Abstract: A system and method for automatically reconfiguring the magnification or zoom level of a surgical camera based upon the detection of a surgical instrument or defined anatomical feature. Utilizing image analysis algorithms, the video images generated by the surgical camera are analyzed for the presence of defined patterns, colors, motion and the like, representing a defined surgical instrument or anatomical feature. Upon detection of a surgical instrument or anatomical feature, the system can automatically adjust the actual or effective focal range of the surgical camera, and thus change the magnification or zoom level of the camera, based on the type of surgical instrument or anatomical feature detected.

Abstract: An objective lens for an endoscope is provided and has a lens group A and a lens group B that are movable in a direction of an optical axis. In the objective lens, first focal adjustment for observing a point between a most-distant point and an intermediate point is performed by moving the lens group A from a lens arrangement for observing the most-distant point; and second focal adjustment for observing a point between the intermediate point to a nearest point is performed by moving the lens group B from a lens arrangement for observing the intermediate point.

Abstract: There is provided an endoscope capable of observing cells at a desired position existing in the depth direction with a simple structure as compared to the conventional configuration. The endoscope includes an insert unit to be inserted into a biological body, a low-scaling observation system for observing an observation position in a biological body with a low scaling, and a high-scaling observation system for observing a target position of the aforementioned observation position as a local position with a high scaling. The high-scaling observation system includes a plurality of illumination units for applying illumination light for high-scaling observation of the target position. The illumination units are arranged at predetermined positions of the end face of the insert unit.

Abstract: An objective optical system is configured to be suitable to be implemented at a tip of an endoscope. The objective optical system is provided with a first lens unit having a first lens barrel and a first optical system including plurality of lens elements assembled in the first lens barrel, and a second lens unit having a second lens barrel and a second optical system including a plurality of lens elements. The first lens unit or the second lens unit includes an alignment lens which is movable in a direction perpendicular to the optical axis thereof. The alignment lens is a lens most sensitive with respect to an alignment error among the plurality of lenses included in the first optical system.

Abstract: An endoscopic image pickup unit includes: a first fixed lens frame which holds a first objective lens group; a second fixed lens frame which, being fitted over the first fixed lens frame, holds a second objective lens group; a movable lens frame which, being installed in the second fixed lens frame so as to be able to move forward and backward along a photographic optical axis, holds a movable lens; and a deformation preventing member which, being interposed between a distal end body and the second fixed lens frame, prevents the second fixed lens frame from being deformed by fixing force of the fixing member when the endoscopic image pickup unit is fixed to the distal end body.

Abstract: An optical system for a remote video inspection device including an elongated probe for inspection of target objects, comprising: an imager located distally within the probe, wherein the imager receives an image of the target object; a focus lens group located within the probe, the focus lens group comprising a variable aperture and at least one focus lens; a zoom lens group located within the probe, the zoom lens group comprising at least one zoom lens, wherein the movement of the zoom lens group in relation to the imager changes the magnification of the image; a tip lens located further from the imager than the focus lens group and the zoom lens group, wherein the distance between the tip lens and the imager is fixed; wherein a first movement of the focus lens group proportional to the movement of the zoom lens group provides an initial image focus, and a second movement of the focus lens group independent of the movement of the zoom lens provides a final image focus and proportional changes to the size of

Abstract: Improved optical devices and methods transmit optical images along elongate optical paths with relatively limited cross-sectional dimensions using an improved objective, relay, and ocular systems. In a first aspect, at least one intermediate image formed within an optical component, rather than being formed in a gap between optical components. In a preferred embodiment, a first intermediate image is formed within glass of the most proximal objective lens, with the first intermediate image extending axially along a curved image location within the glass. The last intermediate image may similarly be disposed within a distal lens of the ocular system. By making use of a first and/or last intermediate image disposed in this manner within a lens, endoscopes can exhibit a significantly larger Numerical Aperture than known endoscopes having similar cross-sectional dimensions.

