Abstract: A deflection prism assembly for an endoscope having a lateral viewing direction, the deflection prism assembly including: a prism holder; and a deflection prism accommodated in the prism holder; wherein the deflection prism has a light outlet surface and an opposite light inlet surface arranged obliquely to the light outlet surface, the deflection prism further having a lateral surface extending between the light inlet surface and the light outlet surface; and the prism holder accommodates the deflection prism such that the prism holder surrounds less than all regions of the lateral surface of the deflection prism.

Abstract: An optical apparatus having a pair of lenses spaced from each other in a first direction and movable in a second direction orthogonal to the first direction includes a movable member configured to hold the pair of lenses and to move in a second direction together with a female thread member, and a guide configured to guide a movement of the movable member in the second direction relative to the base member, where a first plane includes an optical axis of each of the pair of lenses, the guide being located at a position on or along a second plane that is orthogonal to the first plane and includes a central axis of the male thread member.

Abstract: One embodiment is directed to a head-wearable viewing component for presenting virtual image information to a user, comprising: a head wearable frame; a left optical element for a left eye of the user, the left optical element coupled to the head wearable frame and comprising a left fluid/membrane lens configured to have an electromechanically adjustable focal length for the left eye of the user; a right optical element for a right eye of the user, the right optical element coupled to the head wearable frame and comprising a right fluid/membrane lens configured to have an electromechanically adjustable focal length for the right eye of the user; and a controller operatively coupled to the left optical element and right optical element and configured to provide one or more.

Abstract: This application discloses virtual reality (VR) glasses, and a lens barrel adjustment method and apparatus, and relates to the field of VR technologies. The VR glasses includes a glasses body and two lens barrels that are symmetrically disposed within the glasses body. Each of the two lens barrels includes a lens barrel body and a lens barrel kit. The lens barrel kit is provided with a first adjustment component. The lens barrel body is provided with a second adjustment component. The lens barrel kit and the lens barrel body are configured to perform relative movement through coordination of the first adjustment component and the second adjustment component.

Abstract: An eyeball-tilt detecting device for detecting a tilt position of an eyeball, including: a light source array including a plurality of light emitting sections that emit light having directivity; an optical spot position detection element configured to detect an optical spot position of light reflected from an eyeball to output a detection signal; and processing circuitry configured to calculate a tilt position of the eyeball based on the detection signal output from the optical spot position detection element.

Abstract: A head-mounted display apparatus includes a wearing device, a display-source arrangement portion and an optical assembly. The wearing device has a head-wearing portion and a hat brim portion connected to the head-wearing portion. The display-source arrangement portion is connected with the hat brim portion. The optical assembly is movably disposed on the hat brim portion, and arranged between the head-wearing portion and the display-source arrangement portion.

Abstract: In a case where a first coil enters an energized state, the first coil, a second coil, a detection magnet, and a Z-axis position sensor move in an X axis direction. In a case where the second coil enters an energized state, the second coil and the detection magnet move in a Z axis direction, but the first coil and the Z-axis position sensor do not move in the Z axis direction. The Z-axis position sensor is disposed so as to be spaced from the second coil, and the detection magnet is disposed on a side opposite to a second driving magnet with respect to the Z-axis position sensor. The Z-axis position sensor detects a displacement amount V of the detection magnet in the Z axis direction.

Abstract: Provided is a zoom lens including, in order from an object side to an image side: a first lens unit having a positive refractive power; a second lens unit having a negative refractive power; and a third lens unit having a positive refractive power, in which an interval between each pair of adjacent lens units is changed during zooming, the first lens unit consists of, in order from the object side to the image side, a positive lens and a negative lens, and a focal length of the first lens unit, a focal length of the third lens unit, a focal length of the negative lens, and a focal length of an entire system of the zoom lens at a wide-angle end are each appropriately set.

Abstract: A projection system of the disclosure includes an apparatus unit and a controller. The apparatus unit includes a speaker section, a projector section, and an imaging section. The speaker section includes one or more speakers. The imaging section images a projection screen provided by the projector section. The controller controls a sound output state of the speaker on a basis of information indicating an installation state of the apparatus unit. The information is estimated on a basis of a captured image obtained by the imaging section.

Abstract: Improved binocular vision system having a high resolution, uncompressed image in the forward facing direction and compressed images on the left and right side periphery. The binocular vision system utilizes a shared sensor between multiple optics to reduce the cost and weight of the device. The system maps multiple optics to portions of sensor arrays such that the compression on the periphery is in the azimuth only and thus more closely matches human vision.

