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 optical system for stereoscopic vision includes a first optical system and a second optical system. Each of the first optical system and the second optical system includes a front unit, a stop, and a rear unit having a positive refractive power. Each of the two front units includes a first negative lens, and the first negative lens is a lens positioned nearest to an object. Each of the two stops moves in a direction parallel to a plane including an optical axis of the first optical system and an optical axis of the second optical system. Both the stops move to be drawn away from a central axis or move to come closer to the central axis, and the following conditional expressions (1) and (2) are satisfied:

20.0<FLFGn1/IH<0.5(1)

1.5<Ls/IH<7.5(2).

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-vision endoscope optical system includes a pair of objective optical systems, a pair of relay optical systems, and a pair of image forming optical systems. The image forming optical system includes a first lens unit, a first optical-path bending element, and a second optical-path bending element. The objective optical system and the relay optical system are disposed in a first optical path. A second optical path is formed between the first optical-path bending element and the second optical-path bending element. A third optical path is formed between the second optical-path bending element and a final image. The second optical path is positioned farther from the central axis, than the first optical path. The third optical path is positioned closer to the central axis, than the second optical path.

An integrated image sensor for capturing a mixed structured-light image and regular image using an integrated image sensor are disclosed. The integrated image sensor comprises a pixel array, one or more output circuits, one or more analog-to-digital converters, and one or more timing and control circuits. The timing and control circuits are arranged to perform a set of actions including capturing a regular image and a structured-light image. According to the present invention, the structured-light image captured before or after the regular image is used to derive depth or shape information for the regular image. An endoscope based on the above integrated image sensor is also disclosed. The endoscope may comprises a capsule housing adapted to be swallowed, where the components of integrated image sensor, a structured light source and anon-structured light source are enclosed and sealed in the capsule housing.

An image acquisition device including: an imaging optical system forming two images having parallax; and an element acquiring the parallax images, the imaging optical system includes: a first negative lens group having negative refractive power; a first positive lens group having positive refractive power; and a second positive lens group having positive refractive power, the first negative lens group includes two negative lens groups disposed side by side in the parallax direction and having central axes respectively, the first positive lens group is a common lens group having a single central axis, and light rays emitted from the negative lens groups pass therethrough, the second positive lens group includes two positive lens groups disposed side by side in the parallax direction and having central axes respectively and the first positive lens group includes a moving lens group moved along the central axis of the first positive lens group.

A novel dual-path-endoscope where a multi-function light source produces a first-light and a second-light toward an object. The first-light exhibits first-light-characteristics. The second-light exhibits second-light-characteristics different from the first-light-characteristics. The endoscope includes two light-paths, the disparity there between is larger than zero. Each light-path includes a respective pupil and a respective light-separator coupled with the pupil, transmitting there through one of the first-light and the second-light, associating the first-light and the second-light with a respective light-path. The dual-channel-imager includes two imager sensors, each associated with a respective light-path and optically coupled with a respective light-separator. Each imaging-sensor exhibits sensitivity to the characteristics of the respective one of the first-light and the second-light. A first imaging-sensor acquires a first-image of the first-light reflected of the object and a second imaging-sensor acquires a second-image of the second-light reflected of the object. The processor processes the acquired images.

The technology described herein can be embodied in a stereoscopic endoscope in which the orientation of the two eyes may be determined dynamically as the endoscope is moved and rotated. This may enable an improved user-experience when using an angled stereoscopic endoscope even when it is rotated, for example, to view the sides of a cavity.

An optical system for an endoscope, the optical system including: a distal optical assembly; a proximal optical assembly; and at least one elongated bar-shaped fixing element; wherein the proximal optical assembly is fastened to the distal optical assembly by the fixing element.

A stereoscopic vision endoscope objective optical system includes, in order from an object side, a first lens group having a negative refractive power, a second lens group having a positive refractive power, and a rear-side lens group having a positive refractive power. The rear-side lens group includes a first rear group and a second rear group. The first lens group and the second lens group are disposed so that an optical axis of the second lens group coincides with an optical axis of the first lens group. The optical axis of the first lens group is located between an optical axis of the first rear group and an optical axis of the second rear group. Each of the first rear group and the second rear group includes a first sub group, an aperture stop, and a second sub group, and the first sub group includes a negative lens.