Abstract: A method of and apparatus for viewing microscopic images include transmitting tiled microscopic images from a server to a client. The client assembles the tiled images into a seamless virtual slide or specimen image and provides tools for manipulating image magnification and viewpoint. The method and apparatus also provides a virtual multi-headed microscope function which allows scattered viewers to simultaneously view and interact with a coherent magnified microscopic image.

Abstract: An actuator has a magnet moved together with a moving lens frame, an SMA wire capable of extending and contracting in a moving direction I of the moving lens frame with execution or non-execution of energization thereof, a fixing member made of a magnetic material attached to a distal end of the SMA wire, a pressing spring which urges the fixing member toward the magnet along the moving direction I, and a stopper member and a stopper portion which limits the movement of the magnet along the moving direction I at a first position or a second position.

Abstract: A magnifying optical system for endoscope which can be set at least in a usual observing condition (at a wide position) and a condition for observing a magnified image of an object at a short distance (at a tele position) by moving any of one of lens units, and is configured so as to satisfy a condition mentioned below, thereby providing a sufficient observation depth in each observing condition: f(W)/F(T)>0.93.

Abstract: An endoscopic inspection method includes staining step and super magnified observation step. In the staining step, a distal end surface of a distal end portion of an endoscope which includes a distal end opening of a channel and a first lens that forms a super high-power observation optical system is held in contact with the tissue surface of the observation subject region such that the staining fluid supplied via the channel penetrates to the gap between the distal end surface and the tissue surface to eliminate the mucus on the tissue surface. The tissue surface having the mucus eliminated is stained with the staining fluid. In the super magnified observation step, the first lens which forms the super high-power observation optical system provided at the distal end portion is brought into contact with the tissue surface that has been stained with the staining fluid such that the observation at the cellular level is performed.

Abstract: An endoscope objective lens includes, in order from an object side, a negative first lens, a first cemented lens, an aperture diaphragm, a positive fourth lens and a second cemented lens. The negative first lens has a concave surface directed to an image side. The first cemented lens is formed by cementing a second lens and a third lens. One of the second and third lenses is positive and. The other is negative. The positive fourth lens includes a flat surface or a surface having a larger absolute value in radius of curvature, directed to the object side. The second cemented lens is formed by cementing a positive fifth lens and a negative sixth lens in order from the object side. The second cemented lens has a positive refractive power as a whole. The endoscope objective lens satisfies the following conditional expressions (1) and (2). f 2 × ? v 5 - v 6 ? ? R A ? × ( Bf + d 6 / n 6 ) > 10 ( 1 ) Bf / f > 2.

Abstract: There is provided an endoscope insertion portion capable of illuminating a diseased part corresponding to a part of an endoscope image by irradiation light in an amount approximately the same as that in non-enlarged display, when displaying the part of the endoscope image in an enlarged manner. The endoscope insertion portion of this invention includes: an insertion portion having a distal end surface; a first illumination optical system for irradiating light onto a subject; a second illumination optical system for irradiating light onto the subject; a first image pickup portion including on the distal end surface a first optical member for introducing light from the subject; and a second image pickup portion including a second optical member for introducing light from the subject, the second optical member being disposed in an area sandwiched by the first illumination optical system and the second illumination optical system.

Abstract: An otoscope permitting examination of a patient's ear is defined by an instrument head including a proximal end and a distal insertion portion that is insertable into the ear. The otoscope includes an imaging lens train disposed within the instrument head, wherein each of the imaging lens train, an eyepiece and a distal opening of said insertion portion are aligned along an optical axis. The otoscope further includes a focusing mechanism for selectively moving at least one of the imaging lens train and the optics contained within the eyepiece relative to one another along the optical axis. The imaging lens train and the optics in the eyepiece define an optical system such that an entrance pupil is substantially located in the distal insertion portion of the instrument head, thereby enabling the entire tympanic membrane to be viewed at once by the user.

