Abstract: A video scope has an image sensor, a circuit board, and a digital signal processor mounted on the circuit board. The digital signal processor reads image signals from the image sensor, and processes the read image signals to thereby produce at least two types of video signal. A wiring-pattern is formed on the circuit board to feed a video signal component, included in one of the two types of video signals, from the digital signal processor. The wiring-pattern is cut off at a suitable location. When the wiring-pattern remains as an unused wiring-pattern on the circuit board, the wiring-pattern is treated such that radiation of noise is prevented from going through the unused wiring-pattern.

Abstract: A printed circuit board structure for a scope unit of an electronic endoscope system, which is provided with a first printed circuit board formed with a first circuit section, and a second printed circuit board formed with a second circuit section. The first printed circuit board is piled on the second printed circuit board. The second printed circuit board having an area covered with the first printed circuit board and at least one area which is not covered with the first circuit board. The at least one area is used for electrically connecting the second circuit section with an electrical unit other than the second circuit section.

Abstract: An endoscope 2 has a CCD 9 incorporated in the distal part of an insertion unit 6 thereof. The sensitivity of the CCD 9 can be varied by applying a plurality of pulsating driving signals so as to change an electron multiplication rate. The endoscope 2 is connected to a processor 3 so that it can be disconnected freely. Information representing a type of endoscope stored in advance in a ROM 48 is transmitted to a controller 21 incorporated in the processor 3. The control means 21 uses a CCD sensitivity control means 12 to control the sensitivity of the CCD 9 according to the type of connected endoscope 2. In addition, an automatic gain control circuit supplementarily amplifies a signal output from the CCD 9 so that the level of the signal becomes a predetermined level. Consequently, a view image of proper brightness can be produced irrespective of the type of endoscope 2.

Abstract: When an endoscopic imaging system is employed in, for example, the department of otorhinology, a color processing expansion substrate, a still image production expansion substrate, and a still image compression/recording substrate are stacked on an expansion connector formed on a main substrate and are thus connected to the main substrate. A data bus and an address bus extending from a control unit mounted on the main substrate are linked to the expansion substrates. A sync signal generator outputs various kinds of sync signals including a clock signal CLK, a horizontal sync signal HD, a vertical sync signal VD, a field identification signal FLD, and a composite sync signal CSYNC to the expansion substrates.

Abstract: A reduced area imaging device is provided for use with a communication device, such as a wireless/cellular phone. In one configuration of the imaging device, the image sensor is placed remote from the remaining image processing circuitry. In a second configuration, all of the image processing circuitry to include the image sensor is placed in a stacked fashion near the same location. In the first configuration, the entire imaging device can be placed at the distal end of a camera module. In a second configuration, the image sensor is remote from the remaining image processing circuitry wherein available space within the phone is used to house the remaining circuitry. In any of the embodiments, the image sensor may be placed alone on a first circuit board, or timing and control circuits may be included on the first circuit board containing the image sensor.

Abstract: A sampling pulse generator for an electronic endoscope that comprises a CDS circuit, OR circuits, a clock pulse generator, a shift counter, first and second switch groups, EEPROM and a CPU, is provided. The generator cyclically generates clock pulses. The pulses are cyclically counted between 0 and 9 by the counter. The counter has ten output terminals that correspond to each of the count numbers. A signal is only output to a terminal corresponding to the current count number. Each of the first and second switch groups has ten switches that are connected to each of the terminals. With data in the EEPROM, the on-off states of the switches are set by the CPU. The CCD drive pulses are generated by signals from the terminals via OR circuits. The clamp pulse and sample-hold pulse are generated by signals from the switch groups which are set in the on state.

