Abstract: A reduced area imaging device is provided for use in medical or dental instruments such as an endoscope. The imaging device is provided in various configurations, and connections between the imaging device elements and a video display may be achieved by wired or wireless connections. A connector assembly located near the imaging device interconnects the imaging device to an image/power cable extending through the endoscope. The connector provides strain relief and stabilization for electrically interconnecting the imager to the cable. The connector also serves as the structure for anchoring the distal ends of steering wires extending through the body of the endoscopic device. The connector includes a strain relief member mounted over a body of the connector. The connector allows a steering wire capability without enlarging the profile of the distal tip of the endoscopic device.

Abstract: Embodiments of the invention provide a camera module including a lens barrel part in which a plurality of lenses are stacked, a housing having the lens barrel part disposed therein, and an infrared (IR)-cut filter provided in the housing and disposed at a lower portion of the lens barrel part. According to at least one embodiment, the camera module further includes a circuit board having a window formed therein so as to penetrate through a central region thereof and supporting a bottom surface of the housing; an image sensor accommodated in the window of the circuit board and converting an external image into an electrical signal, and a plate coupled to a lower portion of the circuit board to radiate heat generated from the circuit board.

Abstract: An endoscope system according to the invention includes a display device including a first connector, plural apparatuses having different functions in which placing sections, on which the display device can be detachably set from a common direction, are respectively provided, and a second connector disposed in common in each of the placing sections and electrically connected to the first connector of the display device to form a pair in a state in which the display device is set on the placing sections.

Abstract: In-vivo medical devices, systems and methods of operating such devices include a permanent magnetic assembly interacting with external magnetic fields for magnetically maneuvering said device to a desired location along a patient's GI tract, and anchoring said devices to the desired location for a period of time. The in-vivo medical device includes illumination sources, an optical system, and an image sensor for imaging the GI tract and thus assisting in locating the desired location. Some in-vivo medical devices include a concave window, which enables better imaging of small areas along the tissue. Furthermore, in-vivo devices with a concave window enable carrying operating tools without damaging the tissue of the GI tract, since prior to operation, the tools protrude from the concave window but remain behind the ends of the edges of the concave window.

Abstract: The current invention relates to a method for making a camera housing of an endoscope having a camera housing arranged at the distal end of the insertion portion, said camera housing being a molded component comprising an outer surface, a camera device embedded in the material of the camera housing, a light source embedded in the material of the camera housing, an opening at the distal end of the camera housing, and a channel in fluid communication with said opening. The endoscope further comprises a tube which provides fluid communication between the channel in the camera housing to the proximal end of the endoscope. The endoscope further comprises a bending portion arranged at the distal end of the insertion portion and at the proximal end of the camera housing and where the most distal portion of the bending portion is embedded in the material of the camera housing.

Abstract: A system and method may display an image stream, where an original image stream may be divided into two or more subset images streams, each subset image stream being displayed simultaneously or substantially simultaneously. The spatial position of the images displayed substantially simultaneously in each time slot may be variably adjusted based on a predetermined criterion. The images may be collected from an ingestible capsule traversing the GI tract.

Abstract: A method of using a scanning microscope to rapidly form a digital image of an area. The method includes performing an initial set of scans to form a guide pixel set for the area and using the guide pixel set to identify regions representing structures of interest in the area. Then, performing additional scans of the regions representing structures of interest, to gather further data to further evaluate pixels in the regions, and not scanning elsewhere in the area.

Abstract: An image-capturing apparatus and a repair method thereof are provided. The image-capturing apparatus includes a lens frame to which one or more lenses are fixed; an image-capturing frame to which an image-capturing device is fixed; and a fixing member for fixing the lens frame and the image-capturing frame to each other without adhering a fitted portion between the lens frame and the image-capturing frame. The repair method for the image-capturing apparatus includes destructing a fixing member for fixing to each other a lens frame to which one or more lenses are fixed and an image-capturing frame to which an image-capturing device is fixed, and releasing fixing between the frames; replacing at least either of the lens frame and the image-capturing frame; and fixing to each other the lens frame and the image-capturing frame.

Abstract: A support according to an embodiment is a support that supports a wiring board including a mounting area for an image sensor, a first lead area extending from the mounting area and having a first connection terminal formed therein, and a second lead area extending from the mounting area and having a second connection terminal formed therein.