Abstract: An endoscope insertion portion of the invention comprises: a distal end portion; first image pickup means for obtaining a first observation image, the first image pickup means being disposed to the distal end portion; second image pickup means for obtaining a second observation image, the second image pickup means being disposed to the distal end portion; a first object optical system for condensing photographing light incident on the first image pickup means, the first object optical system being located in the distal end portion; a second object optical system for condensing photographing light incident on the second image pickup means, the second object optical system being located in the distal end portion; and a plurality of illumination optical systems for irradiating light to a subject, the plurality of illumination optical systems being located in the distal end portion in a manner sandwiching each of the first object optical system and the second object optical system.

Abstract: A system and method for automatically reconfiguring the magnification or zoom level of a surgical camera based upon the detection of a surgical instrument or defined anatomical feature. Utilizing image analysis algorithms, the video images generated by the surgical camera are analyzed for the presence of defined patterns, colors, motion and the like, representing a defined surgical instrument or anatomical feature. Upon detection of a surgical instrument or anatomical feature, the system can automatically adjust the actual or effective focal range of the surgical camera, and thus change the magnification or zoom level of the camera, based on the type of surgical instrument or anatomical feature detected.

Abstract: A localization device display method and apparatus for displaying different views, e.g., of different magnification, based on the proximity of the tip of a pointer tracked by the localization device to a reference location identified by the localization device. The display method and apparatus may be incorporated into a surgical navigation system for use in identifying a location for drilling a femoral tunnel in an ACL repair procedure.

Abstract: An endoscope is connected optically removably to a TV camera through an adapter. A plurality of fixing pins is arranged on both sides of an insertion axis of an insertion part of the endoscope. A fixing unit to fix the endoscope removably is provided at the front end of an arm unit of an endoscope holder which supports the endoscope movably. The fixing unit has a claw and a movable claw, and grips the fixing pins of the endoscope releasably between the claw and the movable claw.

Abstract: A position control apparatus for controlling position along an axis, comprising: an extensible member that can be extended and contracted along said axis, comprising shape memory alloy locatable to expand and contract along said axis, heating means for controlling said temperature of said shape memory alloy, and a feedback mechanism for controlling said heating means and responsive to variations in said position, wherein said position is controllable by means of said heating means and can be stabilized by means of said feedback mechanism.

Abstract: Equipment includes an image guide (1) consisting of flexible optical fibers with: on the proximal end side: a source (2), angular scanning elements (3), injection elements (4) in one of the fibers, elements for splitting (5) the illuminating beam and the backscattered signal, elements for spatial filtering (6), elements for detecting (7) the signal, electronic elements (8) for controlling, analyzing and digital processing of the detected signal and display; and on the distal end side: an optical head (9) for focusing the illuminating beam exiting from the illuminated fiber. The scanning elements include a resonant line mirror (M1) and a galvanometric field mirror (M2) with a variable frequency and two afocal optical systems adapted to conjugate the two mirrors (M1, M2) firstly in the field mirror (M2) and the injection elements (4) in the image guide in a second step.

Abstract: An endoscopic apparatus comprises: a movable lens that is movably built in an objective optical system arranged at an tip of an insert part of an endoscope; a piezoelectric-element drive mechanism that causes the movable lens to move forward and backward in an optical axis direction due to driving of a piezoelectric element; a control circuit that provides a drive pulse to the piezoelectric element; and a storage section that stores respective ones of drive-pulse count data for moving the movable lens forward and backward equally in amount, wherein the control circuit performs control of providing a drive-pulse count, different in between forward and backward movement, to the piezoelectric element of the piezoelectric-element drive mechanism so as to move the movable lens forward and backward equally in amount depending upon drive-pulse count data read out of the storage section.

Abstract: An endoscope observation system for in vivo cellular observation is disclosed that includes an illumination optical system having a light source for supplying illumination light to an object, an objective optical system that forms a magnified image of the object such that the absolute value of the image scale factor exceeds unity, and an image pickup unit that detects the magnified image. The illumination optical system is provided with a wavelength selection means for dividing, among the blue, green, and red wavelength ranges in the illumination light from the light source, either the blue wavelength range or the red wavelength range into two wavelength bands T1 and T2, with the wavelength band T1 being nearer the green wavelength range than is the wavelength band T2, and light in the wavelength band T1 is prevented from illuminating the object. An in vivo cellular observation method is also disclosed using an endoscope.

