Abstract: An image with an expanded depth of field is more effectively acquired while reducing the manufacturing cost, without enlarging the apparatus. Provided is an endoscope system including: an objective optical system that is provided at an insertion portion tip and that acquires a subject image; an optical path division means for dividing the subject image into two optical images with different focuses; an imaging element that forms the two optical images with different focuses at the same time to acquire two images; an image correction means that corrects the two images acquired by the imaging element so that differences other than the focuses become substantially the same; and an image combination processing unit that selects an image with a relatively high contrast in predetermined corresponding areas between the two images corrected by the image correction means to generate a combined image.

Abstract: An image processing device includes a normal light image acquisition section that acquires a normal light image, the normal light image being an image that includes information within a wavelength band of white light, a special light image acquisition section that acquires a special light image, the special light image being an image that includes information within a specific wavelength band, a normal light motion vector information calculation section that calculates normal light motion vector information based on a feature quantity included in the normal light image, the normal light motion vector information indicating a motion vector between a plurality of normal light images, and a noise reduction section that reduces an amount of noise included in the special light image based on the normal light motion vector information calculated by the normal light motion vector information calculation section.

Abstract: In one embodiment of the invention, an apparatus is disclosed including an image sensor, a color filter array, and an image processor. The image sensor has an active area with a matrix of camera pixels. The color filter array is in optical alignment over the matrix of the camera pixels. The color filter array assigns alternating single colors to each camera pixel. The image processor receives the camera pixels and includes a correlation detector to detect spatial correlation of color information between pairs of colors in the pixel data captured by the camera pixels. The correlation detector further controls demosaicing of the camera pixels into full color pixels with improved resolution. The apparatus may further include demosaicing logic to demosaic the camera pixels into the full color pixels with improved resolution in response to the spatial correlation of the color information between pairs of colors.

Abstract: A light source apparatus includes: a first light source unit including a plurality of light sources arranged therein, the plurality of light sources each emitting illuminating light in a first wavelength band; a second light source unit including a plurality of light sources arranged therein, the plurality of light sources each emitting illuminating light in a second wavelength band; an in-light source light guiding channel that guides the light emitted from the first light source unit and the light emitted from the second light source unit to a proximal end-side input end of a light guiding channel in an endoscope; and a light source control section that, based on endoscope information from an endoscope information storing section, divides the plurality of light sources in the first light source unit into a first light source group, light from which enters a vicinity of an optical axis of the proximal end-side input end of the light guiding channel in the endoscope, and a second light source group in a perip

Abstract: An image processing device includes a special light image acquisition section that acquires an image including an object image that includes information in a specific wavelength band as a special light image, an attention area detection section that detects an attention area based on a feature quantity of each pixel of the special light image, a disappearance determination section that determines whether or not the attention area has disappeared from a display target area based on a detection result for the attention area, the display target area being an area displayed on an output section, a guide information generation section that generates guide information about the attention area that has disappeared based on a determination result of the disappearance determination section, and an output control section that controls output of information including the guide information generated by the guide information generation section.

Abstract: An electronic endoscope apparatus includes a connection unit for selectively connecting a plurality of machine types of electronic endoscopes which use different color information obtainment methods and a plurality of replacement tables which are provided for the plurality of machine types of electronic endoscopes respectively, and each of which stores a correspondence between values representing colors which can be obtained by each of the electronic endoscopes by photographing an observation object and values representing the true colors of the observation object. The electronic endoscope apparatus distinguishes the machine type of the electronic endoscope and replaces the values of obtained colors by using the replacement table for the distinguished machine type. Further, the electronic endoscope apparatus stores setting information for each purpose of examination, and further performs image processing, based on selected setting information, on the image of which the values of the colors have been replaced.

