The disclosure relates to a viewing optic. In one embodiment, the disclosure relates to a viewing optic having an integrated display system. In one embodiment, the disclosure relates to a viewing optic having an integrated display system for generating images that are projected into the first focal plane of an optical system.

The disclosure relates to a viewing optic. In one embodiment, the disclosure relates to a viewing optic having an integrated display system. In one embodiment, the disclosure relates to a viewing optic having an integrated display system for generating images that are projected into the first focal plane of an optical system.

An endoscope or other endoscopic instrument is provided with multiple image sensors incorporated into the distal tip, each capturing a portion of the image provided from an optical imaging system. The output from the multiple sensors is combined and manipulated into a single high resolution image which can then be displayed to the user. A virtual horizon rotation feature is also provided which can rotate a displayed image within a combined field of view including data from the multiple image sensors. Various light directing element designs are provided to direct image light to the multiple sensors.

An endoscope or other endoscopic instrument is provided with multiple image sensors incorporated into the distal tip, each capturing a portion of the image provided from an optical imaging system. The output from the multiple sensors is combined and manipulated into a single high resolution image which can then be displayed to the user. A virtual horizon rotation feature is also provided which can rotate a displayed image within a combined field of view including data from the multiple image sensors. Various light directing element designs are provided to direct image light to the multiple sensors.

An optical system for a microscope for imaging an object includes: a telescope system having an optical correction unit, which is adjustable in order to correct a spherical imaging aberration, and having a zoom optical unit, which is adjustable in order to adapt a magnification of the telescope system to a ratio of two refractive indices, one of which is assigned to an object side and an other of which is assigned to an image side, within a predetermined magnification range. The telescope system is telecentric over an entire magnification range both with respect to the object side and with respect to the image side by the zoom optical unit contained in the telescope system.

An assembly and method of switching direction of camera view. The method comprises disposing a beam splitter element on a camera, the beam splitter element being configured such that first and second beams of light incident on first and second faces, respectively, of the beam splitter element are directable towards an entry lens of the camera; disposing first and second shutter elements in the paths of the first and second beams of light, respectively; and controlling the first and second shutter elements such that one of the first and second shutter elements is in an open state while the other one is in a closed state, and vice-versa.

Systems and methods are described which provide a film through scope camera mount including a housing that includes a beam splitter, first and second mirrors, and a sensor. The camera mount system may receive an input optical signal from a first direction; split the input optical signal using the beam splitter such that a first portion of the input optical signal may be communicated out of the camera mount system in a second direction and a second portion of the input optical signal may be reflected lateral to the first direction; reflect the reflected signal vertically using the first mirror; reflect the vertically reflected signal in a second lateral direction using the second mirror; and receive the signal reflected by the second mirror in the sensor, which may comprise a visible light sensor and/or an infrared sensor.

Systems and methods are described which provide a film through scope camera mount including a housing that includes a beam splitter, first and second mirrors, and a sensor. The camera mount system may receive an input optical signal from a first direction; split the input optical signal using the beam splitter such that a first portion of the input optical signal may be communicated out of the camera mount system in a second direction and a second portion of the input optical signal may be reflected lateral to the first direction; reflect the reflected signal vertically using the first mirror; reflect the vertically reflected signal in a second lateral direction using the second mirror; and receive the signal reflected by the second mirror in the sensor, which may comprise a visible light sensor and/or an infrared sensor.

A supporting and handling system for optical devices, in particular telescopes, radio-telescopes or sun concentrators, and instrumentation, is described, comprising: a primary unit; an independent secondary unit; first motored means for moving the primary unit; second motored means for moving the secondary unit; an arc-shaped structure equipped with sliding guides in altitude with respect to the ground for the rotation of the secondary unit with respect to an altitude rotation axis; a hexapod system to move the primary unit; and a control system.

A supporting and handling system for optical devices, in particular telescopes, radio-telescopes or sun concentrators, and instrumentation, is described, comprising: a primary unit; an independent secondary unit; first motored means for moving the primary unit; second motored means for moving the secondary unit; an arc-shaped structure equipped with sliding guides in altitude with respect to the ground for the rotation of the secondary unit with respect to an altitude rotation axis; a hexapod system to move the primary unit; and a control system.