illumination light in a visible light region having discrete spectral characteristics.
- a narrow-band optical endoscope apparatus that irradiates a living tissue with narrow-band RGB surface sequential light and obtains tissue information of a desired deep part of the living tissue has been proposed.
- the apparatus described in Japanese Patent Laid-Open No. 2003-93336 does not require a filter for generating narrowband RGB light by obtaining a spectral image by signal processing.
- the obtained spectral image is simply output to the monitor. Therefore, the image displayed on the motor may not be an image having a color tone suitable for observing tissue information of a desired deep part of the living tissue, and there is a possibility that the visibility is not good.
- an object of the present invention is to provide a living body observation apparatus that can improve the image quality of a signal that is displayed and output to improve visibility.
- the present invention is capable of adjusting tissue information of a desired deep part of a living tissue based on a spectral image obtained by signal processing into image information having a color tone suitable for observation, and suppressing white scale while reducing a circuit scale.
- An object of the present invention is to provide a living body observation apparatus that can share a circuit for performing necessary signal processing such as balance and ⁇ adjustment.
- a biological observation apparatus includes:
- An illumination unit that irradiates light to a living body as a subject
- An imaging unit that photoelectrically converts light reflected from the living body based on the irradiated light and generates an imaging signal
- a signal processing control unit that controls the operation of the illumination unit and the wing or the imaging unit and outputs the imaging signal to a display device;
- a spectral signal corresponding to an optical wavelength narrow band image from the imaging signal is obtained by signal processing.
- a color adjusting unit that assigns a different color tone to each of a plurality of bands forming the spectral signal when the spectral signal is output to the display device;
- An image quality adjustment unit for adjusting the image quality of a signal output to the display device
- An illumination unit that irradiates light to a living body as a subject
- An imaging unit that photoelectrically converts light reflected from the living body based on the irradiated light and generates an imaging signal
- a signal processing control unit that controls operations of the illumination unit and Z or the imaging unit and outputs the imaging signal to a display device
- a spectral signal generation unit that generates a spectral signal corresponding to an optical wavelength narrow band image from the imaging signal by signal processing
- a color adjusting unit that assigns a different color tone for each of a plurality of bands forming the spectral signal when the spectral signal is output to the display device;
- Signal processing units excluding at least the spectral signal generation unit and the color adjustment unit. Power is shared in each signal processing of the imaging signal and the spectral signal.
- FIG. 1 is a conceptual diagram showing a signal flow when creating a spectral image signal from a color image signal according to Embodiment 1 of the present invention.
- FIG. 2 is a conceptual diagram showing integration calculation of spectral image signals according to Embodiment 1 of the present invention.
- FIG. 3 is an external view showing the external appearance of the biological observation apparatus according to Embodiment 1 of the present invention.
- FIG. 5 is an external view showing the external appearance of the chopper of FIG.
- FIG. 6 is a diagram showing the arrangement of color filters arranged on the image pickup surface of the CCD in FIG.
- FIG. 7 is a graph showing spectral sensitivity characteristics of the color filter of FIG. [8] Configuration diagram showing the configuration of the matrix calculation unit of FIG.
- FIG. 9 is a spectrum diagram showing a spectrum of a light source according to Example 1 of the present invention.
- FIG. 10 is a spectrum diagram showing a reflection spectrum of a living body according to Example 1 of the present invention.
- FIG. 11 is a view showing a layered structure of a biological tissue observed by the biological observation apparatus of FIG.
- FIG. 12 is a diagram for explaining the state in which the illumination light of the living body observation apparatus of FIG.
- FIG. 13 is a diagram showing the spectral characteristics of each band of white light.
- FIG. 14 is a first diagram showing each band image of white light in FIG.
- FIG. 15 is a second diagram showing each band image by the white light of FIG.
- FIG. 16 is a third diagram showing each band image of white light in FIG.
- FIG. 17 is a view showing the spectral characteristics of the spectral image generated by the matrix calculation unit in FIG.
- FIG. 18 is a first diagram showing each spectral image of FIG.
- FIG. 19 is a second diagram showing the spectral images in FIG.
- FIG. 20 is a third diagram showing the spectral images in FIG.
- FIG. 21 is a block diagram showing the configuration of the color adjustment unit in FIG.
- ⁇ 22 A diagram illustrating the operation of the color adjustment unit in FIG.
- FIG. 23 is a block diagram showing a modification of the color adjustment unit in FIG.
- FIG. 18 is a diagram showing the spectral characteristics of the first modification of the spectral image of FIG.
- FIG. 25 A graph showing the spectral characteristics of the second modification of the spectral image of FIG.
- FIG. 18 is a view showing the spectral characteristics of the third modification of the spectral image of FIG.
- FIG. 27 is a block diagram showing another configuration example of the matrix calculation section according to Embodiment 1 of the present invention.
- FIG. 28] A block diagram showing the configuration of the biological observation apparatus according to Embodiment 2 of the present invention.
- ⁇ 29 Diagram showing an example of the light amount control unit in the biological observation apparatus according to Example 4 of the present invention.
- FIG. 30 is a diagram showing another example of the light amount control unit.
- FIG. 31 is a diagram showing another example of the light quantity control unit.
- ⁇ 32 A block diagram showing the configuration of the biological observation apparatus according to Embodiment 4 of the present invention.
- FIG. 33 is a diagram showing the charge accumulation time of the CCD in FIG. 32.
- FIG. 34 is a modification of FIG. 32, and shows the charge accumulation time of the CCD.
- FIG. 35 is a diagram showing an example of image quality improvement in the biological observation apparatus according to Example 8 of the present invention.
- FIG. 36 is a diagram showing an example of image quality improvement in the biological observation apparatus according to Example 9 of the present invention.
- FIG. 37 is a view showing another example of image quality improvement in the biological observation apparatus according to Example 9 of the present invention.
- FIG. 38 is a diagram showing an example of image quality improvement in the biological observation apparatus according to Example 10 of the present invention.
- FIG. 39 is a diagram showing an example of image quality improvement in the biological observation apparatus according to Example 12 of the present invention.
- FIG. 40 is a view showing another example of image quality improvement in the biological observation apparatus according to Embodiment 12 of the present invention.
- FIG. 41 is a diagram showing another example of image quality improvement in the biological observation apparatus according to Embodiment 12 of the present invention.
- FIG. 42 is a block diagram showing a configuration of a biological observation apparatus according to Embodiment 13 of the present invention.
- FIG. 43 is a block diagram showing a configuration of a biological observation apparatus according to Embodiment 14 of the present invention.
- FIG. 44 is a block diagram showing a configuration of a biological observation apparatus according to Embodiment 15 of the present invention.
- FIG. 45 is a diagram showing the arrangement of color filters in the biological observation apparatus according to Example 16 of the present invention.
- FIG. 46 is a graph showing spectral sensitivity characteristics of the color filter of FIG. 45.
- FIG. 47 is a flowchart for matrix calculation in the biological observation apparatus according to the present invention.
- FIGS. 1 to 26 relate to the first embodiment of the present invention
- FIG. 1 is a conceptual diagram showing a signal flow when creating a spectral image signal from a color image signal
- FIG. 2 is a conceptual diagram showing an integration operation of the spectral image signal
- 3 is an external view showing the external appearance of the electronic endoscope apparatus
- FIG. 4 is a block diagram showing the configuration of the electronic endoscope apparatus of FIG. 3
- FIG. 5 is an external view showing the external appearance of the chopper of FIG. 6 is a diagram showing the arrangement of the color filters arranged on the imaging surface of the CCD in FIG. 3
- FIG. 7 is a diagram showing the spectral sensitivity characteristics of the color filter in FIG. 6
- FIG. 8 is the configuration of the matrix calculation unit in FIG.
- Fig. 9 is a spectrum diagram showing the spectrum of the light source
- Fig. 10 is a spectrum diagram showing the reflection spectrum of the living body. It is a vector diagram.
- FIG. 11 is a diagram showing a layer direction structure of the biological tissue observed by the electronic endoscope apparatus of FIG. 4, and FIG. 12 is a diagram showing the illumination light of the electronic endoscope apparatus of FIG.
- FIG. 13 is a diagram illustrating the spectral characteristics of each band of white light
- FIG. 14 is a first diagram showing each band image by white light in FIG. 13, and FIG. 15 is by white light in FIG.
- FIG. 16 is a second diagram showing each band image
- FIG. 16 is a third diagram showing each band image by white light in FIG. 13
- FIG. 17 is a diagram showing the spectral characteristics of the spectral image generated by the matrix calculation unit in FIG. 18 is a first diagram showing each spectral image of FIG. 17,
- FIG. 19 is a second diagram showing each spectral image of FIG. 17, and
- FIG. 20 is a third diagram showing each spectral image of FIG. .
- FIG. 21 is a block diagram showing the configuration of the color adjustment unit in FIG. 4,
- FIG. 22 is a diagram for explaining the operation of the color adjustment unit in FIG. 21, and
- FIG. 23 shows a modification of the color adjustment unit in FIG.