Abstract: One expansion substrate or a plurality of expansion substrates that realize different facilities can be connected to a main substrate that realizes basic processing to be performed by a CCU. Based on an ID number produced by an ID generation unit mounted on a connected expansion substrate, a CPU incorporated in the CCU identifies the facility realized with the expansion substrate. A menu screen image presents item BOD Control under which the facilities are presented. When item BOD Control is designated, a BOD Control screen image that lists control items indicating the facilities realized with all the expansion substrates that are connected to the main substrate is displayed. When a concrete facility such as a P-in-P facility realized with an expansion substrate is selected or designated in the BOD Control screen image, a screen image concerning the designated P-in-P facility is displayed. Thus, the details of a facility that is realized with a connected expansion substrate can be set easily.

Abstract: The invention is intended for rendering a CMOS camera compact and less costly. A semiconductor device constituting a CMOS camera system includes a lens unit which includes a wiring board having an image pick-up opening formed therein and a lens, and the lens is provided on one side of the wiring board and positioned opposite the image pick-up opening. An image pick-up semiconductor is provided on the other side of the wiring board, and is positioned opposite the image pick-up opening, and is connected to a connection section of the wiring board by means of flip-chip bonding. An image processing semiconductor is connected by means of flip-chip bonding to another connection section provided on the other side of the wiring board, and processes an image signal output from the image pick-up semiconductor.

Abstract: When an endoscopic imaging system is employed in, for example, the department of otorhinology, a color processing expansion substrate, a still image production expansion substrate, and a still image compression/recording substrate are stacked on an expansion connector formed on a main substrate and are thus connected to the main substrate. A data bus and an address bus extending from a control unit mounted on the main substrate are linked to the expansion substrates. A sync signal generator outputs various kinds of sync signals including a clock signal CLK, a horizontal sync signal HD, a vertical sync signal VD, a field identification signal FLD, and a composite sync signal CSYNC to the expansion substrates.

Abstract: An energy saving device for acquiring in vivo images of the gastro-intestinal tract is provided. The device, such as an autonomous capsule, includes at least one imaging unit; a control unit connected to the imaging unit and a power supply connected to the control unit. The control unit includes a switching unit and an axial motion detector connected to the switching unit. The axial motion detector detects the axial movement of the device and if the axial acceleration is below a pre-determined threshold, disconnects the power supply thereby preventing the acquisition of redundant images.

Abstract: When an endoscopic imaging system is employed in, for example, the department of otorhinology, a color processing expansion substrate, a still image production expansion substrate, and a still image compression/recording substrate are stacked on an expansion connector formed on a main substrate and are thus connected to the main substrate. A data bus and an address bus extending from a control unit mounted on the main substrate are linked to the expansion substrates. A sync signal generator outputs various kinds of sync signals including a clock signal CLK, a horizontal sync signal HD, a vertical sync signal VD, a field identification signal FLD, and a composite sync signal CSYNC to the expansion substrates.

Abstract: When an endoscopic imaging system is employed in, for example, the department of otorhinology, a color processing expansion substrate, a still image production expansion substrate, and a still image compression/recording substrate are stacked on an expansion connector formed on a main substrate and are thus connected to the main substrate. A data bus and an address bus extending from a control unit mounted on the main substrate are linked to the expansion substrates. A sync signal generator outputs various kinds of sync signals including a clock signal CLK, a horizontal sync signal HD, a vertical sync signal VD, a field identification signal FLD, and a composite sync signal CSYNC to the expansion substrates.

Abstract: In an endoscopic imaging system, a signal representing an object image produced by a scope and projected by a camera head is processed by a CCU and displayed as an endoscopic image on a TV monitor. The object image is stored as digital image data on a memory in the CCU, read as image data of a still image, and recorded on a PC card mounted in a PC card slot. The PC card slot is formed in the front panel or the like of the CCU. A lid member or the like functioning as an anti-liquid invasion member and shield can be located at an opening of the slot.

Abstract: The object of the present invention is to provide a solid-state imaging device making it possible to downsize an imaging unit and further decrease the diameter of the front end of an electronic endoscope.

