An optical scope includes a body and an elongated shaft. The shaft distal end holds an optical assembly including an imaging lens with a field of view of at least 90 degrees. An LED is coupled to the body and has an output numerical aperture (NA) providing a critical angle larger than the field of view. A first pair of fiber bundles have proximal ends receiving light from the LED with distal ends presented at the shaft distal face, and an NA providing a critical angle less than the field of view. A second pair of fiber bundles also receive light from the LED with distal ends having at the shaft distal face, and have an NA providing a critical angle at least as large as the field of view. The bundles are positioned around imaging lens such that they create a light having a desired intensity profile and properties.

An electronic endoscope and an electronic endoscope system, wherein the electronic endoscope comprises a tube body (100), at least two lenses (200) having a non-zero-degree viewing angle, an image sensing component (300), and a transmission module. The tube body (100) comprises a light receiving channel penetrating therein for sequentially accommodating the lenses (200), the image sensing component (300), and the transmission module. Optical axes of the lenses (200) are parallel to an extension axis of the light receiving channel. The image sensing component (300) receives images transmitted by the lenses (200) and converts the same into electrical signals. The transmission module drives the lenses (200) having a non-zero-degree viewing angle to rotate about the optical axes in the same direction. When the field-of-view region of the electronic endoscope changes, the field-of-view direction does not change.

A video imaging system is provided. The video imaging system is configured to maintain a video image displayed on a display unit in a predetermined orientation based upon a use. The video imaging system includes an endoscope, a camera head unit, a camera control unit configured to determine a focal distance, and a display control unit. The display control unit is configured to process the focal distance to determine a use. The use is processed by the display control unit so as to maintain the video image in the predetermined orientation. The contextual information may be focal distance, image data or endoscopic orientation.

A video imaging system is provided. The video imaging system is configured to maintain a video image displayed on a display unit in a predetermined orientation based upon a use. The video imaging system includes an endoscope, a camera head unit, a camera control unit configured to determine a focal distance, and a display control unit. The display control unit is configured to process the focal distance to determine a use. The use is processed by the display control unit so as to maintain the video image in the predetermined orientation. The contextual information may be focal distance, image data or endoscopic orientation.

In one aspect of the present disclosure, a device may include a shaft having a distal end, and a tip at the distal end of the shaft. The tip may include an opening defined by a surface of the tip. An instrument inserted through the shaft may extend distally out of the opening. The device also may include an elevator for engaging the instrument. The elevator may include a proximal end fixed relative to the surface of the tip, a proximal portion extending distally from the proximal end, and a distal portion extending distally from the proximal portion. A force exerted on the elevator bends the proximal portion to deflect the distal portion without bending of the distal portion.

An imaging unit used in an oblique-viewing endoscope in which an endoscope axis along a longitudinal direction of a distal end portion of the endoscope and an optical axis of a lens unit cross along an observation direction includes: a semiconductor package including a light receiving surface arranged perpendicularly to the optical axis of the lens unit, an imaging device converting an optical image formed by the lens unit into an image signal, and a sensor electrode on a rear surface; a first circuit board including a first connecting electrode on a front surface and connected to the sensor electrode, and a second connecting electrode on a rear surface on which an electronic part is mounted; and a second circuit board including a first region including a third connecting electrode connected to the second connecting electrode, and a second region including a cable connecting electrode connected to a cable.

An optical path deflecting prism for endoscope which is used for observing an object in an oblique direction, includes a first prism and a second prism, and the first prism and the second prism are cemented. The first prism has a first polished surface and a second polished surface. The first reflecting surface is a mirror surface having a mirror coating applied to a polished surface of a flat plate, and is fixed by gluing to the fifth polished surface of the second prism upon adjusting an angle so as to correct an optical-axis shift which occurs due to a manufacturing error of the first prism and the second prism.

An endoscopic device is provided. The endoscopic device may comprise a distal end and a proximal end. The proximal end may be opposite the distal end. The endoscopic device may further comprise a handle at the proximal end and a tube extending from the handle towards the distal end of the endoscopic device. The endoscopic device may further comprise an accessory channel. The accessory channel may extend through the tube. The endoscopic device may further comprise a slide, the accessory channel extending through the slide, and a curved track disposed adjacent to the proximal end of the endoscopic device. The slide is movable within the curved track to cause movement of the accessory channel within the tube.

In one aspect of the present disclosure, a device may include a shaft having a distal end, and a tip at the distal end of the shaft. The tip may include an opening defined by a surface of the tip. An instrument inserted through the shaft may extend distally out of the opening. The device also may include an elevator for engaging the instrument. The elevator may include a proximal end fixed relative to the surface of the tip, a proximal portion extending distally from the proximal end, and a distal portion extending distally from the proximal portion. A force exerted on the elevator bends the proximal portion to deflect the distal portion without bending of the distal portion.

A borescope probe for inspecting a side wall of a cavity includes a primary mirror, a main refractive optical group, a stop, and a sensor plane. The primary mirror collects light rays diffused by a surface of the side wall of the cavity according to an inlet angle (α) and reflects the light rays towards the refractive optical group. The main refractive optical group is placed between the primary mirror and the sensor plane and is suitable to receive the light rays reflected by the primary mirror and focus them on the sensor plane.