- FIG. 24 is a diagram showing the spectral characteristics of the first modified example of the spectral image of FIG. 17,
- FIG. 25 is a diagram showing the spectral characteristics of the second modified example of the spectral image of FIG. 17, and
- FIG. 18 is a diagram showing a spectral characteristic of a third modification of the spectral image of FIG.
- an electronic endoscope apparatus as a living body observing apparatus according to an embodiment of the present invention
- light is applied to a living body that is a light source for illumination, and light reflected from the living body based on the irradiated light.
- a solid-state imaging device that is an imaging unit receives light and performs photoelectric conversion to generate an imaging signal that is a color image signal, and a spectral image that is a spectral signal corresponding to an optical wavelength narrowband image from the imaging signal.
- the signal is generated by signal processing.
- the matrix is a predetermined coefficient used when generating a spectral image signal from a color image signal acquired to generate a color image (hereinafter referred to as a normal image).
- FIG. 1 shows a color image signal (in this case, R'G'B for simplicity of explanation, but in a complementary color solid-state imaging device, as shown in the examples described later, G'Cy'Mg
- FIG. 5 is a conceptual diagram showing a signal flow when generating a spectral image signal corresponding to an image in a narrower optical wavelength band from a combination of “Ye”.
- the electronic endoscope apparatus performs numerical data on each color sensitivity characteristic of R′G′B.
- the color sensitivity characteristic of R′G′B is an output characteristic with respect to a wavelength obtained when a white light source is used and a white subject is imaged.
- the color sensitivity characteristics of R'G'B are shown on the right of each image data as a simplified graph. At this time, the color sensitivity characteristics of R'G'B are the n-dimensional column vectors “R”, “G”, and “B”, respectively.
- the electronic endoscope apparatus is a spectral band narrow-band pan-pass filter Fl 'F 2' F3 to be extracted.
- the electronic endoscope apparatus is a special feature of a filter that can efficiently extract a structure as foresight information.
- the characteristics of this filter are those whose wavelength bands are about 590 nm to about 610 nm, about 530 ⁇ m to about 550 nm, and about 400 m to about 430 nm, respectively.
- the matrix elements to be obtained may be obtained.
- equation (3) is given as a solution of the linear least square method that is not a one-dimensional simultaneous equation. In other words, the equation (3) force pseudo inverse matrix should be solved. Assuming that the transpose of matrix “C” is the same, equation (3) becomes
- ⁇ CCJ is a square matrix of n X n, so equation (4) can be viewed as a simultaneous equation for the matrix “A”! /, And its solution is
- the electronic endoscope apparatus performs the conversion of the left side of the equation (3) to extract the narrow-band Pandpass filter F1 'F2' F3 Can be approximated.
- the above is the description of the matrix calculation method that is the basis of the present invention.
- a matrix calculation unit 436 which will be described later, normally generates a spectral image signal from the color image signal.
- the light beam received by a solid-state imaging device such as a CCD is exactly white light (all wavelength intensities are the same in the visible range). It is. In other words, it is an optimal approximation when the RGB outputs are the same.
- the illumination light beam (light source light beam) is not completely white light, and the reflection spectrum of the living body is not uniform. Therefore, the light beam received by the solid-state imaging device is also white light. Dean! ⁇ (The color has arrived! The RGB values are not the same! /).
- the color sensitivity characteristics are R (e), G (e), and) ( ⁇ ), respectively.
- An example of the spectral characteristic of the illumination light is S (e), and an example of the reflection characteristic of the living body is ⁇ ( ⁇ ).
- the spectral characteristics of the illumination light and the reflection characteristics of the living body do not necessarily have to be the characteristics of the apparatus or subject to be inspected. For example, they may be acquired in advance and may be general characteristics.
- the electronic endoscope device When the optimization is actually performed, when the spectral sensitivity characteristic of the target filter (F1'F2-F3 in Fig. 1) is negative, it becomes 0 on the image display (that is, the spectral sensitivity of the filter). It is added that it is allowed to use a partial force S of the optimized sensitivity distribution using only the part having the positive sensitivity).
- the electronic endoscope device In order to generate a narrow spectral sensitivity characteristic, the electronic endoscope device has a negative sensitivity characteristic in addition to the target F1 'F2' F3 characteristic as shown in Fig. 1. By adding, it is possible to generate a component approximating a sensitive band.
- This method for improving the SZN ratio solves the following problems by adding to the processing method described above.
- the characteristics of the filters F1 to F3 in the processing method are those of a filter that can extract the structure efficiently. There is a possibility that the characteristics (ideal characteristics) may be greatly different (R ⁇ G ⁇ B, if only two signals are generated, the two original signals may not be saturated. is necessary).
- this method of improving the SZN ratio involves illumination light irradiation several times (for example, n times) in one field (one frame) of a normal image (a general color image).
- N is an integer of 2 or more) (irradiation intensity may be changed each time.
- it is indicated as 10 to In. This is the control of illumination light.
- O This makes it possible for the electronic endoscope apparatus to reduce the intensity of one irradiation, and to suppress the saturation of any of the RGB signals.
- image signals that have been divided into several times are added n times later.
- the electronic endoscope apparatus The component can be increased to improve the SZN ratio.
- integration units 438a to 438c function as image quality adjustment units that improve the SZN ratio.
- the above is a matrix calculation method that is the basis of the present invention, a correction method for obtaining an accurate spectral image signal that can be carried out together with this, and a generated spectral image signal.
- the color image signal is R, G, B, and the spectral image signal to be estimated is Fl, F2, F3. Strictly speaking, the color image signals R, G, B are also functions of the positions X, y on the image.
- the goal is to estimate the 3X3 matrix "A" that calculates Fl, F2, and F3 for R, G, and B forces.
- ⁇ is the wavelength
- t is the transpose in the matrix operation.
- the image signals R, G, B and the spectral signals Fl, F2, F3 are expressed as a matrix as follows.
- the image signal “P” is calculated by the following equation.
- D is a matrix with three fundamental spectra Dl (D), D2 (D), D3 ( ⁇ ) in the column vector, and “W” is Dl (D), D2 for “H” (E), a weighting coefficient that represents the contribution of D3 ( ⁇ ). It is known that this approximation holds when the color of the subject does not vary so much.
- the 3 x 3 matrix "M” indicates a matrix in which the calculation results of the matrix "CSJD" are combined into one.
- “0050 — 1 ” represents an inverse matrix of the matrix “ ⁇ ”.
- “ ⁇ , ⁇ _1 ” is a 3 X 3 matrix, and the target matrix “ ⁇ ”.
- the electronic endoscope apparatus 100 includes an endoscope 101, an endoscope apparatus body 105, and a display monitor 106 as a display apparatus.
- the endoscope 101 is provided on the side opposite to the distal end side of the insertion portion 102, the insertion portion 102 inserted into the body of the subject, the distal end portion 103 provided at the distal end of the insertion portion 102, and the distal end.
- An angle operation unit 104 for instructing a bending operation or the like of the unit 103 is mainly configured.
- the image of the subject acquired by the endoscope 101 is sent to a predetermined signal by the endoscope apparatus body 105. Processing is performed, and the processed image is displayed on the display monitor 106.
- FIG. 4 is a block diagram of the simultaneous electronic endoscope apparatus 100.
- the endoscope apparatus main body 105 mainly includes a light source section 41 as a lighting section, a control section 42, and a main body processing apparatus 43.
- the control unit 42 and the main body processing device 43 constitute a signal processing control unit that controls the operation of the light source unit 41 and Z or the CDD 21 as the imaging unit and outputs an imaging signal to the display monitor 106 that is a display device. .
- the endoscope apparatus main body 105 which is a single unit, is described as having the light source section 41 and the main body processing apparatus 43 that performs image processing or the like.
- these light source sections 41 and The main body processing device 43 may be configured to be removable as a unit different from the endoscope main body 105.
- the light source unit 41 is connected to the control unit 42 and the endoscope 101. Based on the signal from the control unit 42, white light is emitted with a predetermined amount of light (not complete white light! Irradiation).
- the light source unit 41 includes a lamp 15 as a white light source, a chopper 16 as a light amount control unit for adjusting the light amount, and a chopper driving unit 17 for driving the chopper 16.
- the chopper 16 has a configuration in which a notch portion having a predetermined length in the circumferential direction is provided in a disk-shaped structure having a predetermined radius r and having a center at a point 17a. Is provided.
- the center point 17a is connected to a rotating shaft provided in the chopper driving unit 17.
- the chopper 16 performs a rotational motion around the center point 17a.
- a plurality of notches are provided for each predetermined radius.
- the length and width of the notch in the chopper 16 are merely examples, and are not limited to the present embodiment.
- the chopper 16 has a protrusion 160 extending radially in the approximate center of the notch. has a.
- the control unit 42 switches the frame when the light is blocked by the projection 160a, thereby minimizing the interval between the light emitted one frame before and after the frame, and the movement due to the movement of the subject. Is to minimize.
