A gimbal handle includes an enclosure including an accommodation space, a main control board accommodated in the accommodation space, and an electrical contact member provided at the main control board and electrically connected to the main control board. The electrical contact member penetrates the enclosure to expose to an outside of the enclosure. The electrical contact member is configured to be electrically connected to an adapter.

Diffraction-based imaging systems are described. Aspects of the technology relate to imaging systems having one or more sensors inclined at angles with respect to a sample plane. In some cases, multiple sensors may be used that are, or are not, inclined at angles. The imaging systems may have no optical lenses and are capable of reconstructing microscopic images of large sample areas from diffraction patterns recorded by the one or more sensors. Some embodiments may reduce mechanical complexity of a diffraction-based imaging system. A diffractive imaging system comprises a light source, a sample support configured to hold a sample along a first plane, and a first sensor comprising a plurality of pixels disposed in a second plane that is tilted at an inclined angle relative to the first plane. The first sensor is arranged to record diffraction images of the light source from the sample.

An imaging apparatus includes a first optical system, a first separation optical system that separates the light transmitted through the first optical system into the first wavelength range light and the second wavelength range light, a second optical system that transmits the first wavelength range light obtained by the first separation optical system, a third optical system that transmits the second wavelength range light obtained by the first separation optical system, a first image sensor that receives the first wavelength range light, a second image sensor that receives the second wavelength range light, and a first light source that emits the first wavelength range light, in which the first optical system emits the first wavelength range light emitted from the first light source to a subject, and transmits subject light including first wavelength range reflected light obtained by reflecting the first wavelength range light by the subject.

Voice coil motor (VCM) actuators for rotating an optical path folding element (OPFE) over an extended scanning range relative to a scanning/rotation range needed for optical image stabilization (OIS).

A multifunctional camera system having a bendable arm configured to be inserted into the thoracic cavity of a patient and camera head at a distal end of the bendable arm. The camera head has a high definition video camera and a light source. The camera head has a view adjustment mechanism for changing a view angle of the camera without changing the position of the camera head. A controller controls the view adjustment mechanism under command of a surgeon.

A multi-lens camera includes a main housing assembly, lenses, a lens adjuster and a transparent cover. The transparent cover is mounted on the main housing assembly; the lens adjuster is mounted in the space formed by the main housing assembly and the transparent cover; the transparent cover includes a flat portion and a curved portion surrounding the flat portion; the lenses are located in the space covered by the curved portion; the lens adjuster includes a fixing disc and at least two lens brackets; each of the lens brackets includes a first bracket and a second bracket arranged on the first bracket; the first support is movably arranged on the fixing disc, and is capable of moving along the circumferential direction of the fixing disc; a lens is rotationally engaged with the second bracket, such that the lens rotates around axis thereof.

Multi-aperture zoom digital cameras comprising first and second scanning cameras having respective first and second native fields of view (FOV) and operative to scan a scene in respective substantially parallel first and second planes over solid angles larger than the respective native FOV, wherein the first and second cameras have respective centers that lie on an axis that is perpendicular to the first and second planes and are separated by a distance B from each other, and a camera controller operatively coupled to the first and second scanning cameras and configured to control the scanning of each camera.

A detection system, and method of using the same, for a vehicle in an environment. The system includes a line detector with a plurality of optical receiver elements arranged in a line. The optical receiver elements receive light from the environment and the line detector captures an image of the environment in a series of line scans. An optical scanning element rotates around an axis to change a field of view of the line detector with respect to the environment. The optical scanning element has a glass body defined by four glass sides and a reflective member within the glass body.

Disclosed is a system, method, and devices as system elements to recognize an object by an object recognizing system including an imaging device and a moving assembly to move the imaging device around the object, to form a certified visual model of the object to be recognized. Especially the disclosure relates to gemstone imaging by an imaging method including photographing a target, in an illumination, by a camera, to obtain at least one image of the targeted object to be recognized.

The present disclosure provides systems and methods for medical imaging. The system may comprise a scope assembly. The scope assembly may comprise a housing unit configured to releasably couple to at least a portion of an elongated scope. The scope assembly may comprise an imaging unit operably coupled to the housing unit, wherein the imaging unit comprises an optics assembly configured to (i) receive one or more light beams that are transmitted through the elongated scope and (ii) direct at least a portion of the one or more light beams onto two or more locations within a subject's body. At least one of the two or more locations may comprise a target site. The imaging unit may be configured to move via a rotational and/or translational motion relative to the housing unit to alter a field of view when imaging within the subject's body.