Abstract: A stereoscopic viewing apparatus for use with a SmartPhone including a pair of lenses and a viewer body preferably fabricated at low cost from a single paper sheet. The sheet is provided with a pair of fold lines which define first and second sheet segments separated by a lens mounting segment. The lens mounting segment defines a pair of left and right lens openings for receiving the respective lenses, with the mounting segment further defining features that secure the lenses in place in the lens openings. When in an operating mode, the first and second sheet segments function to position the lenses appropriately for viewing stereoscopic images on a SmartPhone screen, with the viewer being capable of being folded into a compact state for shipping or storage.

Abstract: Disclosed is a display apparatus. The display apparatus includes at least one context image renderer for rendering a context image, wherein an angular width of a projection of the rendered context image ranges from 40 degrees to 220 degrees; at least one focus image renderer for rendering a focus image, wherein an angular width of a projection of the rendered focus image ranges from 5 degrees to 60 degrees; and at least one optical combiner for combining the projection of the rendered context image with the projection of the rendered focus image to create a visual scene, wherein the visual scene is to be created in a manner that at least two different optical distances are provided therein.

Abstract: A head mountable display system includes a visual image system, a head mountable display device including a display screen, and a headset pose sensor system. A controller is configured to generate a camera image based upon the image data, generate an augmented reality overlay based upon the position and the orientation of the operator's head relative to the work site, determine an image to be rendered on the head mountable display based upon the camera image and the augmented reality overlay, and render the image on the display screen.

Abstract: A long-range optical apparatus includes an optical unit defined by lenses and an eyepiece and has at least one manually operable adjusting device for adjusting an optical unit defined by the lenses. With the adjusting device, the optical unit can be adjusted relative to a mounting device. The adjusting device is mechanically coupled to at least one optical element or the mounting device. The optical apparatus has an electronic unit including a memory and the electronic unit performs an electronic function in dependence upon a setting parameter stored in the memory. The adjusting device is coupled with a position detection unit so that actuation of the adjusting device triggers an electrical signal of the position detection unit as a function of the position of the adjusting device. The electronic unit stores or changes a setting parameter in the memory in response to the electrical signal of the position detection unit.

Abstract: A rifle scope includes an image sensor configured to capture visual data corresponding to a view area, a display, and a controller coupled to the display and the image sensor. The controller is configured to apply a first stabilization parameter to at least a portion of the visual data to produce a stabilized view, to provide the stabilized view and a reticle to the display, and to apply a second stabilization parameter to stabilize the reticle relative to the stabilized view in response to motion.

Abstract: An optical system for imaging an object comprises a first lens, a first image stabilization unit and a first image plane. When seen from the first lens in the direction of the first image plane, the order in which the elements are arranged along a first optical axis is as follows: first lens, first image stabilization unit and first image plane. The first image stabilization unit has at least one first inlet surface and at least one first outlet surface. The first inlet surface is oriented towards the first lens. The first outlet surface is oriented towards the first image plane. Furthermore, the first outlet surface is spaced apart from the first image plane in a range of 1 mm to 20 mm.

Abstract: The invention relates to a binocular observation device, in particular binoculars, having two visual beam paths and a laser range finder with a laser transmitter and a laser receiver and with an opto-electronic display element. A part of one of the beam paths of the laser transmitter is integrated into a first visual beam path, wherein a part of one beam path of the laser receiver is furthermore also integrated into the first visual beam path.

Abstract: An optical device includes an objective, an eyepiece and a power corrector, each of which includes one or more lenses, and each of which has a respective focal length. The input focal length of the device is defined jointly by the focal lengths of the objective and the power corrector. The magnification of the device is the ratio of the input focal length to the eyepiece focal length. The combined aberration of the eyepiece and the power corrector is less than the characteristic aberration of the eyepiece. The objective, the eyepiece and the power corrector together define an apparent field of view of at least 75 degrees and an exit pupil. The eyepiece lens diameter(s) is/are no greater than twelve times the pupil diameter and three times the eyepiece focal length.

Abstract: Binoculars includes left and right image stabilizing lenses, a lens holder configured to move in a direction orthogonal to an optical axis direction, a reference member as a positioning reference in an optical axis direction of the lens holder, a plurality of balls provided at least three each around each of the left and right image stabilizing lenses between the lens holder and the reference member, and configured to roll in accordance with a move of the lens holder, and left and right biasing members inside of the three balls in the left and right ball units and configured to press the lens holder and the reference member against the balls. A coupling portion in the lens holder is so flexible that at least three balls can contact the lens holder by the left and right biasing members.