Abstract: In one embodiment, a method includes receiving an image of a user's eye at a device having a screen and a camera operable to input the image, processing the image to identify one or more characteristics of the user's eye for use in determining if the user is having difficulty viewing data displayed on the screen, and magnifying the data displayed on the screen if the user is having difficulty viewing the data. An apparatus and logic are also disclosed.

Abstract: A reduced area imaging device is provided for use in medical or dental instruments such as an endoscope. The imaging device is provided in various configurations, and connections between the imaging device elements and a video display may be achieved by wired or wireless connections. A connector assembly located near the imaging device interconnects the imaging device to an image/power cable extending through the endoscope. The connector provides strain relief and stabilization for electrically interconnecting the imager to the cable. The connector also serves as the structure for anchoring the distal ends of steering wires extending through the body of the endoscopic device. The connector includes a strain relief member mounted over a body of the connector. The connector allows a steering wire capability without enlarging the profile of the distal tip of the endoscopic device.

Abstract: An imaging device and an endoscopic device can be further miniaturized. A vertical selection unit simultaneously resets charge accumulation units of a plurality of pixels, and then a horizontal selection unit sequentially selects a plurality of first pixel signals corresponding to voltages of the charge accumulation units of the plurality of pixels and inputs the first pixel signals to an output unit. Further, a vertical selection unit simultaneously transfers the signal charges generated by the charge generation units in the plurality of pixels to the charge accumulation units, and then a horizontal selection unit sequentially selects a plurality of second pixel signals corresponding to the voltages of the charge accumulation units of the plurality of pixels and inputs the second pixel signals to the output unit.

Abstract: An imaging module includes: an imaging unit including a light receiving unit having a plurality of pixels arranged in a specified shape including a lattice shape and configured to receive light and to perform photoelectric conversion on the received light, the imaging unit being configured to capture an image of a subject and to output the image as a light quantity signal; a signal processing unit configured to perform signal processing on the light quantity signal; and a flexible substrate which includes a bendable insulating film and on which the imaging unit and the signal processing unit are mounted. The flexible substrate is bent to arrange the signal processing unit and the flexible substrate in a space extending from an outer edge of an incident surface of the imaging unit in a direction perpendicular to the incident surface while maintaining a shape of the outer edge.

Abstract: According to this invention, there is provided an image pickup unit for an endoscope, including a lens barrel portion includes a movable lens holding barrel that holds the movable lens and is movable to advance and retract and a drive mechanism portion which is disposed at a side surface portion of the lens barrel portion and drives the movable lens holding barrel. The unit has a holding portion which is disposed at the side surface portion of the lens barrel portion and is configured to position and hold the drive mechanism portion, a gap between the lens barrel portion and the drive mechanism portion is filled with an adhesive which is made to have a difference in hardness such that hardness is lower on a proximal end side than on a distal end side.

Abstract: An endoscope includes: an image pickup device mounted in a distal end portion of an insertion portion; wiring that transmits a power supply having a plurality of different power supply voltages for driving the image pickup device, a drive signal that drives the image pickup device, an image pickup signal that is outputted from the image pickup device, and a ground level; a substrate on which a connector that relays the wiring is provided; a first voltage comparing portion that compares the plurality of different power supply voltages; a power supply generation portion that generates a plurality of second power supply voltages; a second voltage comparing portion that compares the plurality of second power supply voltages; and a power supply control portion that controls a supply of power to the image pickup device based on comparison results of the first and second voltage comparing portions.

Abstract: A reduced area imaging device is provided for use in medical or dental instruments such as an endoscope. The imaging device is provided in various configurations, and connections between the imaging device elements and a video display may be achieved by wired or wireless connections. A connector assembly located near the imaging device interconnects the imaging device to an image/power cable extending through the endoscope. The connector provides strain relief and stabilization for electrically interconnecting the imager to the cable. The connector also serves as the structure for anchoring the distal ends of steering wires extending through the body of the endoscopic device. The connector includes a strain relief member mounted over a body of the connector. The connector allows a steering wire capability without enlarging the profile of the distal tip of the endoscopic device.