Abstract: One expansion substrate or a plurality of expansion substrates that realize different facilities can be connected to a main substrate that realizes basic processing to be performed by a CCU. Based on an ID number produced by an ID generation unit mounted on a connected expansion substrate, a CPU incorporated in the CCU identifies the facility realized with the expansion substrate. A menu screen image presents item BOD Control under which the facilities are presented. When item BOD Control is designated, a BOD Control screen image that lists control items indicating the facilities realized with all the expansion substrates that are connected to the main substrate is displayed. When a concrete facility such as a P-in-P facility realized with an expansion substrate is selected or designated in the BOD Control screen image, a screen image concerning the designated P-in-P facility is displayed. Thus, the details of a facility that is realized with a connected expansion substrate can be set easily.

Abstract: A video scope has an image sensor, a circuit board, and a digital signal processor mounted on the circuit board. The digital signal processor reads image signals from the image sensor, and processes the read image signals to thereby produce at least two types of video signal. A wiring-pattern is formed on the circuit board to feed a video signal component, included in one of the two types of video signals, from the digital signal processor. The wiring-pattern is cut off at a suitable location. When the wiring-pattern remains as an unused wiring-pattern on the circuit board, the wiring-pattern is treated such that radiation of noise is prevented from going through the unused wiring-pattern.

Abstract: A PNP bipolar transistor or an enhancement mode P-channel FET is used as a buffer to drive a video signal from an imager to video processing circuits. An endoscope with a solid state imager having a negative-going video pulse is used, with a video buffer located at or near the distal end to buffer the CCD video signal. The buffer employs a PNP bipolar transistor that is biased by a bias circuit for the base and a power supply for the collector, both located near the transistor, and a load for the emitter located at some distance from the transistor.

Abstract: A reduced area imaging device is provided for use with a miniature hand-held computer referred to in the industry as a PDA. In one configuration of the imaging device, the image sensor is placed remote from the remaining image processing circuitry. In a second configuration, all of the image processing circuitry to include the image sensor is placed in a stacked fashion near the same location. In the first configuration, the entire imaging device can be placed at the distal end of a camera module. In a second configuration, the image sensor is remote from the remaining image processing circuitry wherein available space within the PDA is used to house the remaining circuitry. In any of the embodiments, the image sensor may be placed alone on a first circuit board, or timing and control circuits may be included on the first circuit board containing the image sensor.

Abstract: An electronic endoscope system comprises an electronic endoscope unit equipped with a solid state image pickup element for providing electric signals of an object and a processing unit for processing the electric signals to video signals. During performing black balance adjustment, the processing unit interrupts only vertical transfer signals included in drive signals, vertical and horizontal drive signals, for driving the solid state image pickup element so as to cause the solid state image pickup element to provide electric signals at the same level as electric signals that the solid state image pickup element provides while it is in isolated from ambient light.

Abstract: A reduced area-imaging device is provided for use with a miniature hand-held computer referred to in the industry as a PDA. In one configuration of the imaging device, the image sensor is placed remote from the remaining image processing circuitry. In a second configuration, all of the image processing circuitry to include the image sensor is placed in a stacked fashion near the same location. In the first configuration, the entire imaging device can be placed at the distal end of a camera module. In a second configuration, the image sensor is remote from the remaining image processing circuitry wherein available space within the PDA is used to house the remaining circuitry. In any of the configurations, the image sensor may be placed alone on a first circuit board, or timing and control circuits may be included on the first circuit board containing the image sensor.

Abstract: The present invention is an imaging element assembly unit in which it can easily be promoted to make the diameter of the tip portion of an endoscope thinner by changing the configuration of a circuit board in relation to an image element. In this assembly unit, an imaging element body formed while holding a lead portion between an electrode of a CCD and a cover glass is produced, for example, on the TAB system, and this imaging element body is connected to a circuit board having a storing groove. Then, the width in the electrode arranging direction of this circuit board is formed shorter than the width in the electrode arranging direction of the CCD, and at a position where both ends of this circuit board retreat from both ends of the CCD, these are connected by a lead portion. By doing so, the diameter of the tip portion can be made thinner since the sides of both ends of the circuit board arranged on the side of the inside peripheral surface of a tip portion holding barrel retreat inside.