Abstract: In an oxygen saturation level measurement mode, a color image sensor images an internal body portion alternately irradiated with measurement light and normal light. A normal image is produced from image data obtained under irradiation with the normal light. An oxygen saturation level is calculated from image data obtained under irradiation with the measurement light. Based on the oxygen saturation level, a hyperoxic region and a hypoxic region are determined in the normal image. A color balance process and a color enhancement process are applied to the hyperoxic region to improve visibility of depressions and projections of internal body tissue and a blood vessel pattern. A gain process is applied to the hypoxic region to make distinct color variations according to the degree of the oxygen saturation level.

Abstract: In an endoscope apparatus, a first color separation section separates an image picked up by an image pickup section into a first luminance signal and a first color difference signal, then a first color conversion section and a second color separation section convert the first luminance signal and the first color difference signal to first three primary color signals and second three primary color signals respectively, a signal intensity ratio calculation circuit calculates a signal intensity ratio among the first three primary color signals, matrix coefficients of the second color separation section are changed based on the calculated signal intensity ratio and the second color separation section converts the first luminance signal and the second color difference signal to the second three primary color signals.

Abstract: In a processor of a wireless image transmission system that transmits, by radio communication, an image signal obtained by converting an image obtained by an endoscope apparatus, a communication state detection unit monitors a communication state of radio communication. An editing unit edits the image signal according to a mode in which the endoscope apparatus obtains an image when the deterioration of a communication state is detected by the communication state detection unit. A transmission unit transmits the image signal output from the editing unit to a receiver.

Abstract: The invention relates to a system for visualizing characteristic tissue with a colorant in a surgical region. The system contains a detection unit which detects light from at least one object point in the surgical region. The system has a computer unit which is connected to the detection unit and drives a visualization unit which displays an image of an area in the surgical region. The computer unit determines the color coordinate in a color space with respect to the light from a point from the object point in the surgical region. Depending on the position of the color coordinate determined with respect to the object point, the computer unit calculates a color coordinate information (“0”, “1”) for controlling the visualization unit by comparing information concerning the determined color coordinate of the object point with information concerning a characteristic reference color coordinate.

Abstract: This is an endoscope apparatus which has an endoscope which picks up an image of a sample using a solid state image pickup element and outputs an image pickup signal, and a processor which processes the above-mentioned image pickup signal, generates HDTV and SDTV serial digital video signals, switches one side of those selectively, and performs a serial output, in which the serial digital video signal switched selectively by the above-mentioned processor is output through a first connector, the above-mentioned processor is equipped with a discrimination signal generating section which is linked with selection switching of the above-mentioned HDTV or SDTV serial digital video signal to generate an HDTV/SDTV discrimination signal which can discriminate the above-mentioned HDTV or SDTV serial digital video signal, and the discrimination signal is output through a second connector different from the above-mentioned first connector.

Abstract: In an endoscope apparatus, inside an endoscope, color correction processing is performed that performs multiplication between a color correction coefficient that is set based on a plurality of numerical apertures with respect to a plurality of different wavelengths included in a wavelength band of illuminating light of a light guide that is mounted in the endoscope and that transmits light-source light from a light source apparatus, and at least one of B, G and R signals generated by the signal processing apparatus.

Abstract: An endoscope system includes an endoscope objective optical system that acquires two optical images with different focus positions, an image pickup device that picks up the two optical images to acquire two image signals, an image synthesis processing section that makes a comparison in contrast between the two image signals for each spatially identical pixel region and selects a pixel region having relatively higher contrast to thereby synthesize the two image signals into one image, and a focus switchover mechanism that moves a position of a focus switchover lens provided for the endoscope objective optical system and selectively switches a focus of the endoscope objective optical system to one of two observation regions of proximity observation and remote observation, in which the image synthesis processing section synthesizes two images in each of the respective observation regions of the proximity observation and the remote observation.