Abstract: In a first aspect the invention is a video camera head comprising an objective lens assembly and a solid state imager (SSI) comprised of a solid state pick up device and integrated circuitry adapted to produce an output video signal. The SSI is configured to allow video signals to be sent from the SSI and power to be supplied to the SSI by means of four or less electrically connecting pads. In a second aspect the invention is a video camera head comprising a 0.7 mm×0.7 mm sensor and an integral 1.4 mm inner diameter light ring. In a third aspect the invention is a visualization probe comprising illumination means and a video camera head of the first aspect. The visualization probe has a maximum outer diameter of 2.8 mm or less. In a fourth aspect the invention is a medical device comprising a visualization probe of the third aspect. The medical device has a maximum outer diameter of 3.2 mm or less.

Abstract: An endoscope apparatus includes an image pickup section equipped with a color separation section that picks up an image of returning light from a subject illuminated by an illumination section, an emphasis processing section that performs emphasis processing on sharpness of an image signal generated from the output signal of the image pickup section and a storage section that stores information for modifying processing contents of the emphasis processing, wherein the storage section stores information for setting image signals to be subjected to emphasis processing in first and second observation modes in which images are picked up under illumination of white light and narrow band light respectively to a luminance signal and a color difference signal, and the emphasis processing section performs emphasis processing on the luminance signal with a greater emphasis characteristic than the color difference signal over an entire frequency domain.

Abstract: An image pickup unit includes a board to which an image pickup device is electrically connected, the board is provided with a first terminal portion which includes a plurality of terminals and is used when a first endoscope is configured, and a second terminal portion which includes a plurality of terminals and is used when a second endoscope is configured, a folding portion is provided between the first terminal portion and the second terminal portion of the board, when the board is used as an image pickup unit of the second endoscope, the board is folded at the folding portion, and a signal transmission member is connected to the second terminal portion, and at least one of a terminal size and a space between terminals in the second terminal portion is set to be larger than at least one of a terminal size and a terminal space in the first terminal portion.

Abstract: In a first aspect the invention is a video camera head comprising an objective lens assembly and a solid state imager (SSI) comprised of a solid state pick up device and additional circuitry adapted to produce an output video signal. The video camera head has a maximum outer diameter of 1.1 mm or less and the length of the objective lens assembly is 2.5 mm or less. In a second aspect the invention is a visualization probe comprising illumination means, an objective lens assembly, and a solid state imager (SSI) comprised of a solid state pick up device and additional circuitry adapted to produce an output video signal. The visualization probe has a maximum outer diameter of 2.8 mm or less. In a third aspect the invention is a medical device comprising a visualization probe comprised of illumination means, an objective lens assembly, and a solid state imager (SSI) comprised of a solid state pick up device and additional circuitry adapted to produce an output video signal.

Abstract: A system for wirelessly powering various devices positioned on an endoscope, including, for example, a light source, various electronics including an imager and/or a memory device. The endoscope is coupled to a camera where the endoscope may be rotated relative to the camera when coupled thereto. The system is further provided such that video signal processing parameters are automatically set for an endoscopic video camera system based upon characteristics of an attached endoscope, with reduced EMI and improved inventory tracking, maintenance and quality assurance, and reducing the necessity for adjustment and alignment of the endoscope and camera to achieve the data transfer.

Abstract: Photo-detector device for electro-optical sensors, comprising at least a detection and conversion circuit, or pixel (20), having at least a photo-sensitive reception mean (26) and a reset control terminal (11), which is able to drive an element to control the charge dissipation (23) of the photo-sensitive reception mean (26). The pixel (20) is able to convert the current generated by the photo-sensitive reception mean (26) into a voltage signal on a read-out terminal (28). The photo-detector device also comprises a circuit for controlling the reset voltage (40), able to generate a suitable input signal to the reset control terminal (11) by connecting it alternatively to a reset terminal (42) or to an external reference terminal (47), the input signal to said external reference terminal (47) is the type that can be programmed from outside. Furthermore, the circuit for controlling the reset voltage (40) can be shared between a subset of detection and control circuits (20).