- the chopper driving unit 17 is configured to be movable in the direction with respect to the lamp 15 as indicated by an arrow in FIG.
- the control unit 42 can change the distance R between the rotation center 17a of the chopper 16 shown in FIG. 5 and the luminous flux from the lamp (shown by a dotted circle). For example, in the state shown in FIG. 5, since the distance R is small, the amount of illumination light is small. Increasing the distance R (the chopper drive unit 17 away from the lamp 15) increases the length of the notch through which the light beam can pass, so that the irradiation time increases, and the control unit 42 can increase the amount of illumination light. it can.
- the electronic endoscope apparatus there is a possibility that the newly generated spectral image may be insufficient as the SZN ratio, and whether the RGB signal necessary for generating the spectral image is shifted. If the signal is saturated, the correct calculation is not performed, so the amount of illumination light must be controlled.
- the chopper 16 and the chopper driving unit 17 are responsible for this light quantity adjustment.
- the endoscope 101 connected to the light source unit 41 via the connector 11 includes an object lens 19 and a solid-state imaging device 21 such as a CCD (hereinafter simply referred to as a CCD) at the distal end portion 103.
- the CCD 21 constitutes an imaging unit that photoelectrically converts light reflected from a living body, which is a subject, based on irradiation light from a light source unit 41 that constitutes an illumination unit, and generates an imaging signal.
- the CCD in this embodiment is a single-plate type (CCD used for a simultaneous electronic endoscope) and is a primary color type.
- Fig. 6 shows the arrangement of color filters arranged on the CDD imaging surface.
- Fig. 7 shows the spectral sensitivity characteristics of RGB in the color filter of Fig. 6.
- the insertion unit 102 includes a light guide 14 that guides the light emitted from the light source unit 41 to the distal end portion 103, and an image of the subject obtained by the CCD.
- a forceps port 29 for inserting forceps into the forceps channel 28 is provided in the vicinity of the operation unit 104.
- the main body processing device 43 is connected to the endoscope 101 via the connector 11, similarly to the light source unit 41.
- the main body processing device 43 includes a CCD drive circuit 431 for driving the CCD 21.
- the main body processing device 43 has a luminance signal processing system and a color signal processing system as signal circuit systems for obtaining a normal image.
- the luminance signal processing system includes a contour correction unit 432 that is connected to the CCD 21 and performs contour correction, and a luminance signal processing unit 434 that generates a luminance signal from the data corrected by the contour correction unit 432.
- the color signal processing system is connected to the CCD 21, performs sampling of the signal obtained by the CCD 21, etc., and generates RGB signals.
- a color signal processing unit 435 is connected to the output and generates a color signal.
- a normal image generation unit 437 that generates one normal image from the output of the luminance signal processing system and the output of the color signal processing system is provided, and the normal image generation unit 437 to the switching unit 43 are provided.
- the Y signal, R—Y signal, and B—Y signal are sent to the display monitor 106.
- a matrix calculation unit 436 which receives the outputs (RGB signals) of the SZH circuits 433a to 433c and performs a predetermined matrix calculation on the RGB signals.
- Matrix calculation is the process of performing addition processing on color image signals and multiplying the matrix obtained by the matrix calculation method (or a modification thereof) described above.
- a force S for describing a method using electronic circuit processing (processing by a nodeware using an electronic circuit), a numerical value as in the embodiments described later,
- a method using data processing (processing by software using a program) may be used.
- FIG. 8 shows a circuit diagram of the matrix calculation unit 436.
- the RGB signals are input to the amplifiers 32a to 32c through the resistor groups 31a to 31c, respectively.
- Each resistor group has a plurality of resistors to which RGB signals are respectively connected, and the resistance value of each resistor is a value corresponding to the matrix coefficient. That is, the RGB signal by each resistor The gain is changed and added by an amplifier (subtraction may be used).
- the outputs of the amplifiers 32a to 32c are the outputs of the matrix calculation unit 436. That is, the matrix calculation unit 436 performs so-called weighted addition processing.
- the resistance value of each resistor used here may be variable.
- the outputs of the matrix operation unit 436 are connected to the integration units 438a to 438c, respectively, and after integration is performed, the color adjustment unit 440 applies the respective spectral image signals ⁇ F1 to ⁇ F3. Color adjustment calculation described later is performed, and color channels Rch, Gch, and Bch are generated from the spectral image signals ⁇ F1 to ⁇ F3. The generated color channels Rch, Gch, and Bch are sent to the display monitor 106 via the switching unit 439. The configuration of the color adjustment unit 440 will be described later.
- the switching unit 439 switches between the normal image and the spectral image, and can also switch and display the spectral images. That is, the operator can selectively display on the display monitor 106 a normal image, a spectral channel image by Rch, a spectral channel image by Gch, and a spectral channel image force by Bch. Alternatively, any two or more images may be displayed on the display monitor 106 at the same time.
- the normal image and the spectral channel image can be displayed simultaneously, the normal image generally observed and the spectral channel image can be easily compared, and the respective characteristics (normal image The feature is easy to observe because the color degree is close to that of the normal naked eye.
- the feature of the spectral channel image is that it can observe the predetermined blood vessels that cannot be observed in the normal image.) It can be observed and is very useful for diagnosis.
- the chopper driving unit 17 is set to a predetermined position and rotates the chopper 16.
- the light flux from the lamp 15 passes through the notch of the chopper 16, and is collected by a condenser lens into a light fiber bundle that is an optical fiber bundle provided in the connector 11 at the connection between the endoscope 101 and the light source 41.
- the light is condensed at the entrance end of id 14.
- the condensed light flux passes through the light guide 14 and is irradiated into the body of the subject from the illumination optical system provided at the distal end portion 103.
- the irradiated light beam is reflected in the subject, and signals are collected by the color filters shown in FIG. 6 in the CCD 21 via the objective lens 19.
- the collected signals are input in parallel to the luminance signal processing system and the color signal processing system.
- the signal collected for each color filter is calculated for each pixel and input to the contour correction unit 432 of the luminance signal system, and is supplied to the luminance signal processing unit 434 after contour correction.
- a luminance signal is generated and input to the normal image generation unit 437.
- the signals collected by the CCD 21 are input to the SZH circuits 433a to 433c for each color filter, and R′G′B signals are respectively generated. Further, the color signal processing unit 435 generates a color signal for the R′G′B signal, and the normal image generation unit 437 generates a Y signal, an R ⁇ Y signal, and a B ⁇ Y signal from the luminance signal and the color signal. Then, the normal image of the subject is displayed on the display monitor 106 via the switching unit 439.
- the operator operates the keyboard provided in the endoscope apparatus main body 105 or the switch provided in the operation unit 104 of the endoscope 101 to give an instruction to observe the spectral image from the normal image cover. Do.
- the control unit 42 changes the control state of the light source unit 41 and the main body processing device 43.
- the amount of light emitted from the light source unit 41 is changed as necessary. As described above, since it is not desirable that the output from the CCD 21 is saturated, the amount of illumination light is made smaller when observing a spectral image than when observing a normal image.
- the control unit 42 controls the amount of light so that the output signal from the CCD does not saturate, and also changes the amount of illumination light within the range where it does not saturate.
- the signal output from the switching unit 439 is switched from the output of the normal image generation unit 437 to the output of the color adjustment unit 440.
- the outputs of the SZH circuits 433a to 433c are amplified and added by the matrix calculation unit 436, and output to the integration units 438a to 438c according to the respective bands. It is output to the color adjustment unit 440 later. Even when the amount of illumination light is reduced by the chopper 16, the signal intensity can be increased and the SZN ratio can be improved as shown in FIG. 2 by storing and integrating by the integrating units 438a to 438c. A spectral image can be obtained.
- the ideal narrowband bandpass filters F1 to F3 (in this case, ⁇ tK ⁇ Fl: 590nm ⁇ 620nm, F2: 520nm ⁇ 560nm, F3: 400nm ⁇ 440nm), when trying to create a bandpass filter (hereinafter referred to as pseudo bandpass filter),
- pseudo bandpass filter when trying to create a bandpass filter
- the following matrix is optimal depending on the contents shown in the formula.
- the processing performed by the matrix calculation unit 436 is mathematically equivalent to the following matrix calculation.
- pseudo filter characteristics shown as characteristics of filter pseudo Fl to F3 in FIG. 7 are obtained. That is, the matrix processing described above creates a spectral image signal by using a pseudo bandpass filter (that is, a matrix) generated in advance as described above for a color image signal.
- a pseudo bandpass filter that is, a matrix
- the body cavity tissue 45 often has an absorber distribution structure such as blood vessels that differ in the depth direction.
- a large number of capillaries 46 are mainly distributed near the surface of the mucosa, deeper than this layer, and in the middle layer, in addition to capillaries, thicker than capillaries and blood vessels 47 are distributed. 48 will be distributed.