Abstract: Certain embodiments provide an image reading apparatus including: a monochrome CCD sensor including a first photo-diode array; plural color CCD sensors each including a second photodiode array; an AD converter configured to apply analog-to-digital conversion to each of analog outputs from the second photodiode array and the first photodiode array; a delay processing unit configured to delay at least one of color image data of plural colors from the AD converter and interpolate, with delayed any one or more of the color image data, a blank of image data that is to be read on a line in a sub-scanning direction; and an inter-line correction unit configured to correct, by the intervals and a set reduction magnification, a positional deviation in the sub-scanning direction between the monochrome image data and the color image data, respective timings of which are aligned on the line by the delay processing unit.

Abstract: An endoscope having a color space conversion circuit performs a matrix calculation according to RGB signals and matrix data respectively corresponding to signals in wavelength ranges is provided with a wavelength memory section having a default data memory area, which stores a default value representing a wavelength range selected by a wavelength selection section, and a changed-wavelength saving area that stores a wavelength range selected by the wavelength selection section after changed from the wavelength range represented by the default value. Subsequently, at least a part of the wavelength range stored in the changed-wavelength saving area is rewritten by a reset section into the default value stored in the default data memory area.

Abstract: A method capable of obtaining a fluorescence image and a background image with a simple configuration. A color image is obtained, when excitation light is emitted on a subject, by imaging excitation light reflected from the subject and fluorescence emitted from the subject. Thereafter, an estimated spectral image that includes a background image representing the excitation light and a fluorescence image representing the fluorescence is generated by allocating a wavelength component of the excitation light and a wavelength component of the fluorescence included in the obtained color image to different primary color components.

Abstract: An endoscope system, including: an endoscope for picking up an image of a subject and outputting an image pickup signal of the image; an external processor having a post-signal processing circuit which processes the image pickup signal inputted from the endoscope and generates a video signal that can be outputted to a monitor; and an output detecting circuit for detecting the presence or absence of an output of the image pickup signal and the presence or absence of an output of the video signal.

Abstract: There are provided an image processing apparatus, an endoscope apparatus, and a color balance adjusting method capable of obtaining a good observation image. An image processing apparatus of the invention includes: an image signal input unit for inputting an image signal of a subject image picked up by an image pickup unit, the subject image including at least an image of a color balance adjustment tool; a control unit for calculating a value of coefficient to change brightness value of the image signal, based on a correction value to correct characteristic variation of the color balance adjustment tool, the correction value being shown in a correction value display portion included by the color balance adjustment tool, and a brightness value of the image of the color balance adjustment tool; and a color balance process unit for performing color balance adjustment by changing the brightness value of the image signal based on the coefficient value.

Abstract: Tissue information of a desired deep portion of a biological tissue based on a spectral image obtained from signal processing is adjusted to image information in a color tone suitable for observation. Outputs of a matrix computing section 436 are respectively connected to integrating sections 438a to 438c, and after integrating computation is performed for them, color conversion computation is performed for respective spectral image signals ?F1 to ?F3 in a color adjusting section 440, spectral color channel image signals Rch, Gch and Bch are created from the spectral image signals ?F1 to ?F3, and images of the spectral color channel images Rch, Gch and Bch are sent to a display monitor 106 via a switching section 439.

Abstract: A method for displaying images includes adjusting at least one characteristic of an image from a first imaging device of an endoscope to match at least one corresponding characteristic of an image from a second imaging device of the endoscope. The at least one characteristic may be one or more of color, contrast and brightness. An endoscopic system includes an endoscope including a first imaging device and a second imaging device, and a display device that displays an image from the first imaging device of the endoscope and an image from the second imaging device of the endoscope, wherein the images are sized so that an object, when placed at the same distance from the imaging devices, appears to have about the same size in the images.

Abstract: The image processing device includes: a first image acquisition section that acquires a first image, the first image being an image that includes an object image including information within a wavelength band of white light; a second image acquisition section that acquires a second image, the second image being an image that includes an object image including information within a specific wavelength band; a candidate attention area detection section that detects a candidate attention area based on a feature quantity of each pixel within the second image, the candidate attention area being a candidate for an attention area; a reliability calculation section that calculates reliability that indicates a likelihood that the candidate attention area is the attention area; and a display mode setting section that performs a display mode setting process that sets a display mode of an output image corresponding to the reliability calculated by the reliability calculation section.

