A light source apparatus can avoid double-counting of particles in a flow cytometer for measuring and analyzing a plurality of particles flowing in a flow cell. A light source apparatus for a flow cytometer includes a semiconductor laser for emitting a laser beam, a collimating lens for collimating the laser beam emitted from the semiconductor laser in a spread light state, a first beam conversion unit composed of prisms and a second beam conversion unit composed of prisms for matching a flow cell length direction with a slow axis direction of the collimated laser beam in a flow cell after reducing the beam diameter in a fast axis direction and increasing the beam diameter in the slow axis direction, and a focusing lens for focusing the laser beam passed through these beam conversion units in the flow cell.

An optical system is provided. The optical system includes a first optical module with a first light-entering hole, a second optical module with a second light-entering hole, and a third optical module with a third light-entering hole. The second light-entering hole is close to the first light-entering hole and the third light-entering hole. The focal length of the second optical module is different from the focal length of the first optical module and the focal length of the third optical module.

In some embodiments, a stereoscopic imaging apparatus includes a tubular housing having a bore extending longitudinally through the housing. First and second image sensors are disposed proximate a distal end of the bore, each including a light sensitive elements on a face and mounted facing laterally outward. The apparatus further includes a first beam steering element associated with the first image sensor and a second beam steering element associated with the second image sensor. The beam steering elements receive light from first and second perspective viewpoints and direct the received light onto the faces of the image sensors forming first and second images. Either the first and second beam steering elements or the first and second image sensors are moveable to cause a change a spacing between or an orientation of the perspective viewpoints to cause sufficient disparity between the first and second images to provide image data including three-dimensional information.

An actuator including an electrically conducting coil arranged on or integrated into a wall member, wherein the electrically conducting coil is arranged adjacent to a magnetic flux return structure. A magnet connected to a carrier, wherein the magnet interacts with the electrically conducting coil such that when a current is applied to the coil the coil is either moved towards the carrier along an axial direction or away from the carrier along the axial direction depending on a direction of the current within the coil. A magnetic flux guiding structure connected to the carrier, wherein magnetic flux is guided through the flux return structure and the flux guiding structure.

An illumination module (101) for an optical apparatus comprises a light source unit (102), which is configured to selectively emit light along a multiplicity of beam paths (112) in each case. The illumination module (101) also comprises a multiplicity of optical elements (201-203) arranged with lateral offset from one another, wherein each optical element (201-203) of the multiplicity of optical elements (201-203) is configured to transform at least one corresponding beam path (112) of the multiplicity of beam paths.

A camera module includes: an optical path folding member configured to refract or reflect light incident along a first optical axis in a direction of a second optical axis intersecting the first optical axis; a driving assembly configured to provide driving force to rotate the optical path folding member on a plane intersecting the first optical axis; and a first ball bearing and a second ball bearing supporting the optical path folding member such that the optical path folding member is enabled to rotate on the plane. A distance from the first ball bearing to the first optical axis is less than a distance from the second ball bearing to the first optical axis.

An optical apparatus includes: a condensing optical part having a focal point; and an optical element that is inserted between the condensing optical part and the focal point and capable of shifting, in a direction perpendicular to an optical axis, the apparent focal point as viewed from a side of the condensing optical part.

Examples are disclosed that relate to pixel-shifting devices for increasing display resolution. One example provides a pixel-shifting device comprising an outer frame, an inner frame coupled to the outer frame via a flexure, a path-shifting optical element mounted to the inner frame, and one or more piezoelectric actuators configured to drive motion of the inner frame.

A prism drive device of the present invention comprises: a housing; a mover disposed in the housing; a prism disposed in the mover; a first magnet disposed in the mover; a coil disposed in the housing; a guide part disposed between the housing and the mover and configured to guide the tilting of the mover; and a second magnet disposed in the housing and facing the first magnet, wherein the first magnet and the second magnet face each other with the same pole.

The present invention relates to an optical device (1), comprising: a container (10) enclosing an internal space (11) of the container (10), the internal space (11) being filled with a transparent liquid (12), wherein the container (10) comprises a transparent and elastically deformable membrane (13) delimiting said internal space (11) at least partially, wherein the container (10) further comprises a transparent rigid optical element (2) being connected to said membrane (13), the rigid optical element (2) comprising an optical surface (20) facing the membrane (13), the rigid optical element (2) being configured to receive light (L) for passing the light (L) through the transparent liquid (12) residing in the internal space (11) of the container (10), wherein the optical device (1) further comprises a supporting structure (3) supporting the rigid optical element (2) so that the rigid optical element (2) is tiltable about at least a first tilting axis (X) extending along said optical surface (20) of the rigid optical element (2) to deflect light passing through the container (10), wherein the supporting structure (3) is configured to prevent a translation of the rigid optical element (2) in a direction parallel to an optical axis (A) of the optical device.