- the depth of light in the depth direction with respect to the tissue 45 in the body cavity depends on the wavelength of the light, and the illumination light including the visible range is blue (B) as shown in FIG.
- the illumination light including the visible range is blue (B) as shown in FIG.
- B blue
- green (G) light which has a longer wavelength than blue (B) light, it reaches deeper than the range where blue (B) color light deepens, and is absorbed and scattered within that range. Light is observed.
- red (R) light which has a longer wavelength than green (G) light, reaches a deeper range.
- the image signal picked up by the CCD 21 with B-band light is picked up with a band image having shallow layer and middle layer tissue information including a lot of tissue information in the shallow layer as shown in FIG. (2)
- the image signal picked up by the CCD 21 with G-band light is picked up with band images having shallow layer and middle layer tissue information as shown in FIG.
- the image signal picked up by the CCD 21 with the R-band light is picked up with band images having middle layer and deep layer tissue information including a lot of deep layer tissue information as shown in FIG.
- the endoscope apparatus main body 105 performs signal processing on these RGB imaging signals, so that it is possible to obtain an endoscopic image having a natural color reproduction that is desired as an endoscopic image.
- spectral image signals F1 to F3 are obtained by using pseudo bandpass filters F1 to F3 having discrete and narrow band spectral characteristics from which desired deep layer tissue information can be extracted as shown in FIG. As shown in FIG. 17, the pseudo bandpass filters F1 to F3 overlap each other in wavelength range.
- a band image having tissue information in the shallow layer as shown in FIG. 18 is captured in the spectral image signal F3 by the pseudo bandpass filter F3.
- a band image having tissue information in the middle layer as shown in FIG. 19 is captured in the spectral image signal F2 by the pseudo bandpass filter F2, and further,
- a band image having tissue information in the deep layer as shown in FIG. 20 is captured in the spectral image signal F1 by the pseudo bandpass filter F1.
- the color adjustment unit 440 uses the spectral image signal F1 as the color channel Rch as a simplest color conversion example.
- the signal F2 is assigned to the color channel Gch and the spectral image signal F3 is assigned to the color channel Bch, and output to the display monitor 106 via the switching unit 439.
- the color adjustment unit 440 includes a 3 X 3 matrix circuit 61, three LUTs 62a, 62b, 62c, 63a, 63b, 63c provided before and after the 3 X 3 matrix circuit 61, and an LUT 62a. , 62b, 62c, 63a, 63b, 63c and a coefficient changing circuit 64 for changing the coefficient of the 3 ⁇ 3 matrix circuit 61, and a color conversion processing circuit 440a.
- the spectral image signals F1 to F3 input to the color conversion processing circuit 440a are for each band data.
- the LUTs 62a, 62b, and 62c perform inverse ⁇ correction and nonlinear contrast conversion processing.
- the change by the coefficient changing circuit 64 is performed based on a control signal from a processing conversion switch (not shown) provided in the operation unit of the endoscope 101 or the like.
- the coefficient changing circuit 64 Upon receiving these control signals, the coefficient changing circuit 64 calls appropriate data for the coefficient data stored in advance in the color adjusting unit 440, and rewrites the current circuit coefficient with this data.
- the processing according to the equation (22) is color conversion in which the spectral image signals Fl to F3 are assigned to the spectral channel images Rch, Gch, and Bch in order of decreasing wavelength.
- the processing according to Equation (23) is a conversion example in which the spectral image signal F1 is mixed with the spectral image signal F2 at a certain ratio and the generated data is newly used as the spectral G channel image Gch. It becomes possible to clarify more clearly that scatterers are different in depth position.
- the matrix coefficient is set to the default value from the first operation in the color conversion processing circuit 440a in conjunction with a mode switching switch (not shown) provided in the operation unit of the endoscope 101. .
- the through operation here means a state in which the 3 ⁇ 3 matrix circuit 61 is mounted with a unit matrix, and the LUTs 62a, 62b, 62c, 63a, 63b, and 63c are mounted with non-conversion tables.
- a reverse ⁇ correction table and a y correction table are applied to the LUTs 62a, 62b, 62c, 63a, 63b, and 63c as necessary.
- the color conversion processing circuit 440a is a force that performs color conversion by a matrix computing unit including the 3 ⁇ 3 matrix circuit 61.
- the color conversion processing means is not limited to this, and the color conversion processing means may be configured by a numerical operation processor (CPU) or LUT.
- the color conversion processing circuit 440a is shown with a configuration centered on the 3 ⁇ 3 matrix circuit 61.
- the color conversion processing circuit 440a corresponds to each band.
- the coefficient changing circuit 64 is a processing conversion switch (not shown) provided in the operation unit or the like of the endoscope 101. To change the contents of the table based on the control signal.
- the filter characteristics of the pseudo bandpass filters F1 to F3 are not limited to the visible light range, and as a first modification of the pseudo bandpass filters F1 to F3, the filter characteristics are discrete, for example, as shown in FIG. A narrow band of typical spectral characteristics may be used.
- the filter characteristic of this first modification is that normal observation is possible by setting F3 in the near-ultraviolet region and F1 in the near-infrared region in order to observe the irregularities on the surface of the living body and the absorber near the deep layer. It is suitable for obtaining image information that cannot be obtained by.
- pseudo bandpass filters F1 to F3 As shown in FIG. 26, the two-band narrowband filter characteristics of discrete spectral characteristics that can extract desired layer texture information are shown. Two pseudo bandpass filters F2 and F3 may be generated by the matrix calculation unit 436.
- the color adjustment unit 440 uses the spectral channel image Rch spectral image signal F2, the colorization of the image during narrowband spectral image observation.
- Spectral channel image Gch Spectral image signal F3
- Spectral channel image Bch Spectral image signal F3, RGB3 channel color image is generated.
- the color adjustment unit 440 generates an RGB3 channel color image (Rch Gch Bch) by the following equation (24).
- the spectroscopic image F3 is an image whose central wavelength mainly corresponds to 415 nm
- the spectroscopic image F2 is an image whose central wavelength mainly corresponds to 540 nm.
- the spectral image F3 is an image whose center wavelength is mainly equivalent to 415 nm
- the spectral image F2 is an image whose center wavelength is mainly equivalent to 540 nm
- the spectral image F1 is a center wavelength mainly corresponding to 600 nm.
- Rch hllXFl + hl2XF2 + hl3XF3
- the coefficients of hll, hl3, h21, h22, h31, and h32 are set to 0, and other coefficients may be set to predetermined numerical values.
- a pseudo narrowband filter is generated by using a color image signal for generating a normal electronic endoscopic image (normal image).
- a spectral image having tissue information of a desired deep part such as a blood vessel pattern can be obtained without using an optical wavelength narrowband bandpass filter for images, and parameters of the color conversion processing circuit 440a of the color adjustment unit 440 can be obtained.
- an image corresponding to 415 nm is assigned to the color channels Gch and Bch, for example, an image corresponding to 540 nm is assigned to the color channel Rch, or
- FIG. 27 is a block diagram showing another configuration example of the matrix calculation unit.
- the configuration other than the matrix calculation unit 436 is the same as that shown in FIG.
- the configuration capability of the matrix calculation unit 436 shown in FIG. 27 is different from the configuration of the matrix calculation unit 436 shown in FIG. Only different points will be described, and the same components will be denoted by the same reference numerals and description thereof will be omitted.
- the matrix operation is performed by so-called hardware processing by an electronic circuit.
- this matrix operation is performed by numerical data processing (processing by software using a program).
- a matrix operation unit 436 shown in FIG. 27 has an image memory 50 for storing RGB color image signals.
- the coefficient register 51 stores each value of the matrix “A ′” shown in the equation (21) as numerical data.
- the coefficient register 51 and the image memory 50 are connected to the multipliers 53a to 53i, and the multiplier 5
- 3a, 53d, and 53g are connected to the multiplier 54a, and the output of the multiplier 54a is connected to the integrating unit 438a in FIG.
- the multipliers 53b, 53e, and 53h are connected to the multiplier 54b, and the output thereof is connected to the accumulating unit 438b.
- the multipliers 53c, 53f, and 53i are connected to the multiplier 54c, and the output thereof is connected to the integrating unit 438c.
- the input RGB image data is once stored in the image memory 50.
- each coefficient of the matrix “A,” is stored in the image memory 50 from the coefficient register 51 and the multiplier. Is multiplied.
- FIG. 27 shows an example in which the R signal and each matrix coefficient are multiplied by multipliers 53a to 53c.
- the G signal and each matrix coefficient are multiplied by multipliers 53d to 5d.
- the signal is multiplied by 3f
- the B signal and each matrix coefficient are multiplied by multipliers 53g to 53i.
- the data multiplied by the matrix coefficient is the output of the multiplier 53a, 53d, 53g is the multiplier 54a
- the output of the multiplier 53b, 53e, 53h is the multiplier 54b
- the multiplier 53c, 53f 53i are respectively multiplied by a multiplier 54c.
