A stereoscopic endoscope comprises at least one image sensor for sensing a first image and a second image of a pair of stereo images. The first image is sensed based on light passing through a first aperture within the stereoscopic endoscope and the second image is sensed based on light passing through a second aperture within the stereoscopic endoscope. The stereoscope endoscope comprises a liquid crystal layer disposed between two layers of glass comprising a first arrangement of electrodes, such that each of the first aperture and the second aperture is created in the liquid crystal layer using a portion of the first arrangement of electrodes, wherein a spacing between the first aperture and the second aperture, and a polarization state associated with each of the first and second apertures are controlled using corresponding control signals provided through the first arrangement of electrodes.

A stereo endoscope for capturing a first image which is provided to be observed by a first eye and a second image which is provided to be observed by a second eye, including a shaft with a distal end region, a first image sensor in the distal end region of the shaft, for capturing the first image, and a second image sensor in the distal end region of the shaft, for capturing the second image. The first image sensor and the second image sensor are arranged offset relative to one another in a direction which is parallel to at least either a light-sensitive layer of the first image sensor or a light-sensitive layer of the second image sensor and which is orthogonal to a longitudinal axis the distal end region of the shaft. The first image sensor and the second image sensor are oriented in opposite directions.

A stereoscopic endoscope comprises a first lens train; a second lens train; a prism; and a continuous image sensor surface. The first lens train directs light along a first path through the first lens train and the prism to be incident on a first region of the continuous image sensor, and the second lens train directs light along a second path through the second lens train and the prism to be incident on a second region of the continuous image sensor.

A stereoscopic optical system including: left and right channels; an electromagnetic actuator including a stator and rotor; wherein first optical components of the left channel are arranged in a left tube and second optical components of the right channel are arranged in a right tube; the stator is arranged outside the guide tubes; the rotor includes a left rotor, in which one or more of the first optical components is accommodated, and a right rotor, in which one or more of the second optical components is accommodated; the left and right rotors are mounted in one of the left and right tubes to be movable in a longitudinal axial direction; the left and right rotors include paramagnetic and/or ferromagnetic material and are movable by an electromagnetic field; the stator includes distal and proximal permanent magnets oppositely polarized; and the stator includes an electric coil for generating the electromagnet field.

An image pickup apparatus includes: a plurality of image pickup devices configured to pick up images of a same object and sequentially read the images for each line; an objective optical system configured to form the images at different image-forming positions on the image pickup devices; a memory configured to record predetermined time differences for reading the leading positions of the effective pixels of the images at the same timing; and an I2C control circuit configured to control the image reading timing of the image pickup devices by generating a plurality of synchronizing signals based on a master synchronizing signal and supplying the synchronizing signals to the image pickup devices after shifting the synchronizing signals by the respective predetermined time differences.

A stereoscopic endoscope includes at least one illumination source disposed at a distal end portion in a position to project light to illuminate an object. The endoscope also includes an image capture assembly mounted at the distal end portion. The assembly includes first and second lens trains extending proximally from the distal end portion. The assembly includes an image sensor having a surface with a right side image area and a left side image area. The sensor surface lies in a plane substantially parallel to a plane in which the first and second lens trains lie. The assembly includes at least one optical element disposed to intercept light passing through the first and second lens trains. The optical element is configured to direct light exiting the first lens train to the right side image area and to direct light exiting the second lens trains to the left side image area.

A flexible high-resolution endoscope apparatus and methods involving a plurality of optical fiber bundles; a plurality of lenses in a one-to-one correspondence with the plurality of optical fiber bundles, each lens of the plurality of lenses comprising a distinct depth of field and a distinct angle of view in relation to another lens of the plurality of lenses; and a plurality of cameras in a one-to-one correspondence with the plurality of optical fiber bundles.

An optical system of a stereo-video endoscope with a sideways viewing direction, the optical system including: a sideways-viewing distal optical assembly; and a proximal optical assembly; wherein the distal optical assembly includes an inlet lens, a deflecting unit configured as a prism unit, and an outlet lens on a common optical axis one after the other in the direction of light incidence, the proximal optical assembly includes a left and a right lens system channel, the lens system channels being identically configured and arranged parallel to each other, each lens system channel having its own optical axis, and the outlet lens is formed with one or more of a light-impermeable coating on a light inlet side facing the deflecting unit and with a light-impermeable coating formed on a light outlet side facing away from the deflecting unit in a central region of the outlet lens.

An imaging condition set in a first region of a three-dimensional model of a subject and an imaging condition set in a second region of the three-dimensional model are different from each other. A processor of an observation device determines whether or not the imaging condition that has been set in the first region or the second region including a position on the three-dimensional model is satisfied. The position is identified on the basis of a position of an imaging device and a posture of the imaging device. The processor displays observation information on a display on the basis of a result of determination. The observation information represents whether or not the first region or the second region including the position on the three-dimensional model has been observed.

An imaging device according to the present invention includes: first and second image sensors that respectively capture a first optical image and a second optical image having parallax with each other; a first imaging optical system that forms the first optical image on a light receiving surface of the first image sensor; and a second imaging optical system that forms the second optical image on a light receiving surface of the second image sensor. Each of focal positions of the first imaging optical system and the second imaging optical system is deviated along an optical axis direction and is positioned within mutual depth of field.