A medical otoscope, comprises an otoscope body and an observation apparatus connected to one end of the otoscope body, the other end of the otoscope body having a tapered portion capable of inserting into an ear, the observation apparatus comprising at least one optical lens group arranged along a same optical axis, the optical lens group comprising at least one optical lens capable of moving along the optical axis, central axis of the observation apparatus being coaxial with or deviating from central axis of the otoscope body. The focal length of the medical otoscope can be adjusted by means of arranging two groups of optical lenses movable relative to one another, and the medical otoscope has a simple structure and is convenient for operation.

A stereoscopic endoscope apparatus includes: an insertion portion; a variable focus objective optical system; a fixed focus objective optical system; an image pickup section; an image signal generation output section that outputs an image signal for two-dimensional display when a focal length of the variable focus objective optical system and a focal length of the fixed focus objective optical system are different from each other, and outputs an image signal for stereoscopic observation when the focal length of the variable focus objective optical system and the focal length of the fixed focus objective optical system are coincident with each other in the near point observation state.

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.

A system for preventing motion sickness resulting from virtual reality or augmented reality is disclosed herein. In one embodiment, the system includes a virtual reality or augmented reality headset configured to be worn by a user, the virtual reality or augmented reality headset configured to create an artificial environment and/or immersive environment for the user; at least one fluidic lens disposed between an eye of the user and a screen of the virtual reality or augmented reality headset; and a fluid control system operatively coupled to the at least one fluidic lens. In another embodiment, the system includes at least one tunable prism disposed between an eye of the user and a screen of the virtual reality or augmented reality headset, the at least one tunable prism configured to correct a convergence problem associated with the eye of the user.

The optical system is characterized by a rotationally symmetric front group that is located on a single axis of rotational symmetry passing through the center of an image plane, a rotationally symmetric back group, and an aperture, wherein the front group includes two internal reflecting surfaces and two transmitting surfaces, a light beam incident from at least one object plane on the front group forms an optical path along which the light beam enters a first transmitting surface, is reflected off a first reflecting surface and then off a second reflecting surface, and exits out of a second transmitting surface, and the light beam passes through the back group and aperture and is imaged in a position of the image plane away from the axis of rotational symmetry without being intermediately imaged within a section including the axis of rotational symmetry.

An optical unit includes: a fixed portion configured to hold at least one of an object side fixed lens group and an image side fixed lens group; a movable portion configured to hold a movable lens group between the object side fixed lens group and the image side fixed lens group; and a voice coil motor configured to relatively move the movable portion with respect to the fixed portion in a direction of a central axis, the voice coil motor including a coil arranged on the fixed portion, and magnets magnetically polarized in directions orthogonal to the central axis and substantially symmetrical with respect to the central axis. At least two magnets adjacent to each other in a circumferential direction in a cross section orthogonal to the central axis are arranged so as to be shifted in opposite directions in a circumferential direction.

The objective optical system consists of order from an object side, a first group having a positive refractive power, a second group having a negative refractive power, and a third group having a positive refractive power, wherein focusing is carried out by moving the second group, and a lens nearest to image is a planoconvex positive lens having a convex surface directed toward the object side, and a flat surface of the planoconvex positive lens is either affixed directly to an image pickup surface or cemented to a cover glass formed on the image pickup surface, and the objective optical system satisfies the following conditional expression (1).
5<ff/f<8(1) where, ff denotes a focal length of the planoconvex positive lens disposed nearest to image, and f denotes a focal length of the overall objective optical system at the time of normal observation.

There is disclosed an imaging system for use in imaging a sample. The imaging system comprising a light source and a light detector. A probe optically coupled to the imaging assembly. The probe being configured to, during use, direct light from the light source to a focal point to illuminate the sample, and from the focal point to the light detector. The probe having a tunable liquid crystal lens (TLCL) assembly comprising at least one pair of TLCLs, the TLCLs of the pair being superposed to one another, a gradient-index (GRIN) lens assembly having a base being optically connected to the TLCL assembly, and a tip opposite to the base. The focal point being at a working distance from the tip. The working distance being adjustable relative to the tip by tuning each TLCL of the TLCL assembly during use.

A fluidic light field camera is disclosed herein. The fluidic light field camera includes a fluidic objective lens; a fluid control system operatively coupled to the fluidic objective lens, the fluid control system to change the shape* of the fluidic objective lens in accordance with the amount of fluid therein; a microlens array disposed behind the fluidic objective lens: a sensor array disposed behind the microlens array; and a data processing device operatively coupled to the fluid control system and the sensor array, the data processing device configured to vary the focal point of the fluidic light field camera by using the fluid control system to control the shape of the fluidic objective lens, thereby enabling all portions of an image being captured by the fluidic light field camera to be in focus during a single recording cycle of the fluidic light field camera.

A fluidic light field camera is disclosed herein. The fluidic light field camera includes a fluidic objective lens; a fluid control system operatively coupled to the fluidic objective lens, the fluid control system to change the shape of the fluidic objective lens in accordance with the amount of fluid therein; a microlens array disposed behind the fluidic objective lens; a sensor array disposed behind the microlens array; and a data processing device operatively coupled to the fluid control system and the sensor array, the data processing device configured to vary the focal point of the fluidic light field camera by using the fluid control system to control the shape of the fluidic objective lens, thereby enabling all portions of an image being captured by the fluidic light field camera to be in focus during a single recording cycle of the fluidic light field camera.