Abstract: Systems and methods for combining tomographic images with human vision. The systems preferably include a first assembly located proximal to an object to be imaged and a second assembly remote from the target. The first assembly is preferably able to collect a tomographic image from a target object and superimpose that tomographic image onto a direct view of the target object. The first assembly also includes components that allow the transmission of the tomographic image to the remote assembly. At the remote location, a highly trained expert may interact with the captured image by placing electronic markers on the image via an electronic interface. The captured image plus electronic marker are then preferably transmitted back to the local site via a second transmitter-receiver. The local user may use the electronic marker to guide his actions during the appropriate task.

Abstract: An endoscope signal processor to which an endoscope having an image pickup device is detachably connected has a phase-locked loop circuit in which a phase comparator compares a phase of a variable clock with that of a reference clock output from the image pickup device to generate a variable clock phase-synchronized with the reference clock. The processor includes a gate section opened or closed to input of the reference clock to the phase comparator, an operation control signal generation section which generates an operation control signal for setting the phase-locked loop circuit in a closed loop operable state during intermittent periods, and a sync timing setting section which synchronizes a timing of starting the generation of the operation control signal with a timing of input of the variable clock to the phase comparator at least within a predetermined time period shorter than the cycle of the variable clock.

Abstract: In one embodiment of the invention, an apparatus is disclosed including an image sensor, a color filter array, and an image processor. The image sensor has an active area with a matrix of camera pixels. The color filter array is in optical alignment over the matrix of the camera pixels. The color filter array assigns alternating single colors to each camera pixel. The image processor receives the camera pixels and includes a correlation detector to detect spatial correlation of color information between pairs of colors in the pixel data captured by the camera pixels. The correlation detector further controls demosaicing of the camera pixels into full color pixels with improved resolution. The apparatus may further include demosaicing logic to demosaic the camera pixels into the full color pixels with improved resolution in response to the spatial correlation of the color information between pairs of colors.

Abstract: An electronic endoscope has a video-scope with an image sensor, and a signal processor that generates digital component video signals from image-pixel signals that are read from the image sensor. The electronic endoscope has, further, a color-reverse detector that determines whether a color-reverse occurs in the digital component video signals, and a color correcting processor that changes color signal data associated with the color-reverse so as to correct the color-reverse when the color-reverse occurs.

Abstract: An image display apparatus according to the present invention includes: a storage unit which stores an image group including a same number of first and second images which have a coincident positional relationship with respect to a subject and are respectively obtained through different image processes; a display unit which displays at least the first image in a display area; an input unit which indicates a display switching area of the first image displayed in the display area; and a display controller which controls the display unit to keep displaying the first image in an image part outside the display switching area and to switch an image part inside the display switching area of the first image to an image part, having a coincident positional relationship with the image part inside the display switching area of the first image with respect to the subject, of the second image.

Abstract: An endoscope signal processing apparatus has a first video signal generating circuit and a second video signal generating circuit which respectively generate a first video signal and a second video signal offering different resolutions depending on a first image capturing device and a second image capturing device respectively which are mounted in an endoscope removably connected to an endoscope connecting portion. The first and second video signals can be selectively output to an exterior through a common video signal output connector.

Abstract: In an endoscope apparatus, a first color separation section separates an image picked up by an image pickup section into a first luminance signal and a first color difference signal, then a first color conversion section and a second color separation section convert the first luminance signal and the first color difference signal to first three primary color signals and second three primary color signals respectively, a signal intensity ratio calculation circuit calculates a signal intensity ratio among the first three primary color signals, matrix coefficients of the second color separation section are changed based on the calculated signal intensity ratio and the second color separation section converts the first luminance signal and the second color difference signal to the second three primary color signals.