Abstract: The present invention provides a system and method for obtaining in vivo images. The system contains an imaging system and an ultra low power radio frequency transmitter for transmitting signals from the CMOS imaging camera to a receiving system located outside a patient. The imaging system includes at least one CMOS imaging camera, at least one illumination source for illuminating an in vivo site and an optical system for imaging the in vivo site onto the CMOS imaging camera.

Abstract: A reduced area imaging device is provided for use in medical or dental instruments such as an endoscope. In one configuration of the imaging device, the image sensor is placed remote from the remaining circuitry. In another configuration, all of the circuitry to include the image sensor is placed in a stacked fashion at the same location. In a first embodiment of the invention, the entire imaging device can be placed at the distal tip of an endoscope. In a second embodiment, the image sensor is remote from the remaining circuitry according to the first configuration, and wherein a control box can be provided which communicates with the image sensor and is placed remotely from the endoscope. In another embodiment, the imaging device can be incorporated in the housing of a standard medical camera which is adapted for use with traditional rod lens endoscopes.

Abstract: A reduced area imaging device is provided for use in medical or dental instruments such as an endoscope. In one configuration of the imaging device, the image sensor is placed remote from the remaining circuitry. In another configuration, all of the circuitry to include the image sensor is placed in a stacked fashion at the same location. In a first embodiment of the invention, the entire imaging device can be placed at the distal tip of an endoscope. In a second embodiment, the image sensor is remote from the remaining circuitry according to the first configuration, and wherein a control box can be provided which communicates with the image sensor and is placed remotely from the endoscope. In yet another embodiment, the imaging device can be incorporated in the housing of a standard medical camera which is adapted for use with traditional rod lens endoscopes.

Abstract: An electronic endoscope system that provides, even when it uses a halogen lamp, an image having a brightness equal to that of an image obtained with a xenon lamp. The electronic endoscope system leads rays emitted from a halogen lamp to the tip of an electronic endoscope through a light guide, picks up an internal image of an object to be observed with a CCD through an objective optical system and reads out twice each of an odd field signal and an even field signal successively when a slow scan mode is selected. The odd or even field signal from each field is delayed by a delay memory in a luminance enhancement circuit, and the same field signals are added by an adder. The electronic endoscope system performs image processing of an addition signal thus obtained as a single odd or even field signal, thereby being capable of enhancing the luminance signal, for example, to a level twice as high.

Abstract: Configurations of a reduced area imaging device include the image sensor placed remote from the remaining circuitry, or all of the circuitry to include the image sensor placed in a stacked fashion at the same location. The entire imaging device can be placed at the distal tip of an endoscope or within a simple tubular structure, or the image sensor can be remote from the remaining circuitry, wherein a control box which communicates with the image sensor is placed remotely from the image sensor. The imaging device can be incorporated in the housing of a standard medical camera adapted for use with traditional rod lens endoscopes. In any of the configurations, the image sensor may be placed alone on a first circuit board, or timing and control circuits may be included on the first circuit board containing the image sensor. One or more video processing boards can be stacked in a longitudinal fashion with respect to the first board, or the video processing boards may be placed in the control box.

Abstract: An electronic endoscope with which the electrical insulation between side faces of a solid-state imaging element and inner leads of a flexible circuit board will be secured and with which the external dimension after assembly of the unit comprised of the solid-state imaging element and the flexible circuit board can be made small. The inner leads of the flexible circuit board are bonded to pad parts disposed on the solid-state imaging element, and these inner leads are bent so as to be disposed along the side faces of the solid-state imaging element. An electrically insulating tape is attached to the side faces of the solid-state imaging element along which inner leads are disposed.