- the output of the multiplier 54a is sent to the accumulating unit 438a.
- the outputs of the multiplier 54b and the multiplier 54c are sent to the integrating units 438b and 438c, respectively.
- the matrix coefficient is not only the result value, ie, the matrix “A,” S ( ⁇
- FIG. 28 is a block diagram showing a configuration of an electronic endoscope apparatus according to Embodiment 2 of the present invention. Since the second embodiment is almost the same as the first embodiment, only differences from the first embodiment will be described, and the same components will be denoted by the same reference numerals and description thereof will be omitted.
- This embodiment is different from the first embodiment in the light source unit 41 that controls the amount of illumination light.
- the lamp 15 shown in FIG. 28 is provided with a current control unit 18 as a light amount control unit.
- control unit 42 controls the current flowing through the lamp 15 so that none of the RGB color image signals are saturated.
- the current used for light emission in the lamp 15 is controlled, so that the amount of light changes according to the magnitude of the current.
- Other operations are the same as those in the first embodiment, and are omitted here.
- a spectral image in which a blood vessel pattern is clearly displayed can be obtained as in the first embodiment. Further, this embodiment has an advantage that the control method is simpler than the light amount control method using the chopper as in the first embodiment.
- the light quantity is controlled by using the chopper 16 of FIG. 5 that blocks light at a predetermined time interval and controls the light quantity. In other words, the amount of light from the light source is reduced so that all color separation signals of R, G, and B are captured with an appropriate dynamic range.
- a movable light shielding member such as a diaphragm panel and a shutter
- a light shielding filter such as a mesh turret and an ND filter
- FIG. 29 shows an example of the diaphragm panel 66.
- the diaphragm panel 66 is rotated by a central axis 67, and a front end portion includes a blocking portion 69 for blocking a light beam 68 condensed to a certain size, and a diaphragm blade portion 71 having a notch 70 for controlling the amount of emitted light.
- the light is controlled by blocking the light at predetermined time intervals.
- the diaphragm panel 66 may be used as a dimming diaphragm panel that controls the amount of light emitted from the light source unit 41, or may be provided as a separate blocking mechanism.
- FIG. 30 shows an example of the shutter 66A.
- the shutter 66A has the same shape as the example of the aperture panel 66, but has a structure in which the notch 70 of the aperture panel 66 is not provided in the blocking portion 69.
- the operation of the shutter 66A controls the light quantity by blocking light at a predetermined time interval by controlling two operation states of full open and full close.
- FIG. 31 shows an example of the mesh turret 73. Large holes with mesh spacing, mesh 75 or smaller mesh spacing, mesh 76 is attached by welding etc. to the holes in rotating plate 74
- FIG. 32 and 33 relate to the fourth embodiment of the present invention, and FIG. 32 shows the configuration of the electronic endoscope apparatus.
- FIG. 33 is a diagram showing the charge accumulation time of the CCD shown in FIG.
- the present embodiment is mainly different from the first embodiment in the light source unit 41 and the CCD 21.
- the color filter shown in FIG. 6 is provided in the CCD 21 and a color signal is generated by this color filter.
- the illumination light is transmitted for a period of one frame.
- a so-called frame sequential method is used in which color signals are generated by illuminating in the order of RGB.
- the light source unit 41 in the present embodiment is provided with a diaphragm 25 for dimming on the front surface of the lamp 15, and further on the front surface of the diaphragm 25 in the order of R, G, and B.
- an RGB rotation filter 23 that rotates, for example, once in one frame is provided.
- the aperture 25 is connected to an aperture control unit 24 as a light amount control unit, and restricts the luminous flux to be transmitted among the luminous flux emitted from the lamp 15 in accordance with a control signal from the aperture control unit 24. Dimming is possible by changing the amount of light.
- the RGB rotation filter 23 is connected to the RGB rotation filter control unit 26 and rotates at a predetermined rotation speed.
- the operation of the light source unit in the present embodiment is as follows.
- the luminous flux output from the lamp 15 is limited to a predetermined amount of light by the aperture 25, and the luminous flux transmitted through the aperture 25 passes through the RGB rotation filter 23 to be predetermined.
- Each illumination light is reflected within the subject and received by the CCD 21.
- Signals obtained by the CCD 21 are distributed by a switching unit (not shown) provided in the endoscope apparatus main body 105 according to the irradiation time, and input to the SZH circuits 433a to 433c, respectively.
- the illumination light is irradiated from the light source unit 41 through the R filter, the signal obtained by the CCD 21 is input to the SZH circuit 433a. Since other operations are the same as those in the first embodiment, they are omitted here.
- the fourth embodiment as in the first embodiment, a spectral image in which the blood vessel pattern is clearly displayed can be obtained. Also, in the fourth embodiment, unlike the first embodiment, it is possible to enjoy the merits of the so-called frame sequential method. This merit is, for example, a modification of FIG. 34 described later.
- the illumination light quantity (light quantity from the light source unit) is controlled and adjusted in order to avoid saturation of the RGB color signal.
- a method of adjusting the electronic shutter of the CCD 21 is adopted. In the CCD 21, charges that are proportional to the intensity of light incident within a certain period of time are accumulated, and the amount of charges is used as a signal.
- an electronic shutter Corresponding to this accumulation time is what is called an electronic shutter.
- the electronic shutter By adjusting the electronic shutter with the CCD drive circuit 431, the amount of accumulated charge, that is, the signal amount can be adjusted.
- a similar spectral image can be obtained by obtaining an RGB power error image with the charge accumulation time sequentially changed for each frame. That is, in each of the above-described embodiments, the illumination light amount control by the diaphragm 25 is used for obtaining a normal image, and when obtaining a spectral image, the electronic shutter is changed to change the R, G, B color signals. It is possible to avoid saturation of.
- FIG. 34 is a diagram showing the charge accumulation time of a CCD which is another example of Embodiment 4 of the present invention.
- this example uses the frame sequential method and makes use of the advantages of this frame sequential method. That is, by adding weights for each of R, G, and B during the charge accumulation time by the electronic shutter control in the example of FIG. 33, it is possible to simplify the generation of spectral image data S.
- the CCD drive circuit 431 is provided that can change the charge storage time of the CCD 21 for each of R, G, and B within one frame period. Others are the same as the example of FIG.
- tdr, tdg, tdb is the charge accumulation time of CCD21 when the illumination light is R, G, B (in this figure, tdb is omitted because the B color image signal has no accumulation time) ).
- the F 3 pseudo filter image in the case of performing the matrix processing expressed by the equation (21) is obtained from an RGB image normally obtained by an endoscope,
- the matrix calculation unit simply adds the B component and the inverted signal of the R and G components. As a result, a spectral image similar to that of the first to third embodiments can be obtained.
- Example 4 in Figs. 33 and 34 a spectral image in which a blood vessel pattern is clearly displayed can be obtained.
- the frame sequential method is used to create the color signal, and the charge accumulation time can be varied for each color signal using an electronic shutter. It is possible to simplify processing by simply performing addition and difference processing. That is, the electronic shutter control can perform an operation equivalent to a matrix calculation, and the processing can be simplified.
- the light quantity control of the first to third embodiments and the electronic shirt (charge storage time) control of the fourth embodiment can be performed simultaneously.
- the normal observation image may be controlled by controlling the amount of illumination light by a chopper or the like, and of course, when obtaining the spectroscopic observation image, control by an electronic shutter may be performed.
- Example 5 to Example 7 a signal amplifying unit that amplifies the signal level of the imaging signal of the normal image and the spectral signal of Z or the spectral image and its amplification control will be described.
- FIG. 4, FIG. 28 or FIG. 32 is applied to the configuration of the living body observation apparatus according to the fifth embodiment of the present invention.
- the AGC (auto gain control) in these configurations is performed by the signal amplification unit in each of the luminance signal processing unit 434 and the color signal processing unit 435 in FIG. 4, FIG. 28 or FIG. 32 during normal image observation. This is done by an AGC circuit (not shown).
- AGC at the time of spectral image observation is performed by an AGC circuit (for example, amplifiers 32a to 32c in FIG. 8 are variable amplifiers) which is a signal amplifying unit in the matrix calculation unit 436 in FIG. 4, FIG. 28 or FIG. It is.
- AGC control refers to the amplification level of the amplification function and the operation speed of the amplification function ( follow-up speed), or amplification function operation Z non-operation (may be referred to as ON Z OFF).
- Amplification function operation Z non-operation (on Z off) often does not operate the AGC during normal image observation. This is because the amount of light is sufficient for observation with normal light.
- the AGC is activated because the light quantity is insufficient.
- the operation speed (follow-up speed) of the amplification function for example, as the camera and the subject scene move away, the light intensity gradually decreases and the image becomes darker.
- the dimming function works at first and tries to increase the amount of light when it is dark, but the dimming operation cannot follow.
- AGC operates when it can no longer follow.