Abstract: The present invention relates to an anti-thrombogenic, physically well-tolerated polymer and its use for manufacturing sheaths and films as a component of therapeutic devices for preventing excessive cell proliferation. Furthermore, it relates to films made from the polymer as well as wrappings for medical devices such as stents. It also relates to medical devices that are enclosed by a film or wrapping according to the invention.

Abstract: A confocal probe emits a scanning beam to a target and receives light returned therefrom to obtain an image thereof. The confocal probe has a chamber accommodating an optical system. The optical system includes an optical fiber through which a light beam is introduced to the optical system, a converging lens that converges the light beam introduced by the optical fiber, an optical element having a light incident surface, a first surface and a light emerging surface which statically define an optical path of the light beam, and a deflecting device mounted on the first surface of the optical element. The light beam enters the optical element through the light incident surface, enters the deflecting device through the first surface, and is dynamically deflected by the deflecting device. The deflected beam is output through the light emerging surface, as the scanning beam, toward the target.

Abstract: A method of and apparatus for viewing microscopic images include transmitting tiled microscopic images from a server to a client. The client assembles the tiled images into a seamless virtual slide or specimen image and provides tools for manipulating image magnification and viewpoint. The method and apparatus also provides a virtual multi-headed microscope function which allows scattered viewers to simultaneously view and interact with a coherent magnified microscopic image.

Abstract: An apparatus and method acquires and stores multiple resolution images from a specimen on a support and provides to the user a low magnification, reconstructed macro image of the entire specimen, or a large portion thereof, to aid the person in selecting points of interest to be viewed or analyzed at higher magnifications and resolution. The reconstructed image is formed of a large number of tiled, stored images which are coordinated and assembled to form the macro image of the specimen which is displayed on a monitor. Preferably, the stored, reconstructed image is reduced further in size by a software system before it is displayed to the user. The display may be on a local monitor over a local area network or sent over the Internet to the user who is typically a pathologist. The user selects by a marker such as a cursor the defined area of interest or region and then views higher magnification images or has them analyzed.

Abstract: An endoscope assembly is disclosed having a housing adapted to be manipulated by medical personnel, such as a surgeon. An elongated lens tube has one end secured to the housing while an elongated stage is removably secured to the housing so that the stage encompasses and is coaxial with the tube. The stage together with the lens tube are adapted for insertion into the cavity of a body. A lens assembly provided within the lens tube relays the optical image from the free end of the stage to the housing. A lens assembly within the housing, furthermore, varies the magnification of the image between macroscopic magnification and microscopic magnification in which tissue may be examined on a cellular level. For macroscopic magnification, white light is transmitted through the lens tube as well as reflected back from the target tissue through the lens tube and to the housing. For microscopic examination, laser radiation is utilized in lieu of the white light illumination.

Abstract: In a nearer order from its object, a first lens group which has a negative refractive power, a brightness diaphragm, and a second lens group which has a positive refractive power, and a moving lens group which moves on an optical axis, conditions such as 2?DL/fW?6, and ?2?DVH/fW?0.37 are satisfied under condition that DL (mm) indicates an air-converged length from an end surface near an image in the first lens group to an end surface nearer to an object in the moving lens group, fW (mm) indicates a focal length in an entire system in a wide angle end, DVH (mm) indicates a distance from the end surface near the object in the moving lens group to a front principal point. By doing this, it is possible to provide an objective optical system which can obtain a high magnification while securing a sufficient distance between the diaphragm which is disposed behind the optical axis direction converting element such as a prism to the moving lens group.

Abstract: A variable-view arthroscope or similar instrument (endoscope, etc.) includes a housing tube with an input end. The housing tube contains an input assembly and a portion of a light relay assembly. A control varies the position of the input assembly to change the viewing position of the arthroscope. In certain embodiments, the control uses external master magnets that rotate around an axis orthogonal to the longitudinal axis of the housing to drive internal slave magnets magnetically. This permits the housing to be sealed completely. In certain embodiments, a cam-axle assembly translates the rotational motion of the internal slave magnets to linear motion that drives a push rod that manipulates the input assembly.

