A scanner arrangement, suitable for use in laser scanning microscopes, for scanning a scanning field (42) by means of optical radiation (5). It is equipped with at least one scanner (1), which comprises a scanning mirror (2) that is tiltable about one or two scanning axes (3, 4) and means for rotating the scanning field, for scanning a size-variable scanning field and for centring the scanning field centre (43) when panning. The arrangement includes a mechanical pivot device (7) for rotating the scanning field (42). The pivot device is arranged to pivot the scanner (1) about a pivot axis (8). Pivoting is implemented through angular dimensions that correspond to an intended rotation of the scanning field.

An optical adapter for connecting between a beam splitter of a surgical microscope or an ophthalmic slit lamp microscope and a digital camera equipment including mobile phones, tablet computers, cameras, video cameras with image capturing function is provided. The optical adapter includes a lens group located on an optical path and an optical image rotating lens group for adjusting a direction of an optical image on a photosensitive unit of the digital camera equipment. The optical image rotating lens group is configured to be either independently rotatable around optical axis or be set fixedly. Embodiments of the present invention provide a system and method for real-time adjustment of the direction of an optical image on the photosensitive unit of a digital camera equipment, where regardless of the position of the digital camera a satisfactory direction of the optical image can be obtained with a simple user friendly and convenient structure.

Cameras with panoramic scanning range comprising a folded digital camera in which an optical path folding element (OPFE) that folds a first optical path from an object or scene into a second optical path substantially parallel with an optical axis of a lens of the folded camera, the OPFE being rotatable around the lens optical axis, and systems incorporating such cameras.

The current invention relates to an electrically actuated device for orientating an optical element around a rotational axis comprising a rotor and a stator, said rotor comprising said axis, said axis comprising an optical end and an electronic end, the stator comprising a means for generating a magnetic field; the device further comprising a first axial rotation bearing associated with said optical end and a second axial rotation bearing associated with said electronic end, each bearing comprising an inner part and an outer part; said device further comprising electronic actuation means for providing a charged particle having a velocity v moving through a conductor provided on said rotor, wherein the axis is able to perform a rotational movement over less than 180, and whereby the orientation of said axis is controlled by a Lorentz force resulting from said charged particle moving in said magnetic field; wherein said device comprises axis-related clamping means configured to exert an axial force on the inner parts of the bearings toward each other for axially clamping said axis, thereby radially fixating said axis with respect to each of the inner parts of the bearings.

There is provided an an apparatus for reducing coherence of a laser beam, which apparatus comprises a rectangular chamber having a first, second, and third walls each comprising a reflective inner surface, and a fourth wall comprising a beam splitter. The fourth wall is configured to transmit a portion of the laser beam into the chamber to form an input beam incident upon the first wall. The first wall is configured to reflect the input beam onto the second wall, which is configured to reflect the input beam onto the third wall, which is configured to reflect the input beam onto the fourth wall. The fourth wall is configured to reflect a portion of the input beam to form a further input beam incident upon the first wall and to transmit another portion of the input beam out of the chamber to form an output laser beam.

An optical observation instrument according to the invention, in particular a surgical microscope or exoscope, comprises an optics unit with an objective arrangement and at least one electronic image recorder, wherein the optics unit has a first stereo channel with a first beam path and a second stereo channel with a second beam path for recording a stereo image of an object field with the at least one electronic image recorder and wherein the first and the second beam path extend through the objective arrangement. The instrument moreover comprises a retaining apparatus, on which the optics unit is mounted so as to be rotatable about a first axis of rotation, the latter at least approximately corresponding to an axis of the objective arrangement, wherein the optical observation instrument has a viewing direction that is angled in relation to the axis of the objective arrangement and comprises a deflection element, arranged on the object-side of the objective arrangement, for deflecting the first and the second beam path into the objective arrangement. The invention further relates to a method for generating a stereo image of an object field.

A lens apparatus includes a rotator configured to rotate around the optical axis direction when contacting the vibrator, a biasing member configured to bias the vibrator from a first side to a second side in the optical axis direction so as to compressively bring the vibrator into contact with the rotator, and a driving ring configured to receive a rotation of the rotator, to rotate around the optical axis direction relative to the fixed lens barrel, and to move the lens unit in the optical axis direction. The fixed lens barrel includes a receiver configured to receive the biasing force of the biasing member transmitted to the driving ring via the rotator. The receiver is provided inside the vibrator and the rotator in the radial direction and on the first side of the end of the driving ring on the second side.

A digital microform imaging apparatus includes a bracket movably coupled to a chassis. A microform media support is coupled to the bracket and includes a frame and a window supported by the frame. An illumination source is provided to direct light through the window of the microform media support along an optical axis. An optical sensor is positioned along the optical axis. A motor is operatively engaged with the microform media support to move the bracket and frame relative to the chassis along an axis perpendicular to the optical axis.

Bundle adjustment systems and methods are disclosed for determining a solution for orientation information associated with a plurality of image frames captured by at least one rolling shutter camera in a rotating camera lens type imaging system having a camera lens that moves across track in an oscillating manner and captures image frames as the camera lens moves. The system may define a plurality of pose time domain polynomials for the rolling shutter camera, the pose time domain polynomials together defining pose information for the rolling shutter camera for scanlines of an image frame captured by the rolling shutter camera, and each pose time domain polynomial including a plurality of parameters to be adjusted in a bundle adjustment process and carry out a bundle adjustment process using the pose time domain polynomials to produce a bundle adjustment solution wherein the pose time domain polynomial parameters are adjusted to reduce error.

An image device capable of compensating image variation includes at least one image capturer and a compensator. The compensator is electrically connected to the at least one image capturer for generating a 360 degree image, projecting the 360 degree image according to a view angle to generate a plane image corresponding to the view angle, detecting image position variation of at least one object of the plane image, and compensating the image position variation of the at least one object of the plane image, wherein position variation of the image device makes an image position of the at least one object be changed.