Abstract: An endoscope system is provided with an endoscope unit which emits an excitation light to an object to be observed and receives a fluorescent light emitted by the object, a filtering optical element, which extracts a predetermined component of the fluorescent light received by the endoscope unit, an image capturing device, which receives an image formed by the predetermined component of the fluorescent light, an amplifier, which amplifies an output signal of the image capturing device, and a gain controller, which automatically controls a gain of the amplifier in accordance with the output signal of the image capturing element.

Abstract: A reduced area imaging device is provided for use in medical or dental instruments such as an endoscope. In one configuration of the imaging device, the image sensor is placed remote from the remaining circuitry. In another configuration, all of the circuitry to include the image sensor is placed in a stacked fashion at the same location. In a first embodiment of the invention, the entire imaging device can be placed at the distal tip of an endoscope. In a second embodiment, the image sensor is remote from the remaining circuitry according to the first configuration, and wherein a control box can be provided which communicates with the image sensor and is placed remotely from the endoscope. In yet another embodiment, the imaging device can be incorporated in the housing of a standard medical camera which is adapted for use with traditional rod lens endoscopes.

Abstract: An electronic endoscope system includes an electronic endoscope, and a video processor. The video processor transmits a clock signal to the electronic endoscope in order to generate a driving signal for driving a CCD provided therein. The clock signal transmitted from the video processor has a sinusoidal waveform, and the electronic endoscope has a circuit which generates the driving signal based on the clock signal transmitted from the video processor. The driving signal is a periodical signal having a rectangular waveform. Further, a signal transmission line, which transmits the driving signal from the circuit to the CCD, is inserted into and wound around a ferrite material.

Abstract: A reduced area imaging device is provided for use in medical or dental instruments such as an endoscope. In one configuration of the imaging device, the image sensor is placed remote from the remaining circuitry. In another configuration, all of the circuitry to include the image sensor is placed in a stacked fashion at the same location. In a first embodiment of the invention, the entire imaging device can be placed at the distal tip of an endoscope. In a second embodiment, the image sensor is remote from the remaining circuitry according to the first configuration, and wherein a control box can be provided which communicates with the image sensor and is placed remotely from the endoscope. In yet another embodiment, the imaging device can be incorporated in the housing of a standard medical camera which is adapted for use with traditional rod lens endoscopes.

Abstract: An adhesive agent 116 is coated to a peripheral flat portion 115 of an optical glass 113. A center flat portion 114 is mounted to an opening portion 108 of a TAB tape 105 from the reverse side of which copper leads 107 are formed. Thus, the optical glass 113 and the TAB tape 105 are adhered. At this point, the center flat portion 114 and the TAB tape 105 are arranged almost on the same plane. Thus, protrusion of the adhesive agent 116 and foreign matter stuck on the optical glass 113 can be easily and securely removed.

Abstract: A reduced area imaging device is provided for use in medical or dental instruments such as an endoscope. In one configuration of the imaging device, the image sensor is placed remote from the remaining circuitry. In another configuration, all of the circuitry to include the image sensor is placed in a stacked fashion at the same location. In a first embodiment of the invention, the entire imaging device can be placed at the distal tip of an endoscope. In a second embodiment, the image sensor is remote from the remaining circuitry according to the first configuration, and wherein a control box can be provided which communicates with the image sensor and is placed remotely from the endoscope. In yet another embodiment, the imaging device can be incorporated in the housing of a standard medical camera which is adapted for use with traditional rod lens endoscopes.

Abstract: A video camera isolation system and method for use with video cameras that are coupled to endoscopes that utilize simple pulse transformer technology to isolate the video camera head from the video processing circuitry allowing the processing circuitry to be referenced to ground. The video signal from the CCD sensor in the camera head is specifically processed to prevent shutter pulses from interfering with the isolated video signal. Special circuitry blanks the shutter pulse from the pulse transformer. Timing errors due to cable length delays are corrected by means of a pilot signal which correlates with the CCD output signal. Open collector data circuitry is also specially processed by dual channel detecting and amplifying circuits which are transistor switched through the pulse transformers before being delivered to and from the camera head.