Abstract: An optical system pair for a stereo endoscope is described which enables adjustment of magnification matching in the production phase with low cost and small size for the resulting stereo endoscope products. The stereo optical systempair for stereo endoscope system includes a right optical system and a left optical system, wherein one of the right and left optical systems includes a lens group which has a refractive power, and which is designed to be moveable axially with a moveable range and has a position within the moveable range at which optical magnification equals to ?1. Also described are optical arrangements of a stereo endoscope incorporating the stereo optical system pair.

Abstract: An endoscope to perform non-tethered macroscopy and microscopy at the same time is provided. An electromagnetic source is used to deliver electromagnetic energy through a first optical pathway to a tissue inside a body. An image detector is used to detect the reflected electromagnetic energy from the tissue through a second optical pathway as real-time images. A macro-to-micro lens set is used to change the magnification of the reflected electromagnetic energy before it reaches the image detector with two or more different magnification levels. A filter set is used to filter the reflected electromagnetic energy before it reaches the image detector. Furthermore, the endoscope includes a flexible shaft. The distal end of the shaft includes a spread and spot means to spread and spot the electromagnetic energy at the tissue. A processing means is also included for processing the detected images.

Abstract: An endoscope has an inserting tube to be inserted into a human body, first and second optical systems integrally secured to a tip end portion of the inserting tube. The first and second optical systems are for observing the in vivo tissues at different magnifications. A front end portion of the second optical system is protruded by a predetermined amount with respect to a front end portion of the first optical system so that the front end portion of said second optical system is located within a field of view of said second optical system.

Abstract: An endoscope probe system includes an endoscope probe to be inserted into a body cavity to observe tissue of a living body. The endoscope probe system further includes a laser source that emits multiple laser beams, a light detector having multiple light receiving elements each of which detects intensity of light incident thereon, and a plurality of confocal optical systems arranged to focus the laser beams emitted from the laser source to small spots arranged in a matrix pattern on the target and selectively transmit the laser beams reflected by the target at the spots to respective ones of the light receiving elements of the light detector.

Abstract: An electronic endoscope equipped with an electronic zoom IC circuit that optically scales an object under observation using power scaling lenses and performs electronic power scaling processing on an image obtained by a CCD, wherein the electronic endoscope sets a predetermined depth of field by driving the power scaling lenses with the image optically magnified based on an operation of a variable depth switch and maintains the magnification immediately before this switch operation through electronic power scaling processing. This makes it possible to change a depth of field and observe an image magnified under an equal magnification focused in the depth direction on the monitor. The electronic endoscope can also form a plurality of still images of different depths of field based on an operation of the freeze switch and record optimal still images.

Abstract: A confocal probe unit is provided with a scanning type confocal probe, which includes at least one scanning mirror, and a transparent substrate on which the at least one scanning mirror is mounted. The transparent substrate is inserted in an optical path of the confocal probe such that a light beam proceeding along the optical path is deflected by the scanning mirror.

Abstract: An endoscope includes an optical system for endoscope observation arranged in an edge of an inserting portion which can be inserted in a specimen, an optical system for microscopic observation which microscopically observes an observing portion of the specimen, a moving mechanism for adjusting an angle of view which changes the angle of view by moving a part of the optical system for endoscope observation, and a focal-point adjusting mechanism which is arranged in the edge of the inserting portion and which moves a focal point on the side of a subject in the optical system for microscopic observation, wherein the moving mechanism for adjusting the angle of view and the focal-point adjusting mechanism are arranged forward and backward of the same axis to the inserting portion.

Abstract: To provide an electronic endoscope system provided with an objective optical system for optically magnifying an image to be observed by using a variable power lens and an electronic zoom IC circuit for electronically magnifying an image obtained by a CCD. A depth of field at the time of switching between optical variable power and electronic variable power is set at an arbitrary value by key operation etc. of a control panel of a processor. When the depth of field becomes a setting value, for example, 16 mm (lens position before Near end), during the operation of optical variable power based on the operation of a variable power switch, electronic variable power is executed by the electronic zoom IC circuit. Thereby, an enlarged image in which the depth of a subject to be observed with irregularities is properly in focus can be obtained.