Abstract: An electronic endoscope apparatus is provided and includes: a light source that illuminates a subject with white light; a color imaging device that takes an image of the subject illuminated with white light; and a spectral-image forming circuit that operates RGB three color image signals based on an output from the color imaging device and a matrix data to generate an spectral image signal representative of a spectral image in a color at a designated wavelength. The spectral-image forming circuit is adapted to generate spectral image signals representative of spectral images in respective colors at least three wavelengths different from one another.

Abstract: An endoscope spectral image system is provided and includes: an image recording apparatus for recording a color image provided by using a scope; and a processor apparatus, in which spectroscopic characteristic information including a spectroscopic characteristic of CCD is output from the processor apparatus to the image recording apparatus along with color image data. At the image recording apparatus, matrix data in correspondence with the spectroscopic characteristic information is selected to be read from a plurality of matrix data stored in a memory, matrix operation by the matrix data and color image data is carried out at a spectral image-forming circuit, and a spectral image formed by signals of arbitrarily selected wavelength regions is provided.

Abstract: An image-signal generating apparatus comprises a solid-state image pickup device-equivalent load circuit unit including a load approximately equivalent to a solid-state image pickup device such as a charge coupled device, etc. The image-signal generating apparatus further comprises an image-signal generating circuit for generating an image signal corresponding to an output signal output from the solid-state image pickup device through the solid-state image pickup device-equivalent load circuit unit, which is a load to which a driving signal for driving the solid-state image pickup device is applied.

Abstract: A color control algorithm compensates variations in the display system so as to maintain color consistency in the projected images on the screen by constructing a color mapping table of the display system to include effects due to the variations and during image display applications, generating inputs of the color mapping table to include the effects due to the variations in the display system.

Abstract: An endoscope apparatus comprises: an endoscope comprising an imaging device that forms a color image signal of a body to be observed; a storage portion that stores matrix data for forming a spectral image based on the color image signal; a spectral image-forming circuit that conducts matrix calculation based on the color image signal by using the matrix data of the storage portion and forms at least one spectral image signal each of which corresponds to an arbitrarily selected wavelength range; and an amplifier circuit that amplifies said at least one spectral image signal formed by the spectral image-forming circuit.

Abstract: An image obtained by an electronic endoscope apparatus is changed to an image that is appropriate for observation with suppressed halation and fewer dark areas. Halation detection means detects halation of a predetermined level or higher in an image represented by a signal obtained by an imaging device, based on the signal. Light amount adjustment means decreases an amount of light emitted from illumination means to cause the halation to become a predetermined level or lower. Luminance conversion means processes the signal so as to generate a luminance conversion image wherein only a dark area having a predetermined luminance or lower in the image due to the decrease in the amount of the light is changed to have a higher luminance.

Abstract: An electronic endoscope apparatus includes an imaging element and a signal processing unit. The imaging element obtains an image of an observation object, and outputs an image signal of the observation object. The signal processing unit alternately repeats obtainment of a partial image signal using a part of a light receiving area of the imaging element and obtainment of a partial image signal using the remaining part of the light receiving area. The signal processing unit also obtains a whole image signal corresponding to an image of the observation object using a partial image signal obtained in the n-th (n is a natural number) obtainment and a partial image signal obtained in the (n+1)th obtainment. Further, a partial component of the n-th partial image signal is extracted by an extraction unit, and the extracted partial component is added to the (n+1)th partial image signal.

Abstract: A body-insertable apparatus is inserted into a subject and obtains information of an inside of the subject. The body-insertable apparatus includes an illuminating unit that outputs an illumination light to illuminate the inside of the subject; an imaging unit that obtains image information of the inside of the subject which is illuminated by the illuminating unit; a radio transmitting unit that transmits information of the inside of the subject by radio; a clock generating unit that generates a clock for obtainment of the image information by the imaging unit; and a correcting unit that corrects a clock for radio transmission by the radio transmitting unit based on the clock generated by the clock generating unit.