Abstract: In an image pickup apparatus arranged to carry out a predetermined signal processing action including a gamma correction process on a signal outputted from an image sensor and to invert the signal during the process of the signal processing action, a varying circuit is arranged to vary a gamma value to be used for the gamma correction process.

Abstract: An electronic endoscope system which includes a device for detecting an image, and a device for inputting an information signal. The image detecting device outputs an electrical image signal, which is converted to an analog video signal and a digital video signal. The digital video signal is combined with the information signal by an image combining device, to form a digital information signal. The digital information signal is serially outputted to a device which displays the image data in accordance with the outputted serial digital information signal. The digital information signal is also serially outputted to a device which reproduces the information signal in accordance with the outputted serial digital information signal.

Abstract: A video camera system stores operating parameter information for reading by the system to provide optimum operating conditions, collects information reflecting system uses for later reading by the system to provide a performance history, and is relatively small and operates with a reduced number of electrical lines to transmit electrical information.

Abstract: An endoscope apparatus including an endoscope, a supply portion for supplying a required signal or energy to a peripheral unit relating to the endoscope; and a control portion for controlling the supply portion, wherein the control portion is constituted to have at least one field programmable gate array and a function required by at least either of the endoscope or the peripheral unit relating to the endoscope is realized by receiving circuit information for constituting a control circuit for controlling the supply portion to selectively write the circuit information on the field programmable gate array so that the control circuit is constituted.

Abstract: An assembled body of an electronic endoscope which is capable of reducing the diameter of the endoscope and simplifying the structure thereof. The assembled body comprises an imaging device provided with a color filter and a microlens on the imaging plane, and an objective optical member connected to the imaging device. A circuit board with a wiring pattern and a through hole formed thereon and therein is inserted and adhered between the imaging plane of the imaging device and a prism as a part of the objective optical member. The terminals on the imaging device are connected to the terminals on the circuit board by contact bonding. Since the through hole in the circuit board forms an air gap on the imaging plane, it is possible to protect the color filter and the microlens.

Abstract: A solid state imager assembly for use in an insertion tube of a video endoscope that includes a TAB imager package having fine pitch leads extending outwardly to either side of the imager. A transparent window covers the imager. A first hybrid board is attached to one set of leads and a second hybrid circuit board is attached to the second set of leads. The boards are turned downwardly to either side of the imager and placed in opposed parallel alignment beneath the imager. Circuitry is mounted on the opposed inside surfaces of the boards. A block of encapsulating material is placed between the boards to encapsulate the circuitry therein and provide structural support to the package.

Abstract: An endoscope including an insertion tube containing a TAB imager package in the distal end thereof. The imager is mounted in a complementary opening formed in a circuit board and the board is aligned along the central axis of the insertion tube. Fine pitch leads extend from between the imager and a transparent window covering the imager to both sides of the imager. The leads are bonded to traces on the board which connect the leads to circuitry mounted on the board. A reflecting surface optically couples the imager to a forward viewing lens system.

Abstract: A video camera isolation circuit for use with video cameras that are coupled to endoscopes utilizes simple pulse transformer technology to isolate the video camera head from the video processing circuitry allowing the processing circuitry to be referenced to ground. The video signal from the CCD sensor in the camera head is specially processed to prevent shutter pulses from interfering with the isolated video signal. Special circuitry blanks the shutter pulse from the pulse transformer. Open collector data circuitry is also specially processed by dual channel detecting and amplifying circuits which are transistor switched through the pulse transformers before being delivered to and from the camera head. Timing pulses are processed through logic buffering conditioning circuitry and pulse transformers for reconstruction on the secondary of the pulse transformer by hysteresis buffers.