Abstract: An endoscope assembly is disclosed having a housing adapted to be manipulated by medical personnel, such as a surgeon. An elongated lens tube has one end secured to the housing while an elongated stage is removably secured to the housing so that the stage encompasses and is coaxial with the tube. The stage together with the lens tube are adapted for insertion into the cavity of a body. A lens assembly provided within the lens tube relays the optical image from the free end of the stage to the housing. A lens assembly within the housing, furthermore, varies the magnification of the image between macroscopic magnification and microscopic magnification in which tissue may be examined on a cellular level. For macroscopic magnification, white light is transmitted through the lens tube as well as reflected back from the target tissue through the lens tube and to the housing. For microscopic examination, laser radiation is utilized in lieu of the white light illumination.

Abstract: A micro-endoscopic system employs a pulsed xenon light source and novel image collection optics with a fine diameter optical probe for an endoscope. Very bright pulses of light emitted by a xenon flash tube increase the intensity of light incident on the light transmitting optics, allowing a reduction in size of the optical components, resulting in a corresponding reduction in the size of the optical probe. A novel segmented glass image guide directs the reflected light to a sensor array. Segmentation of the image guide avoids the birefringence problems associated with fine diameter glass optical structures. Conventional optical fiber imaging and light delivery apparatus may also be used in conjunction with the pulsed xenon light source.

Abstract: A device for positioning components within endoscopic systems includes a hermetically sealed housing. An outer ring element is mounted to rotate about the outer side of the housing and carries on its circumference at least one outer magnet. Further, an inner ring element is mounted inside the housing and carries likewise at least one inner magnet, the magnets being aligned in such a way that any rotation of the outer ring element has the effect to move the at least one inner magnet by magnetic coupling, such movement serving the purpose to position the respective components. In order to achieve a simple, relatively small and functionally safe structure it is proposed that both the outer and inner ring elements be configured as axially displaceable rings carrying the oppositely arranged magnets, and that the inner ring be mechanically connected with the component to be positioned.

Abstract: An endoscope with a sealed housing having inner magnetic structures coupled to a displacement element and outer magnetic structures coupled to an adjustment element. The inner and outer magnetic structures are magnetically coupled to each other through the wall of the housing and are displaceable parallel to the wall. The inner magnetic structure is displaceable toward and away from stop and the outer magnetic structure magnetically drives the inner structure. The outer magnetic structure can be affixed beyond the stop position of the inner structure in a secured adjustment position.

Abstract: A probe of a video microscope system has a window sealed to a casing, the window having a flat outer surface for contacting an area of the body of a patient, such as the patient's mouth In the method of the invention, a dye is administered to the body area so as to stain both normal and any abnormal cells, which stained area is then examined with magnification means of the probe so as to allow a surgeon to interpret the images and identify any cancerous cells.

Abstract: This endoscope apparatus utilizes a phenomenon called “curvature of field” of a lens to satisfactorily bring a shape, into focus, of an object to be observed such as unevenness especially during enlargement in accordance with a shape of unevenness or the like of the object. For example, there is provided an objective lens group having two movable lenses, and variable-power is performed and field curvature characteristics are changed by moving these movable lenses. This change in the field curvature characteristics is performed by operating an image surface curving switch and driving the movable lenses through the use of an actuator or the like. Also, information on differences in height on the image central part to the peripheral part is operated from the amount of field curvature changed by the objective lens group to display the information on differences in height on the monitor.

Abstract: An endoscope system in which a normal observation image and a near observation image are photographed by a solid-state image sensor upon operation of a focus adjustment device for changing a focal length and a working distance satisfies: WDWide>WDtele fwide≧ftele where fwide is a focal length in a normal observation mode, WDwide is a working distance in the normal observation mode, ftele is a focal length in a near observation mode, and WDtele is a working distance in the near observation mode. Whereby, the endoscope system is provided with a wide depth of field so as to allow even a person without considerable skills to easily manipulate the system in the magnifying observation mode, is able to improve accuracy of diagnosis information by enhancing seeming resolution of the magnified information, and is able to improve accuracy of diagnosis by facilitating discussion among a plurality of medical doctors.

