An observation optical system has an objective system and an eyepiece system in the order from the object side. The objective system includes, in the order from the object side, a first group having a positive power, a second group having a positive power, and a third group having a negative power. The objective system has an inverting optical system. The eyepiece system includes, in the order from the object side, a fourth group having a positive power and a fifth group having a positive power. The third group and the fourth group move in directions separating from each other along an optical axis to thereby perform variable power from a low magnification to a high magnification, and also the following conditional expression is satisfied:

0.28<HL/f0.55 (1).

According to an exemplary embodiment, a loupe attachment for glasses may be provided. The loupe attachment may include a loupe and a number of optical devices such as mirrors or prisms. The loupe and the optical devices may be connected to eyeglasses and be positioned as desired. The loupe and the optical device may be connected to the glasses on number of locations and the relative position of the loupe and optical devices in the trajectory of light may be modified. According to a second exemplary embodiment, loupes may be rigidly connected to eyeglasses and a number of optical elements may be rigidly or rotatably connected to the front end of the loupe so as to reflect the field of view situated at an angle from the loupe viewing direction.

Various embodiments include a tilt actuator and a spring suspension arrangement for use in a camera having a folded optics arrangement. In some embodiments, the folded optics arrangement may include a light path-folding element that is coupled with a carrier and that is tilted using the tilt actuator. The spring suspension arrangement may suspend the carrier and the light path-folding element from a base structure, and may allow motion of the light path-folding element enabled by the tilt actuator. The spring suspension arrangement may include one or more springs attached to the carrier and to the base structure. In some embodiments, the spring suspension arrangement may further include one or more suspension wires attached to the spring(s) and to a stationary structure of the camera.

An optical member driving mechanism is provided. The optical member driving mechanism includes a first movable portion, a fixed portion, a first driving assembly, and a plurality of second guiding members. The first movable portion is configured to connect an optical member. The optical member is used for adjusting a direction of a light from an incident direction to an outgoing direction. The first movable portion can move relative to the fixed portion. The first driving assembly is configured to drive the first movable portion to move relative to the fixed portion. The second guiding members include a first ball, a second ball, and a third ball. The first ball, the second ball, and the third ball are disposed in a plane that is perpendicular to the incident direction.

An optical system includes two imaging optical systems, each imaging optical system including a reflective optical element having a reflecting surface and a held part at a different position from the reflecting surface, the reflecting surface configured to reflect light incident from a subject side; a first holding body configured to hold the held part of the reflective optical element of one of the imaging optical systems; and a second holding body configured to hold the held part of the reflective optical element of the other one of the imaging optical systems. When the first holding body is combined with the second holding body, the reflecting surface of the reflective optical element of the one of the imaging optical systems is opposed to the reflecting surface of the reflective optical element of the other one of the imaging optical systems.

A setting tool system includes a housing. The housing includes a first conduit that receives one or more anchoring systems at a first end, and a second conduit at least partially separated from the first conduit with an interior wall. The second conduit includes a weighted shaft that moves freely within the length of the second conduit. The first and second conduits merge at a second end opposite the first end. Each of the one or more anchoring systems inserted at the first end are individually received at the opening at the second end. Each anchoring system is individually fastened via the weighted shaft to the external surface. The setting tool system includes a prism system removably coupled to the housing, where the prism system is configured to aid in identifying one or more installation locations.

Systems and methods for correcting point of view (POV) aberrations in scanning folded cameras and multi-cameras including such scanning folded cameras. In a Tele folded camera that includes an optical path folding element (OPFE) and an image sensor, the OPFE is tilted in one or two directions to direct the Tele folded camera towards a POV of a scene, a Tele image or a stream of Tele images is captured from the POV, the Tele image having POV aberrations and the POV aberrations are digitally corrected to obtain an aberration-corrected image or stream of images.

Disclosed are a prism fixing structure of the optical machine and a projection optical machine. The prism fixing structure of an optical machine includes a body and a prism, the body is provided with a slot, a bearing surface and a baffle, and the prism includes a first side edge, a second side edge and a hypotenuse connected end to end; a glue point is provided between the first side edge and the bearing surface, the hypotenuse is fitted with the baffle, and an oblique angle end formed by the second side edge and the hypotenuse is clamped in the slot.

An adjustable beam directing optical system for a focused laser differential interferometer (FLDI) instrument according to various aspects of the present technology may include optical half waveplate to achieve an incident linear polarization orientation with equal components of laser intensity aligned to the vertical and horizontal axis of the optical system, and an optical prism for splitting these components of an incident laser beam into two orthogonally-polarized beams equally about an optical axis of the FLDI instrument. A series of beam realignment devices positioned downstream of the optical prism are configured to selectively direct each beam to a predetermined location.

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.