Abstract: A video camera head for use with medical diagnostic instrumemts. A connector assembly, positioned at the outlet of the housing of the camera head, allows a video cable including a multi-conductor tightenable connector to be attached to and detached from the fragile internal wiring of the camera head without applying destructively high forces thereto. A mounting assembly, positioned at the inlet of the housing of the camera head, enclose and protects a video imaging chip while securely mounting the same in a predetermined position and orientation within the housing of the camera head.

Abstract: An in vivo video camera system and an autonomous video endoscope are described. Each system includes a swallowable capsule, a transmitter and a reception system. The swallowable capsule includes a camera system and an optical system for imaging an area of interest onto the camera system. The transmitter transmits the video output of the camera system and the reception system receives the transmitted video output.

Abstract: An assembly for a combustion chamber monitoring camera comprises an image-forming optical system (20) whose object space (26) is a combustion chamber and whose image plane (5) is coincident with the photosensitive element of the camera, and whose focal point (24) on the object space side is situated outside the optical system (20), and a structure (22) enclosing the optical system (20). on the object space side of the optical system (20), a solid baffle plate (38) is placed having a hole (1) made cocentrical with the center axis of the optical system (20) and situated at the focal point (24) of the entire optical system on the object space side, or in the vicinity thereof, and the structure (22, 40) encloses the optical system (20) in such a manner that purging air can be fed via the hole (1) along a channel (32, 34) positioned between the optical system (20) and the enclosing structure (22, 40) thereof in the combustion chamber.

Abstract: A shielding structure of an electronic endoscope apparatus which can sufficiently remove noise even when an electric cautery is used. A signal transmission cable which connects a charge coupled device disposed at the end portion of an electronic endoscope to a processor unit is electrically shielded by a double shield composed by an inner shield and an outer shield. The inner shield is connected to the ground in a light source connector and the outer shield is connected to the frame ground of the processor unit through a capacitor. The outer shield is further connected to a shielding member provided around the charge coupled device and a patient ground to which an electrode piece of an electric cautery is connected. Noise is greatly removed, so that the picture quality is improved.

Abstract: A plurality of leads are formed on a wiring board which is adhered onto a light transmitting member for transmitting a light beam. A plurality of electrode pads are formed, corresponding to the leads, on a photoelectric converting device. An anisotropically conductive film is formed between each of the leads and each of the corresponding electrode pads.

Abstract: An endoscope image data compressing apparatus comprises a plurality of image compressing apparatus not equivalent to each other for compressing input endoscope image data and outputting the compressed data and a selecting apparatus for selecting the compressed data output from at least one of the image compressing apparatus. The selecting apparatus selects the compressing method in response to the kind of the endoscope, characteristic of the image, picture quality of the compressed image, recording time intervals and others.A method for compressing endoscope image data is realized by an image compressing apparatus capable of compressing image data at different compressing rates. The endoscope image data is determined to be either ordinary image data or dyed image data and, based on this determination, is compressed at different rates. The compressing rate for dyed image data is lowered below the rate for ordinary image data.

Abstract: A video laparoscope has a miniature video camera disposed at the distal end of its insertion tube. A removably installed tubular lens cell contains one or more focussing lenses. The lens cell has a male-threaded first end and a second end on which is formed a radial flange of a predetermined diameter. A tubular lens retainer canister is fixedly mounted in the distal end of the insertion tube, and has an outer distal portion with a diameter to match the diameter of the flange. A sealing portion adjacent to this has a smaller diameter, and biases against an O-ring or similar sealing member. A female-threaded proximal portion is screwed into the male-threaded first portion of the lens cell.

Abstract: A video endoscope has in its distal end region an objective lens, a semi-conductor imager assigned to it and further electronic components provided for wiring it. In order to further reduce the required diameter of the endoscope shaft compared to the known designs, the electronic components are arranged on an integral ceramic substrate, on which the conductors for joining and for connecting these parts are directly placed.