- the speed of the AGC operation is important. If the follow-up speed is too fast, noise will appear when it gets dark. An appropriate speed that is neither too fast nor too slow is important.
- the AGC operation may be quite slow, but during spectroscopic image observation it becomes dark immediately, so the AGC operation needs to follow the fast eye. As a result, the image quality of the signal that is displayed and output can be improved.
- FIG. 4, FIG. 28 or FIG. 32 is applied to the configuration of the living body observation apparatus according to the sixth embodiment of the present invention.
- the AGC (auto gain control) in these configurations is performed by the signal amplification unit in each of the luminance signal processing unit 434 and the color signal processing unit 435 in FIG. 4, FIG. 28 or FIG. 32 during normal image observation. This is done by an AGC circuit (not shown).
- AGC at the time of spectral image observation is performed by an AGC circuit (for example, amplifiers 32a to 32c in FIG. 8 are variable amplifiers) which is a signal amplifying unit in the matrix calculation unit 436 in FIG. 4, FIG. 28 or FIG. It is.
- the AGC circuit as the signal amplification unit is controlled to operate in conjunction with the light amount control unit such as the chopper 16, the lamp current control unit 18, or the aperture control unit 24.
- the interlock operation is controlled so that, for example, the AGC circuit as the signal amplifying unit functions only after the light output control unit reaches the maximum output light amount.
- the light quantity control unit is set to control the maximum light quantity (for example, the dimming blades are fully opened), and even when the light quantity reaches the maximum, the AGC is controlled to function only when the screen is dark. Thereby, the range of light quantity control can be widened.
- the AGC auto gain control
- the AGC in these configurations is performed by the signal amplification unit in each of the luminance signal processing unit 434 and the color signal processing unit 435 in FIG. 4, FIG. 28 or FIG. 32 during normal image observation. This is done by an AGC circuit (not shown).
- AGC at the time of spectral image observation is performed by an AGC circuit (for example, amplifiers 32a to 32c in FIG. 8 are variable amplifiers) which is a signal amplifying unit in the matrix calculation unit 436 in FIG. 4, FIG. 28 or FIG. It is.
- a normal image and a spectral image are displayed simultaneously (spectral images are estimated from RGB and can be displayed simultaneously), the amount of light may have been reduced in consideration of CCD saturation. For example, a normal image may have reduced light intensity to reduce CCD saturation. In this case, the normal image is naturally dark.
- spectral images are adjusted within an appropriate dynamic range so that details can be observed. Therefore, when displaying the normal image and the spectral image at the same time, the normal image remains dark if it is left as it is. Therefore, the brightness of the normal image is adjusted for simultaneous display and output. Amplification of image output is performed by electrically increasing the gain with an AGC circuit that is a signal amplifier. Thereby, the image quality at the time of simultaneous display can be improved.
- FIG. 35 is applied to the configuration of the living body observation apparatus according to the eighth embodiment of the present invention.
- the broadband luminance signal is weighted and added to the luminance component of the spectral image to improve the brightness and the SZN ratio.
- an electronic endoscope apparatus 100 includes an endoscope 101, an endoscope apparatus body 105, and a display monitor 106.
- the endoscope apparatus main body 105 mainly includes a light source section 41, a control section 42, and a main body processing apparatus 43.
- the main body processing device 43 is provided with a CCD drive circuit 431 for driving the CCD 21, and has a signal circuit system for obtaining a normal image and a signal circuit system for obtaining a spectral image.
- the signal circuit system for obtaining a normal image is used to sample the signal obtained by the CCD 21. And SZH circuits 433a to 433c that generate RGB signals, and a color signal processing unit 435 that is connected to the outputs of the SZH circuits 433a to 433c and generates color signals.
- a matrix calculation unit 436 is provided at the output of the SZH circuits 433a to 433c, and a predetermined matrix calculation is performed on the RGB signals.
- the output of the color signal processing unit 435 and the output of the matrix calculation unit 436 are connected via a switching unit 450 to a white balance processing (hereinafter referred to as WB) circuit 451, a gamma correction circuit 452, and a color conversion circuit (1) 4 53 ⁇ signal, R— ⁇ signal, ⁇ — ⁇ signal are generated, and further emphasized luminance signals YEH, R— ⁇ signal, ⁇ — ⁇ signal described later are generated, and the color conversion circuit (2 ) 455 and sent to the display monitor 106 as R, G, ⁇ output.
- WB white balance processing
- a broadband luminance signal generator 444 is provided, and C When the output signal power SZN ratio of the CD deteriorates, a broadband luminance signal (YH) is generated, and weighted addition with the luminance component Y of the spectral image is performed.
- YH broadband luminance signal
- the weighting circuit (445, 446 ) Weighting is performed by the adding unit 447, and the enhancement circuit 454 corrects the outline of the luminance signal after the addition. That is, the broadband luminance signal generation unit 444, the weighting circuits 445 and 446, and the addition unit 447 constitute an image quality adjustment unit.
- the contour-corrected luminance signal YEH is supplied to the color conversion unit (2) 455, and is then converted again to RGB by the color conversion unit (2) 455 and output to the display monitor 106.
- the weighting coefficients in the above weighting circuits (445, 446) can be switched according to the observation mode and the number of connected CCD pixels, and can be set arbitrarily within the range where there is no problem with contrast degradation of the spectral image. For example, if the weighting coefficient of the weighting circuit 445 is ⁇ and the weighting coefficient of the weighting circuit 446 is
- the effects of the configuration of the eighth embodiment can improve the brightness and SZN ratio without acquiring multiple images, and the weighting coefficient can be optimized depending on the type of connected CCD. Therefore, depending on the number of pixels and spectral characteristics of each CCD, there is no influence of contrast deterioration, and optimization is possible within a range.
- FIG. 36 or FIG. 37 is applied to the configuration of the living body observation apparatus according to the ninth embodiment of the present invention.
- the ninth embodiment is intended to improve the SZN ratio.
- this method of improving the SZN ratio ratio involves illumination light irradiation several times (for example, n times, where n is 2) in one field (one frame) of a normal image (general color image).
- Ignition intensity may be changed at each time. It is indicated by 10 to In in Fig. 2. This can be realized only by controlling the illumination light.
- This will reduce the intensity of each irradiation, and each of the RGB signals will be Saturation can be suppressed.
- the image signal divided several times is added n times later. This can increase the signal component and improve the SZN ratio.
- connection cable to the CCD is connected with a circuit with high drive capability. It is necessary to drive, and technical difficulty is high.
- the CCD drive circuit 431 is moved from the main body processing unit (processor) 43 to the endoscope 101 side, and the CCD drive circuit 4
- connection cable between 31 and CCD 21 is designed to be as short as possible.
- the CCD drive circuit 431 is on the endoscope 101 side, the drive capability required for the drive circuit can be set low. In other words, even if drive capacity is low, it is advantageous in terms of cost.
- the CCD drive circuit 431 has a built-in force in the main body processing device (processor) 43 as compared with the configuration of FIG. Waveform shaping circuit provided near the CCD at the tip of the endoscope 101
- the waveform is shaped at 450 and the CCD 21 is driven.
- the CCD drive pulse from the main body processing device 43 can be output with a waveform close to a sine wave, so the EMC characteristics are good. That is, an unnecessary radiated electromagnetic field can be suppressed.
- the noise suppression circuit is provided in the matrix calculation unit 436 or an input unit in front of the matrix calculation unit 436 necessary for spectral image observation.
- the wavelength band is limited, so the amount of illumination light may be smaller than during normal image observation.
- the brightness deficiency due to the small amount of illumination can be corrected electrically by amplifying the captured image, but simply increasing the amplification factor by the AGC circuit will cause noise in dark image parts. It will be a noticeable image. Therefore, by passing through a noise suppression circuit, noise in the dark area is suppressed, and a decrease in contrast in the bright area is reduced.
- the noise suppression circuit is described in FIG. 5 of Japanese Patent Application No. 2005-82544.
- the noise suppression circuit 36 shown in FIG. 38 is a circuit applied to a biological observation apparatus as shown in FIG. 32 that handles frame-sequential R, G, and B image data. Frame sequential R, G, B image data is input.
- the noise suppression circuit 36 includes a filter processing unit 81 that performs filter processing using a plurality of spatial filters on image data captured by a CCD that is an imaging unit, and brightness in a local region of the image data.
- the average pixel value calculation unit 82 as the brightness calculation means to be calculated, and the output of the filter processing unit 81 is weighted according to the output of the filter processing unit 81 and Z or the output of the average pixel value calculation unit 82
- the p filter coefficients in the filter processing unit 81 are switched for each of R, G, and B input image data, and are read from the filter coefficient storage unit 84 and set in the filters Al to Ap. .
- the average pixel value calculation unit 82 calculates the average value Pav for the pixel values of the small region (local region) of n X n pixels of the same input image data used in the spatial filter processing by the filter processing unit 81. According to the average value Pav and the value of the filter processing result in the filter processing unit 81 Then, the weighting coefficient W is read from the lookup table (LUT) 86 and set in the weighting circuits Wl, W2,.