Abstract: An object is to provide a receiver system that allows a plurality of antennas to be easily attached onto a body surface without losing receiving functions of the antennas while improving freedom for a living body. A receiver system transmits in-vivo information including in-vivo images received from a capsule endoscope being the interior of a subject to an exterior receiving device via a plurality of wireless relay devices. Each of the wireless relay devices includes a receiving unit that receives the in-vivo information from the capsule endoscope at a first frequency, a transmitting unit that transmits the in-vivo information at a second frequency, a receiving unit that receives a control signal transmitted by the receiving device at the second frequency, and a control unit that controls transmissions and receptions performed by the receiving unit and the transmitting unit based on the control signal.

Abstract: An inspection apparatus can include a handset and an elongated inspection tube extending from the handset. For reduction of heat energy radiating from one or more components of the apparatus, the apparatus can include a particularly designed heat sink assembly.

Abstract: An image pickup apparatus having an image pickup device chip, a wiring board placed within a projection plane of the image pickup device chip and a reinforcement member fixed in abutment with at least a part of the wiring board. An endoscope having the image pickup apparatus. A method for manufacturing the image pickup apparatus.

Abstract: An image pickup device constituted by a bare chip is mounted to a flexible substrate including an opening portion and a wiring pattern, so that a light receiving area is positioned at the opening portion and so as to be electrically connected to the wiring pattern. A rigid substrate having a concave portion capable of housing the image pickup device is connected to the flexible substrate. A bottom face of the concave portion is set as a reference face for regulating the optical axis direction of the image pickup device, and a rear face of the image pickup device is firmly fixed to the bottom face. A wiring pattern is provided on the rigid substrate, and the wiring pattern of the rigid substrate and the wiring pattern of the flexible substrate are electrically connected.

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: The present invention provides a system and method for obtaining in vivo images. The system contains an imaging system and a transmitter for transmitting signals from a camera to a receiving system located outside a patient.

Abstract: An image pickup apparatus includes: a solid-state image pickup device partitioned into a light-receiving portion region that generates an image pickup signal of an optical image, a circuit portion region that processes the image pickup signal and generates a driving signal, and a terminal portion region having terminals for inputting/outputting signals with an external apparatus; and an objective optical portion having an objective lens unit including a unit main body having an objective lens group for forming an optical image and a holding barrel where the unit main body is fixed, and a prism that guides the optical image that passes through the objective lens unit to the light-receiving portion region. The prism of the objective optical portion is disposed on the light-receiving portion region of the substrate, and the holding barrel of the objective lens unit is disposed on the circuit portion region.

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 includes an insertion portion including an insulative distal end hard portion main body at a distal end thereof, an operation portion provided at a proximal end portion of the insertion portion and including a connector connection electrically connected to a ground portion, a ground metal member provided between the main body and the operation portion, forming a structure of the insertion portion, and being electrically conductive to the ground portion through the connector connection, an observation optical system including an optical element and a frame member having conductive properties and holding the optical element, and being extended from the distal end of the insertion portion toward the operation portion, and a conductive connecting portion allowing the frame member of the observation optical system to become electrically conductive with respect to the ground metal member.

Abstract: An imager and a method for real-time, non-destructive monitoring of light incident on imager pixels during their exposure to light. Real-time or present pixel signals, which are indicative of present illumination on the pixels, are compared to a reference signal during the exposure. Adjustments, if necessary, are made to programmable parameters such as gain and/or exposure time to automatically control the imager's exposure to the light. In a preferred exemplary embodiment, only a selected number of pixels are monitored for exposure control as opposed to monitoring the entire pixel array.

Abstract: An imaging module of the invention includes: an electrical cable; a solid-state image sensing device; and a flexible wiring substrate including: a device-mounted portion onto which the solid-state image sensing device is mounted; two extended portions which bend at both sides of the device-mounted portion and extend from the device-mounted portion so as to come close to each other with increasing distance from the device-mounted portion; two connection end portions extending from the two extended portions along the direction of the axis of the front end of the electrical cable on an opposite side of the device-mounted portion; and terminals which are provided on the two connection end portions and connected to the electrical cable, the flexible wiring substrate electrically connecting the solid-state image sensing device and the electrical cable.

Abstract: According to this invention, there is provided an image pickup unit for an endoscope, including a lens barrel portion includes a movable lens holding barrel that holds the movable lens and is movable to advance and retract and a drive mechanism portion which is disposed at a side surface portion of the lens barrel portion and drives the movable lens holding barrel. The unit has a holding portion which is disposed at the side surface portion of the lens barrel portion and is configured to position and hold the drive mechanism portion, a gap between the lens barrel portion and the drive mechanism portion is filled with an adhesive which is made to have a difference in hardness such that hardness is lower on a proximal end side than on a distal end side.