Abstract: An endoscope processor comprising a signal receiver, an average calculator, a difference calculator, an emphasizer, a synthesizer, and an output block is provided. The signal receiver receives an image signal generated by an imaging device. The image signal comprises a plurality of pixel signals. The average calculator calculates a signal average value. The difference calculator calculates a signal difference value. The emphasizer calculates an emphasized value by multiplying the signal difference value by a predetermined gain. The synthesizer generates an emphasized image signal, in which the pixel signal for each pixel is replaced with the sum of the emphasized value for each pixel and the signal average value.

Abstract: An endoscope processor comprising a signal receiver and a standard value calculator is provided. The signal receiver receives an image signal generated based on an optical image captured at a light receiving surface on an imaging device. The image signal comprises a plurality of pixel signals generated by a plurality of pixels according to amounts of received light. A plurality of the pixels are arranged on the light receiving surface. The standard value calculator calculates a standard value using a focused pixel signal and surrounding pixel signals. The surrounding pixel signals are the pixel signals of surrounding pixels. The surrounding pixels surround the focused pixel. The standard value is used for carrying out signal processing on the focused pixel signal.

Abstract: An image generating device includes a first image-information generating unit that generates first image information based on a plurality of pieces of acquired color element information, a color-component detecting unit that detects a predetermined color component based on each piece of color element information, a color-component eliminating unit that eliminates the predetermined color component detected by the color-component detecting unit from a predetermined piece of color element information among the plurality of pieces of color element information, and a second image-information generating unit that generates second color information based on a piece of color element information obtained by eliminating the predetermined color component by the color-component eliminating unit and another piece of color element information.

Abstract: An image processor effects a color conversion appropriate for an image acquisition unit, such as a scope, and improves color reproduction accuracy. The image processor includes a plurality of color conversion sections; an information acquisition section that acquires an index for selecting at least one of the plurality of color conversion sections as a specific color conversion means for applying a color conversion process to an input video signal; and a selection section that selects at least one of the plurality of color conversion sections as the specific color conversion means based on the index, in which the plurality of color conversion sections include a linear color conversion section that applies a color conversion process based on linear conversion to the input video signal. A table conversion section applies a color conversion process to the input video signal, based on nonlinear conversion.

Abstract: A method capable of obtaining a fluorescence image and a background image with a simple configuration. A color image is obtained, when excitation light is emitted on a subject, by imaging excitation light reflected from the subject and fluorescence emitted from the subject. Thereafter, an estimated spectral image that includes a background image representing the excitation light and a fluorescence image representing the fluorescence is generated by allocating a wavelength component of the excitation light and a wavelength component of the fluorescence included in the obtained color image to different primary color components.

Abstract: A color filter array pattern for use in a solid-state imager comprising red sensitive elements located at every other array position, with alternating blue sensitive and green sensitive elements located at the remaining array positions, is disclosed. Since red color is sampled most frequently, the color filter may be part of an in vivo camera system for imaging internal human body organs and tissues.

Abstract: A device, for processing each pixel signal output from a solid-state imaging device, has a determination processor and an interpolation processor. Each pixel is defined as a center pixel of a k×k matrix. The interpolation processor presumes which pixels have the same color as one another in the k×k matrix, according to the plurality of pixel-array patterns, and conducts a pixel interpolation in each case of presumed color arrangement according to the plurality of pixel-array patterns, so as to generate signal groups of presumed interpolation signals of the center pixel. The determination processor determines a pixel-array pattern in the k×k matrix to be a pattern selected from the plurality of pixel-array patterns. One of the signal groups that is generated according to the determined pixel-array pattern is selected as interpolation signals of the center pixel.

Abstract: A diagnosis supporting system acquires a reference image signal of a subject illuminated with visible light and a fluorescent image signal of the subject excited by irradiation with excitation light. The diagnosis supporting system calculates a difference between a brightness level of a pixel in the reference image signal and a brightness level of a pixel in the fluorescent image signal at the corresponding position for target pixels. An observation image signal is generated by converting the pixels in the reference image signal with differences larger than a predetermined value into red pixels. In the case a ratio of the red pixels in the observation image signal is higher than a predetermined level, more pixels become the target pixels to be processed than in the other case.

