Apparatus (38) for the optical manipulation of a pair of landscape stereoscopic images (L, R), which apparatus (38) comprises: (i) a camera (36) which has its own focus lens (40); (ii) an enclosed housing (4), three ports (6, 8, 10) in the housing (4) with one port being a photographic interface port which forms a photographic interface (12) to the camera (36), and the other two ports being human interface ports which form a human interface (18), said three ports (6, 8, 10) allowing the light to pass from the human interface to the photographic interface (12) for camera recording, or from the photographic interface (12) to the human interface (18) for each eye of the human, in a direction parallel to that of light entering the other said interface without left-right image inversion between the photographic interface (12) and the human interface (18); and (iii) at least four reflective surfaces (20, 22, 24,26) which direct light along three mutually perpendicular axes, each of said surfaces having an edge lying on a flat plane (28), said plane (28) also including a division line (30) between adjacent landscape stereoscopic images presented at said photographic interface (12), whereby the apparatus (38) causes landscape stereoscopic images which are side by side with a left eye image left of a right eye image and with shortest dimensions adjacent and which are at the human interface (18) to become stacked one image above the other at the photographic interface (12), and wherein: (iv) the apparatus (38) causes the left and right eye images which are stacked one image above the other at the photographic interface (12) to emerge as parallel light towards the camera (36); and (v) the focus lens of the camera (36) is on an optical axis passing through the centre of the photographic interface port and is focussed for infinity distance to receive the parallel light conveying the two stereoscopic images.

Apparatus (38) for the optical manipulation of a pair of landscape stereoscopic images (L, R), which apparatus (38) comprises: (i) a camera (36) which has its own focus lens (40); (ii) an enclosed housing (4), three ports (6, 8, 10) in the housing (4) with one port being a photographic interface port which forms a photographic interface (12) to the camera (36), and the other two ports being human interface ports which form a human interface (18), said three ports (6, 8, 10) allowing the light to pass from the human interface to the photographic interface (12) for camera recording, or from the photographic interface (12) to the human interface (18) for each eye of the human, in a direction parallel to that of light entering the other said interface without left-right image inversion between the photographic interface (12) and the human interface (18); and (iii) at least four reflective surfaces (20, 22, 24,26) which direct light along three mutually perpendicular axes, each of said surfaces having an edge lying on a flat plane (28), said plane (28) also including a division line (30) between adjacent landscape stereoscopic images presented at said photographic interface (12), whereby the apparatus (38) causes landscape stereoscopic images which are side by side with a left eye image left of a right eye image and with shortest dimensions adjacent and which are at the human interface (18) to become stacked one image above the other at the photographic interface (12), and wherein: (iv) the apparatus (38) causes the left and right eye images which are stacked one image above the other at the photographic interface (12) to emerge as parallel light towards the camera (36); and (v) the focus lens of the camera (36) is on an optical axis passing through the centre of the photographic interface port and is focussed for infinity distance to receive the parallel light conveying the two stereoscopic images.

The vehicle delimits an interior space from an exterior space. The sighting device includes: a support defining an interior volume, an optronic head adapted to rotate about an axis, an optical path comprising: a collecting optical unit for collecting a portion of the surroundings of exterior space, adapted to rotate about the axis; and an optical transport system including a plurality of optical components, portion of the components being, in the interior space and the other portion being in the interior volume; a drive means driving the optronic head and the collecting optical unit so that the ratio between the angle of rotation of the head and the angle of rotation of the collecting optical unit is substantially equal to 1.

The vehicle delimits an interior space from an exterior space. The sighting device includes: a support defining an interior volume, an optronic head adapted to rotate about an axis, an optical path comprising: a collecting optical unit for collecting a portion of the surroundings of exterior space, adapted to rotate about the axis; and an optical transport system including a plurality of optical components, portion of the components being, in the interior space and the other portion being in the interior volume; a drive means driving the optronic head and the collecting optical unit so that the ratio between the angle of rotation of the head and the angle of rotation of the collecting optical unit is substantially equal to 1.

A device can include a display that includes a display area; and an optical assembly that includes an optical element that defines an origin of a view of a camera, where the optical element is positionable directly in front of the display area of the display.

Certain examples relate to a terrestrial terahertz imaging system. In one example, the terrestrial terahertz imaging system has an imaging assembly to form a first image of at least a portion of an object using electromagnetic radiation in a terahertz band of frequencies and a receiver assembly comprising a cryostat. The cryostat contains a detector and reflective cold re-imaging optical components to receive the electromagnetic radiation from the imaging assembly. The reflective cold re-imaging optical components form a second image of at least a portion of the object on the detector. The imaging assembly has reflective optical components arranged in a confocal configuration that is arranged to image at finite conjugates. The reflective cold re-imaging optical components implement a reflective, confocal optical relay. Other examples relate to body and vehicle scanning devices that may be used in security applications.

Certain examples relate to a terrestrial terahertz imaging system. In one example, the terrestrial terahertz imaging system has an imaging assembly to form a first image of at least a portion of an object using electromagnetic radiation in a terahertz band of frequencies and a receiver assembly comprising a cryostat. The cryostat contains a detector and reflective cold re-imaging optical components to receive the electromagnetic radiation from the imaging assembly. The reflective cold re-imaging optical components form a second image of at least a portion of the object on the detector. The imaging assembly has reflective optical components arranged in a confocal configuration that is arranged to image at finite conjugates. The reflective cold re-imaging optical components implement a reflective, confocal optical relay. Other examples relate to body and vehicle scanning devices that may be used in security applications.

Dental periscopes having mounting clips configured to couple to mobile devices are disclosed. A patient can mount the dental periscope to a mobile device by coupling the mounting clip of the periscope to the mobile device. The patient can then use the mobile device-mounted dental periscope to capture image and/or video data of one or more dental structures. The captured image/video data can be sent to a remote system to obtain a remote dental diagnosis based on the captured data. The remote diagnosis may be an automated diagnosis generated by a trained machine learning classifier.

Dental periscopes having mounting clips configured to couple to mobile devices are disclosed. A patient can mount the dental periscope to a mobile device by coupling the mounting clip of the periscope to the mobile device. The patient can then use the mobile device-mounted dental periscope to capture image and/or video data of one or more dental structures. The captured image/video data can be sent to a remote system to obtain a remote dental diagnosis based on the captured data. The remote diagnosis may be an automated diagnosis generated by a trained machine learning classifier.

An optical element driving mechanism is provided and includes a movable portion and a fixed portion. The movable portion includes a carrier for carrying an optical member with a first optical axis. The fixed portion has a top surface, a first side surface and a second side surface. The top surface extends in a direction that is parallel to the first optical axis. The first side surface and the second side surface extend in a direction that is not parallel to the first optical axis from the edge of the top surface and face different sides of the optical member. The shortest distance between the optical member and the first side surface is shorter than the shortest distance between the optical member and the second side surface. The optical element driving mechanism includes a noise-reducing structure configured to avoid a noise entering a photosensitive member.