- LUT lookup table
- noise is suppressed while avoiding a decrease in the contrast of the image data by changing the weighting of the noise suppression processing by the spatial filter according to the brightness of the local region of the image data.
- FIG. 4, FIG. 28 or FIG. 32 is applied to the living body observation apparatus of Example 11 of the present invention.
- a spatial frequency filter (LPF) (not shown) is provided in the matrix calculation unit 436, but this spatial frequency characteristic is controlled to be slightly changed when displaying a spectral image. For example, control is performed to widen the band.
- the control unit 42 changes the setting of the spatial frequency filter characteristics (LPF characteristics) provided in the matrix calculation unit 436 in the main body processing device (processor) 43. Specifically, the control unit 42 Performs control to change the band characteristics of the LPF to wide band during image observation. Such control operation is described in Fig. 4 of Japanese Patent Application No. 2004-250978.
- the operator can perform endoscopy by inserting the insertion portion 102 of the endoscope 101 into the body cavity of the patient.
- the surgeon operates the V and mode switching switches (not shown) when he wants to observe in more detail the condition of blood vessels running on the surface of the tissue to be examined such as the affected area in the body cavity.
- control unit 42 changes the operation mode of the light source unit 41 and the main body processing device 43 to the setting state of the spectral image observation mode.
- control unit 42 controls the light amount so as to increase the light amount for the light source unit 41, and the spatial frequency L PF in the matrix calculation unit 436 for the main body processing device 43.
- the bandwidth characteristics of the image are changed so as to be wideband, and the switching unit 439 is controlled to switch to the spectral image processing system including the matrix calculation unit 436.
- the conventional simultaneous color imaging function is maintained in the normal image observation mode, and the coefficients of each part in the main body processing device 43 are also in the spectral image observation mode.
- the processing characteristics such as changing the settings such as, the observation function in the spectral image observation mode can be sufficiently ensured.
- NBI characters are displayed during spectral image observation.
- a mark such as ⁇ may be displayed at one of the four corners of the monitor instead of the character display.
- An LED is simply provided on the operation panel, and it is turned off during normal image observation and turned on during spectral image observation.
- an LED lighting unit 91 is provided in the vicinity of the NBI character, and is turned off during normal image observation and turned on during spectral image observation.
- an LED is provided so that the NBI character itself 92 is lit, or the character peripheral portion 93 other than the NBI character is lit, and is turned off during normal image observation and lit during spectral image observation. To do.
- an LED is provided so that the NBI character itself 94 is lit, or the character peripheral part 95 other than the NBI character is lit, green is turned off during normal image observation, white light is emitted during spectral image observation, etc. Lights with different colors.
- a biological observation device is assembled by a system with multiple devices and is displayed on the controller screen for centralized control.
- the spectral image observation mode switching switch ie, the NBI switch
- the NBI switch itself is displayed in black characters during normal image observation and in reverse characters during spectral image observation.
- FIG. 42 is a block diagram showing a configuration of the biological observation apparatus according to Example 13 of the present invention.
- FIG. 42 is a block diagram of the simultaneous electronic endoscope apparatus 100. As shown in FIG.
- the endoscope apparatus main body 105 mainly includes a light source section 41, a control section 42, and a main body processing apparatus 43. Descriptions of the same parts as in FIG. 4 of the first embodiment will be omitted, and different parts from FIG. 4 will be mainly described.
- the main body processing device 43 is connected to the endoscope 101 via the connector 11, similarly to the light source unit 41.
- the main body processing device 43 is provided with a CCD drive circuit 431 for driving the CCD 21. It also has a color signal processing system as a signal circuit system for obtaining normal images.
- the color signal processing system is connected to the CCD 21, performs sampling of the signal obtained by the CCD 21, and generates RGB signals.
- Color signals R ′, G ′, and B are sent from the color signal processing unit 435 to the common circuit unit (451 to 455) through the switching unit 450.
- the signal processing of these circuits 451 to 455 is signal processing for displaying on the display monitor 106 an imaging signal that is a color image signal and a spectral signal generated from the imaging signal. Is a process that can be shared by both signal processing and spectral signal processing.
- a common circuit unit (451 to 455) that shares a circuit for performing processing will be described.
- the common circuit section (451 to 455) is configured so that WB processing, ⁇ processing, and enhancement processing can be shared by the normal observation image and the spectral observation image.
- the following circuits a) to c) are used in common when generating the normal observation image and the spectral observation image.
- a) WB circuit 451, b) gamma correction circuit 452, c) enhancement circuit 454 are shared.
- the output of the color adjustment unit 440 and the output of the matrix calculation unit 436 are supplied to the WB circuit 451, the ⁇ correction circuit 452, and the color conversion circuit (1) 453 via the switching unit 450, and the ⁇ signal, R- ⁇ Signal, ⁇ — ⁇ signal is generated, and further emphasized luminance signals YEH, R— ⁇ signal, ⁇ — ⁇ signal, which will be described later, are generated and supplied to the color conversion circuit (2) 455, and R, G, ⁇ Display as output Sent to monitor 106.
- the spectral images (Fl, F2, F3) from the matrix calculation unit 436 are generated by the following procedure.
- the images obtained by integrating and color-adjusting the spectral images (F1 to F3) and the normal observation images (R ′, G ′,) ′) are shown on the front panel and keyboard at the switching unit 450. Selected with no mode switch.
- the output from the switching unit 450 is processed by the WB circuit 451 and the ⁇ correction circuit 452, and then the luminance signal ( ⁇ ) and the color difference signal (R— ⁇ — Is converted to ⁇ ).
- the enhancement circuit 454 performs contour correction on the converted luminance signal ⁇ .
- the color conversion unit (2) 455 converts the image data into RGB again and outputs it to the display monitor 106.
- ⁇ ⁇ enhancement processing can be used in common, and the spectral image (Fl, F2, F3) from the matrix calculation unit 436 is output as G—B—B, so the color conversion unit (1) Since the luminance signal of the spectral image converted at 453 contains a lot of ⁇ components, It is possible to emphasize the surface blood vessel image obtained from the image with emphasis.
- Example 13 in Fig. 42 shows a configuration in which WB, y correction, and enhancement processing are shared mainly between the normal observation image system and the spectroscopic observation image system. Without being limited thereto, it may be a configuration in which at least one of WB, gradation conversion, and spatial frequency enhancement processing is shared.
- FIG. 43 is a block diagram showing the configuration of the biological observation apparatus according to Embodiment 14 of the present invention. Since Example 14 is almost the same as Example 13, only differences from Example 13 will be described, and the same components will be assigned the same reference numerals and description thereof will be omitted.
- This embodiment is mainly different from the thirteenth embodiment in the light source unit 41 that controls the amount of illumination light.
- the amount of light emitted from the light source unit 41 is controlled not by the chopper but by the current control of the lamp 15.
- the lamp 15 shown in FIG. 43 is provided with a current control unit 18 as a light amount control unit.
- control unit 42 controls the current flowing through the lamp 15 so that none of the RGB color image signals are saturated.
- the current used for light emission in the lamp 15 is controlled, so that the amount of light changes according to the magnitude of the current.
- the present embodiment as in the thirteenth embodiment, it is possible to obtain a spectral image in which the blood vessel pattern is clearly displayed. Further, the present embodiment has an advantage that the control method is simpler than the light amount control method using the chopper as in the thirteenth embodiment.
- FIG. 44 is a block diagram showing the configuration of the biological observation apparatus according to Embodiment 15 of the present invention.
- the diagram showing the charge storage time of the CCD in the embodiment of FIG. 44 is the same as FIG. Since the fifteenth embodiment is almost the same as the thirteenth embodiment, only differences from the thirteenth embodiment will be described.
- This embodiment is mainly different from the thirteenth embodiment in the light source unit 41 and the CCD 21.
- the CCD 21 is provided with the color filter shown in FIG. 6 and a color signal is generated by this color filter!
- the illumination light is 1
- the so-called frame-sequential method is used in which color signals are generated by illuminating in the order of RGB during the frame period.
- the light source unit 41 in the present embodiment is provided with a diaphragm 25 that performs dimming on the front surface of the lamp 15, and on the further front surface of the diaphragm 25, R, G, and B are sequentially arranged.
- an RGB rotation filter 23 that rotates, for example, once in one frame is provided.
- the aperture 25 is connected to an aperture control unit 24 as a light amount control unit, and restricts the luminous flux to be transmitted among the luminous flux emitted from the lamp 15 in accordance with a control signal from the aperture control unit 24. Dimming is possible by changing the amount of light.
- the RGB rotation filter 23 is connected to the RGB rotation filter control unit 26 and rotates at a predetermined rotation speed.
- the operation of the light source unit in this embodiment is as follows.
- the luminous flux output from the lamp 15 is limited to a predetermined amount of light by the aperture 25, and the luminous flux transmitted through the aperture 25 passes through the RGB rotation filter 23 to Is output from the light source unit as R'G'B illumination light at each time.