Abstract: A method of one aspect may include receiving an encapsulated image acquisition device having an internal memory. The internal memory may store images acquired by the encapsulated image acquisition device. The images may be transferred from the internal memory to an external memory that is external to the encapsulated image acquisition device. An image analysis station may be selected from among a plurality of image analysis stations to analyze the images. The images may be analyzed with the selected image analysis station. Other methods, systems, and kits are also disclosed.

Abstract: A system for wirelessly powering various devices positioned on an endoscope, including, for example, a light source, various electronics including an imager and/or a memory device. The system is further provided such that video signal processing parameters are automatically set for an endoscopic video camera system based upon characteristics of an attached endoscope, with reduced EMI and improved inventory tracking, maintenance and quality assurance, and reducing the necessity for adjustment and alignment of the endoscope and camera to achieve the data transfer.

Abstract: An image pickup unit includes an image pickup device, an objective lens, and a prism that has a reflective surface. The image pickup unit includes: a projecting portion that is an area at which the image pickup device projects to the rear from the prism; a terminal portion provided on the projecting portion; a flexible printed wiring board that extends along the prism and the projecting portion; an image pickup device connection terminal portion formed on a face that faces the projecting portion of the flexible printed wiring board; and a cable connection terminal portion formed at an area that extends over the projecting portion of the flexible printed wiring board. The terminal portion and the image pickup device connection terminal portion are joined in an opposed state. An electronic component is mounted on a face on an opposite side to the reflective surface of the flexible printed wiring board.

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: The present invention provides a system for imaging an object comprising: an optical imaging unit for imaging an object on a detection array, the optical imaging unit defining an optical axis and comprising a multicore fiber configured to collect light from the object at an input edge of the multicore fiber and transfer collected light to an output edge of the multicore fiber; a displacing unit configured to shift the input edge of the multicore fiber relatively to the object in a plane substantially perpendicular to the optical axis to obtain a set of shifted images of the object; and an operating unit configured to operate the displacing unit by setting a shifting amplitude to either a first amplitude inferior or equal to the diameter of a core of the multicore fiber or a second amplitude superior or equal to the diameter of the multicore fiber.

Abstract: There is provided herein a flexible electronic circuit board for a tip section of a multi-camera endoscope, the circuit board comprising a front camera surface configured to carry a forward looking camera, a first side camera surface configured to carry a first side looking camera, a second side camera surface configured to carry a second side looking camera, one or more front illuminator surfaces a configured to carry one or more front illuminators to essentially illuminate the FOV of the forward looking camera, one or more side illuminator surfaces configured to carry one or more side illuminators to essentially illuminate the FOV of the first side looking camera and one or more side illuminator surfaces configured to carry one or more side illuminators to essentially illuminate the FOV of the second side looking camera.

Abstract: An endoscope includes: an image pickup device mounted in a distal end portion of an insertion portion; wiring that transmits a power supply having a plurality of different power supply voltages for driving the image pickup device, a drive signal that drives the image pickup device, an image pickup signal that is outputted from the image pickup device, and a ground level; a substrate on which a connector that relays the wiring is provided; a first voltage comparing portion that compares the plurality of different power supply voltages; a power supply generation portion that generates a plurality of second power supply voltages; a second voltage comparing portion that compares the plurality of second power supply voltages; and a power supply control portion that controls a supply of power to the image pickup device based on comparison results of the first and second voltage comparing portions.

Abstract: An endoscope system has a light source apparatus and an endoscope including an illumination optical system and an objective optical system. At least the objective optical system of the endoscope is provided with an adjustable diaphragm, and in a light path in one of the light source apparatus, the illumination optical system, and the objective optical system, an insertable/retractable filter for observation for special light is provided. The adjustable diaphragm performs a closing operation or an opening operation only when the filter for observation for special light is inserted into the light path.

Abstract: There is provided an endoscope camera that achieves closer cumulative tolerance of a camera head and achieves improved accuracy in positioning the camera head. An endoscope camera includes a cylindrical hard case, a camera head provided at a distal end portion of the hard case, and a cover attached to the distal end portion of the hard case which covers the camera head. A rib wall having a holding section is provided inside the cover, and an abutment section which is held by the holding section is provided at the camera head. The abutment section is biased toward the holding section.