Abstract: An endoscope processor including a receiver and a correction circuit block is provided. The receiver receives an image signal. The image signal corresponds to a captured subject. The image signal is generated by an imaging device. The image signal comprises a plurality of pixel signals corresponding to a plurality of pixels. A plurality of pixels forms an optical image of the subject. The correction circuit block carries out first signal processing on the pixel signals so that a representative value matches a standard value when the image signal received by the receiver is a fluorescence image signal. The representative value is calculated on the basis of a plurality of chrominance difference values corresponding to a plurality of pixel signals. The fluorescence image signal is generated when the subject is illuminated with excitation light. The excitation light makes an organ fluoresce.

Abstract: An electronic endoscope system, including a scope that outputs a plurality of types of color signals obtained by an imaging device and a processor for processing the signals outputted from the scope. A color conversion matrix in which each element data value is defined such that only a color involved in diagnosis is converted to desired color is stored in a memory of the scope or in a memory of the processor. The processor includes at least one multiplier that multiplies the plurality of types of color signals outputted from the scope by coefficients, each provided for each color signal, a coefficient setting means (microcomputers) for setting each element data of the color conversion matrix read out from the memory in the multiplier as the coefficients, and at least one adder that adds up signals outputted from the multiplier.

Abstract: A drive signal from an SSG drives a CCD through a delay circuit and the like. An imaging signal from the CCD is converted to a video signal in a CDS circuit, which is driven by a sample hold signal given through the delay circuit, and is converted to a video signal that can be displayed on a monitor through an A/D converter circuit, a video signal processing circuit and a digital encoder to be output. Here, by correcting phases of the imaging signal and the sample hold signal, length of a signal line is corrected. Also, since the delay circuit is constructed by being incorporated in a DSP for video signal processing, which includes a video signal processing circuit and the like, the construction is simplified. Thus, the number of parts is reduced, and it can be constructed inexpensively.

Abstract: There are provided an image processing apparatus, an endoscope apparatus, and a color balance adjusting method capable of obtaining a good observation image. An image processing apparatus of the invention includes: an image signal input unit for inputting an image signal of a subject image picked up by an image pickup unit, the subject image including at least an image of a color balance adjustment tool; a control unit for calculating a value of coefficient to change brightness value of the image signal, based on a correction value to correct characteristic variation of the color balance adjustment tool, the correction value being shown in a correction value display portion included by the color balance adjustment tool, and a brightness value of the image of the color balance adjustment tool; and a color balance process unit for performing color balance adjustment by changing the brightness value of the image signal based on the coefficient value.

Abstract: Tissue information of a desired deep portion of a biological tissue based on a spectral image obtained from signal processing is adjusted to image information in a color tone suitable for observation. Outputs of a matrix computing section 436 are respectively connected to integrating sections 438a to 438c, and after integrating computation is performed for them, color conversion computation is performed for respective spectral image signals ?F1 to ?F3 in a color adjusting section 440, spectral color channel image signals Rch, Gch and Bch are created from the spectral image signals ?F1 to ?F3, and images of the spectral color channel images Rch, Gch and Bch are sent to a display monitor 106 via a switching section 439.

Abstract: The invention relates to a method improving the images in an image processing unit (5) receiving images from an electronic color video camera (3) of a medical endoscope (1) and then transmitting them to an image display unit (7), and to an endoscope operating on the basis of the said method, where first the pixels of the color components (RGB) are individually mapped into a color space (HSL) wherein the color saturation (S) is independent of the other components (H, L), thereupon the saturation component (S) of each pixel to be mapped is converted by means of a nonlinear mapping function (11) which amplifies the color saturation differential between an upper zone (b->1) and a lower zone (0-b) of the color saturation, lastly the pixels being remapped into an (RGB) color space suitable for image display.