- Each illumination light is reflected within the subject and received by the CCD 21.
- Signals obtained by the CCD 21 are distributed by a switching unit (not shown) provided in the endoscope apparatus main body 105 according to the irradiation time, and input to the SZH circuits 433a to 433c, respectively.
- the illumination light is irradiated from the light source unit 41 through the R filter, the signal obtained by the CCD 21 is input to the SZH circuit 433a. Since other operations are the same as those in the first embodiment, they are omitted here.
- the fifteenth embodiment as in the thirteenth embodiment, a spectral image in which a blood vessel pattern is clearly displayed can be obtained. Further, unlike the thirteenth embodiment, the fifteenth embodiment can enjoy the advantages of the so-called frame sequential method. This merit is, for example, the one described in Fig. 34.
- the illumination light quantity (light quantity from the light source unit) is controlled to adjust in order to avoid saturation of the RGB color signal.
- the fifteenth embodiment employs a method of adjusting the electronic shutter of the CCD 21.
- CCD21 incident within a certain time Charges proportional to the light intensity accumulated are accumulated, and the charge amount is used as a signal. A force equivalent to this accumulation time is called an electronic shutter.
- the electronic shutter By adjusting the electronic shutter with the CCD drive circuit 431, the amount of accumulated charge, that is, the signal amount can be adjusted.
- a similar spectral image can be obtained by obtaining an RGB color image with the charge accumulation time sequentially changed for each frame.
- the illumination light amount control by the diaphragm 25 is used to obtain a normal image, and when obtaining a spectral image, the electronic shutter is changed to change the R, G, B color signals. It is possible to avoid saturation of.
- FIG. 45 and 46 relate to the living body observation apparatus according to the sixteenth embodiment of the present invention
- FIG. 45 is a diagram showing the arrangement of color filters
- FIG. 46 is a diagram showing the spectral sensitivity characteristics of the color filters.
- the color filter provided in the CCD 21 is different from that in the first embodiment.
- an RGB primary color filter is used as shown in FIG. 6, whereas in this embodiment, a complementary color filter is used.
- the complementary color filter array is composed of G, Mg, Ye, and Cy elements.
- Fig. 46 shows the spectral sensitivity characteristics when the complementary color filter is used, the target bandpass filter, and the characteristics of the pseudo bandpass filter obtained by the above equations (27) to (33). Show.
- the SZH circuit shown in Fig. 4 and Fig. 42 is not for R 'G ⁇ B, but for G ⁇ Mg ⁇ Cy ⁇ Ye! Needless to say it will be done! /.
- the present embodiment as in the first embodiment, it is possible to obtain a spectral image in which the blood vessel pattern is clearly displayed. Further, in this embodiment, it is possible to enjoy the advantages of using the complementary color filter.
- a new pseudo bandpass filter can be created by the operator himself / herself at other timings in the clinic and applied to the clinic. That is, in Example 1, the control unit 42 in FIGS. 4 and 42 can calculate and calculate matrix coefficients. Provide a design section ( ⁇ not shown) that can be used.
- a pseudo bandpass filter suitable for obtaining a spectral image desired by the operator can be obtained by inputting conditions via the keyboard provided in the endoscope apparatus main body 105 shown in FIG.
- the correction coefficient matrix “K” in Eqs. (20) and (32) is used.
- Set the final matrix coefficient corresponding to each element of the matrix “ ⁇ '” in equations (21) and (33)) to the matrix calculation unit 436 in FIGS. 4 and 42. Therefore, it can be applied immediately to clinical practice.
- Figure 47 shows the flow until application. This flow will be described in detail.
- the operator inputs information about a target bandpass filter (for example, a wavelength band) via a keyboard or the like.
- a target bandpass filter for example, a wavelength band
- the matrix “ ⁇ ” is calculated together with the characteristics of the light source color filter already stored in a predetermined storage device etc., and as shown in FIG. 46, along with the characteristics of the target bandpass filter,
- the calculation result (pseudo bandpass filter) of the matrix “ ⁇ '” is displayed on the monitor as a force spectrum diagram.
- the newly created matrix “ ⁇ ,” is to be used, it is set, and this matrix “ ⁇ '” is used to set the actual internal vision. A mirror image is generated.
- the newly created matrix “ ⁇ ′” is stored in a predetermined storage device and can be used again according to a predetermined operation by the operator.
- the operator can generate a new bandpass filter based on his / her own experience, etc., without being bound by the existing matrix “ ⁇ '”, which is particularly effective when used for research purposes. is there.
- the biological observation apparatus of the present invention is particularly useful when applied to an electronic endoscope apparatus for acquiring biological information and observing biological tissue in detail.
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Abstract
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Priority Applications (6)
Application Number | Priority Date | Filing Date | Title |
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CN2006800162245A CN101175435B (zh) | 2005-05-13 | 2006-03-07 | 生物体观测装置 |
AU2006245248A AU2006245248B2 (en) | 2005-05-13 | 2006-03-07 | Biometric instrument |
US11/914,347 US20090091614A1 (en) | 2005-05-13 | 2006-03-07 | Biological observation apparatus |
EP06715358A EP1880659A4 (en) | 2005-05-13 | 2006-03-07 | BIOMETRIC INSTRUMENT |
BRPI0610260-3A BRPI0610260A2 (pt) | 2005-05-13 | 2006-03-07 | aparelho de observação biológica |
CA002606895A CA2606895A1 (en) | 2005-05-13 | 2006-03-07 | Biological observation apparatus |
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JP2005-141534 | 2005-05-13 | ||
JP2005141534A JP4500207B2 (ja) | 2005-05-13 | 2005-05-13 | 生体観測装置 |
JP2005-154372 | 2005-05-26 | ||
JP2005154372A JP2006325974A (ja) | 2005-05-26 | 2005-05-26 | 生体観測装置 |
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CN105848553A (zh) * | 2013-12-25 | 2016-08-10 | 奥林巴斯株式会社 | 光扫描型观察装置 |
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CA2793449A1 (en) | 2010-03-17 | 2011-09-22 | Haishan Zeng | Rapid multi-spectral imaging methods and apparatus and applications for cancer detection and localization |
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JP5554253B2 (ja) * | 2011-01-27 | 2014-07-23 | 富士フイルム株式会社 | 電子内視鏡システム |
JP5335017B2 (ja) * | 2011-02-24 | 2013-11-06 | 富士フイルム株式会社 | 内視鏡装置 |
JP5404968B1 (ja) * | 2012-03-30 | 2014-02-05 | オリンパスメディカルシステムズ株式会社 | 内視鏡装置 |
JP5362149B1 (ja) * | 2012-03-30 | 2013-12-11 | オリンパスメディカルシステムズ株式会社 | 内視鏡装置 |
JP5789280B2 (ja) * | 2013-05-14 | 2015-10-07 | 富士フイルム株式会社 | プロセッサ装置、内視鏡システム、及び内視鏡システムの作動方法 |
US20150265202A1 (en) * | 2014-03-20 | 2015-09-24 | Olympus Medical Systems Corp. | Method for collecting duodenal juice |
JP6596502B2 (ja) * | 2015-10-08 | 2019-10-23 | オリンパス株式会社 | 内視鏡装置 |
JP6654117B2 (ja) * | 2016-08-31 | 2020-02-26 | 富士フイルム株式会社 | 内視鏡システム及び内視鏡システムの作動方法 |
JP7073145B2 (ja) * | 2018-03-12 | 2022-05-23 | ソニー・オリンパスメディカルソリューションズ株式会社 | 医療用調光制御装置、および医療用調光制御装置の作動方法 |
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- 2006-03-07 EP EP11000358.9A patent/EP2332460B1/en not_active Not-in-force
- 2006-03-07 RU RU2007146448/14A patent/RU2378977C2/ru not_active IP Right Cessation
- 2006-03-07 US US11/914,347 patent/US20090091614A1/en not_active Abandoned
- 2006-03-07 WO PCT/JP2006/304388 patent/WO2006120795A1/ja active Application Filing
- 2006-03-07 EP EP06715358A patent/EP1880659A4/en not_active Withdrawn
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Also Published As
Publication number | Publication date |
---|---|
EP1880659A1 (en) | 2008-01-23 |
AU2006245248A1 (en) | 2006-11-16 |
EP1880659A4 (en) | 2010-05-05 |
AU2006245248B2 (en) | 2010-02-18 |
BRPI0610260A2 (pt) | 2010-06-08 |
KR100988113B1 (ko) | 2010-10-18 |
US20090091614A1 (en) | 2009-04-09 |
RU2378977C2 (ru) | 2010-01-20 |
EP2332460A1 (en) | 2011-06-15 |
RU2007146448A (ru) | 2009-06-20 |
KR20080002945A (ko) | 2008-01-04 |
EP2332460B1 (en) | 2013-06-05 |
CA2606895A1 (en) | 2006-11-16 |
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