Abstract: In an image managing apparatus connected to: an image processing apparatus receiving an image signal from an imaging apparatus capturing a medical examination image; and an image recording apparatus recording a captured image, an apparatus information storage stores an image processing apparatus type. An apparatus ID acquiring unit acquires an image processing apparatus identifier from the connected image processing apparatus. An apparatus type acquiring unit reads out the type of the connected image processing apparatus based on the image processing apparatus identifier acquired by the apparatus ID acquiring unit. If the image processing apparatus type read by the apparatus type acquiring unit indicates that the apparatus can transmit an image file directly to the image recording apparatus, a file acquiring unit reads out from the image recording apparatus an image file that the image processing apparatus stores directly in the image recording apparatus.

Abstract: In an assembly method for an endoscope image pickup unit, the endoscope image pickup unit includes a distal end portion main body portion including a front opening portion, a side opening portion, a rear opening portion and an arrangement space portion, a lens section including a distal end lens having an outer diameter that generally fits in the front opening portion, and an image pickup section that fits in the rear opening portion and includes an image pickup device arranged in an image forming position by a lens system such as the lens section. The assembly method includes steps for inserting the lens section into the arrangement space portion from the side opening portion, fitting the inserted lens section in the front opening portion, and fitting the image pickup section in the rear opening portion from a rear of the rear opening portion.

Abstract: An endoscope system includes a host device and an endoscope including a very small area CMOS image sensor having only four pads (power, ground, digital in, analog out), and including an array of 4T pixels and associated control circuitry for performing correlated double sampling (CDS) to generate analog reset level and analog signal level values associated with light detected by photodiodes in each pixel. Instead of processing the analog values on-chip, the analog reset values and analog signal values are transmitted in separate sets one row at a time along with interleaved synchronization signals by way of a single analog contact pad to the host device of the endoscopic system, which uses the synchronization signals to reconstruct the sensor's internal clock in order to process the analog values. The endoscope housing thus requires only four wires and is made very small.

Abstract: There is provided a conductive supporting member provided to be electrically brought into contact with a shielding part of a cable bundle, and supporting the cable bundle. Further, there is provided a supporting member holding part provided to support a circuit board controlling an imaging element, and holding the conductive supporting member connected to a part of cables of the cable bundle. Further, there is provided a conductive coating member coated on a part of the supporting member and a part of the supporting member holding part.

Abstract: An endoscope includes an imaging unit capturing an image of an object; an imaging holder holding the imaging unit; two systems of driving force transmission mechanisms each including a pair of driving rods having distal ends connected in a diagonal position to each other relative to the imaging holder; a driving apparatus disposed on a base end side of the driving rods and driving forward and backward at least one of the driving rods in each of the driving force transmission mechanisms; and a cover member extending from a base member of the driving apparatus and covering at least a portion of the imaging unit, the imaging holder, and the driving force transmission mechanisms. The imaging unit rotates around two different axes according to forward and backward movement of the driving rods.

Abstract: An impedance matching apparatus includes: a cable that transmits a rectangular wave outputted from a solid image pickup device; a correlated double sampling circuit that performs scanning of the rectangular wave by sampling the rectangular wave with a timing of a signal clamp pulse being changed, based on a timing of the feed-through sampling pulse fixed at a timing at which the rectangular wave by the cable indicates a high value; a variable resistance provided at a tail end side of the cable; and a resistance value varying unit that, that performs the scanning with a resistance value of the variable resistance being changed, based on a signal outputted from the correlated double sampling circuit, changes a resistance value of the variable resistance so as to match a characteristic impedance of the cable.

Abstract: An imaging mechanism and an endoscope apparatus include: an image sensor including a sensor face and a plurality of input/output leads, a holding member having a sensor contact face, a circuit board that is secured to an outer face of an opposite side of the holding member to the sensor contact face, and a contact-point part disposed on a side face of the circuit board intersecting with a mount face, and in a region where the outline of the circuit board is inside the outline of the holding member. At least one of the holding member and the circuit board includes a relay wiring part which the contact-point part and at least one of the input/output leads are electrically connected to.