Abstract: In the endoscope, in which a protective tube and a linear transmission member are arranged from a tip end portion to an operating unit, for transmitting rotation of a motor to the tip end portion through the linear transmission member to thereby drive a movable lens for making the observation distance variable, the protective tube is divided into a front-side tube and a rear-side tube having a larger inner diameter than the front-side tube, and these are connected together within the operating unit. Also, the linear transmission member is also divided into a front-side transmission member and a rear-side transmission member having a larger outside diameter, and as regards this rear-side transmission member, there is used a multiple coiled spring formed by winding strands of a predetermined number of threads brought into tight contact in a state, in which space for predetermined intervals is left.

Abstract: A micro-endoscopic system employs a pulsed xenon light source and image collection optics with a fine diameter optical probe for an endoscope. Very bright pulses of light emitted by a xenon flash tube increase the intensity of light incident on the light transmitting optics, allowing a reduction in size of the optical components, resulting in a corresponding reduction in the size of the optical probe. A segmented glass image guide directs the reflected light to a sensor array. Segmentation of the image guide avoids the stress related problems associated with fine diameter glass optical structures.

Abstract: This endoscope includes a magnification change manipulative switch made easy to manipulate in relation to an angle manipulative knob. That is, in an endoscope manipulative section with an angle manipulative knob for bending a front end and a magnification change manipulative switch disposed, two switch bodies making up the above magnification change manipulative switch are arranged in a direction nearly perpendicular to a rotation axis of the angle manipulation knob and disposed nearly in contact with each other so as to be retained by a retaining member to which a rubber cover is attached in an airtight condition. On an outer surface of this rubber cover, a convex portion for identifying function is provided. According to this endoscope, movement of a thumb between the angle manipulation knob and the magnification change manipulative switch is smoothed and the above convex portion enables a magnification change, for example, to a near side or to the far side, to be manipulated.

Abstract: An endoscope according to the invention includes a red component cut optical filter having a characteristic that a spectral transmittance becomes half at 630 nm and zero at 670 nm, for example between a light source and an infrared cut filter, to remove a long wavelength component mainly in a red band of illumination light. This restrains scattering of light on a long wavelength side of red light, and allows taking images of mucosa, blood vessels, and other tissue in good contrast in an object to be observed and satisfactorily observing them on a monitor. Further, reduction in light amount resulting from cutting a red component with the filter is eliminated by light amount control with an aperture and gain control of a signal.

Abstract: The present invention provides an electronic endoscope equipped with an electronic zoom IC circuit that optically scales an object under observation using power scaling lenses and performs electronic power scaling processing on an image obtained by a CCD, wherein the electronic endoscope sets a predetermined depth of field by driving the power scaling lenses with the image optically magnified based on an operation of a variable depth switch and maintains the magnification immediately before this switch operation through electronic power scaling processing. This makes it possible to change a depth of field and observe an image magnified under an equal magnification focused in the depth direction on the monitor. The electronic endoscope can also form a plurality of still images of different depths of field based on an operation of the freeze switch and record optimal still images.

Abstract: An endoscope assembly is disclosed having a housing adapted to be manipulated by medical personnel, such as a surgeon. An elongated lens tube has one end secured to the housing while an elongated stage is removably secured to the housing so that the stage encompasses and is coaxial with the tube. The stage together with the lens tube are adapted for insertion into the cavity of a body. A lens assembly provided within the lens tube relays the optical image from the free end of the stage to the housing. A lens assembly within the housing, furthermore, varies the magnification of the image between macroscopic magnification and microscopic magnification in which tissue may be examined on a cellular level. For macroscopic magnification, white light is transmitted through the lens tube as well as reflected back from the target tissue through the lens tube and to the housing. For microscopic examination, laser radiation is utilized in lieu of the white light illumination.