Abstract: A catadioptric telescope is a modified version of a conventional Maksutov-Cassegrain optical telescope. In accordance with the invention, the reflecting surfaces of the primary mirror and the secondary spot mirror are on the second surfaces of the primary mirror and correcting lens, respectively. In further accordance with the invention, two of these telescopes can be joined together to form a binocular telescope array. The array can be easily customized to suit different remote sensing/satellite applications.

Abstract: A long-range optical device with at least one replaceable electrical energy storage device for supplying power to the long-range optical device, which energy storage device is disposed in a closable compartment of the device incorporating electrical contacts, wherein an adapter is provided which can be inserted in the compartment instead of the energy storage device, which is configured to run a data exchange with at least one other component, in particular a memory, of the long-range optical device and/or by means of which the long-range optical device can be supplied with power.

Abstract: The binoculars of the present invention comprise two optical units; one optical unit for each eye. Each optical unit comprises a first reflector element and a second reflector element, wherein at least one of the reflector elements is a micromirror array reflector. The binoculars of the present invention provide focusing and/or zoom functions without or with minimal macroscopic mechanical lens movement.

Abstract: The present invention relates to control system for a vehicle. The control system includes a manually operable control lever, such as a joystick, an actuator, a sensor and a control unit. The control lever sets a state variable of the vehicle. The actuator applies a force to the control lever. The sensor senses a vehicle parameter and transmits a parameter signal to the control unit. The control unit determines a current operating state of the vehicle. The control unit, depending on the present operating state of the vehicle, controls the actuator and causes it to apply a changed, predetermined force to the control lever, in order to make the operator aware of an unsafe operating state.

Abstract: A binocular-type viewing apparatus designed in such a manner that a user, wanting to view an object located at a distance above the viewer's horizontal line of sight, need only direct his/her view downward into the apparatus to view the elevated object. Thus the eyepiece component has an optical axis inclined downwardly and an objective optical component of the apparatus has an optical axis inclined upwardly. An optical structure is disposed between the objective and the eyepiece to redirect the image optical path from the objective optical component to the eyepiece component and into the viewer's eyes. The binocular may have a fixed deviated optical axis or a variably adjustable optical axis from in-line up to or exceeding 90 degrees.

Abstract: An optical device includes an objective, an eyepiece and a power corrector, each of which includes one or more lenses, and each of which has a respective focal length. The input focal length of the device is defined jointly by the focal lengths of the objective and the power corrector. The magnification of the device is the ratio of the input focal length to the eyepiece focal length. The combined aberration of the eyepiece and the power corrector is less than the characteristic aberration of the eyepiece. The objective, the eyepiece and the power corrector together define an apparent field of view of at least 75 degrees and an exit pupil. The eyepiece lens diameter(s) is/are no greater than twelve times the pupil diameter and three times the eyepiece focal length.

Abstract: A pair of binoculars includes: a pair of lens barrels in each of which a telescopic optical system including an objective lens and an eyepiece is held; a reticle that is provided between the objective lens and the eyepiece of one of the telescopic optical systems movably in an optical axis direction of the one of the telescopic optical systems; and an adjusting ring that moves the reticle in the optical axis direction by rotation operation to adjust a position of the reticle in the optical axis direction.

Abstract: A night vision goggle system is shown, including optical modules, a heads-up display (HUD) module, and a camera module. Each module may be added to and removed from the system without structural, electrical, or optical damage to itself or the remaining modules. Each optical module takes input light at one end and provides an intensified image at the other. A heads-up display module (HUD) can provide an informational display in any of at least two of the optical modules or both. A camera module is capable of recording both the intensified image produced by a particular optical module, as well as the HUD information shown through that module with substantially no offset from the original display. Both the camera module and the HUD module are installable onto the same optical module at the same time, and can be installed on either (or in some embodiments, any) optical module.

Abstract: An observation apparatus includes a first member 9 supporting first optical elements L1L and L1R, a second member 7 supporting second optical elements L4L and L4R and the first member via balls so as to be movable in an optical axis direction, and a biasing device 11 generating a biasing force for clamping the balls. The first and second members include guide portions 7a, 7b, 9a, and 9b engaging with first balls so as to permit a rolling motion of the two first balls 10a and 10b in the optical axis direction and prevent the first member from displacing with respect to the second member in a direction orthogonal to the optical axis direction, and ball holding portions 7c, 7d, 9c, and 9d holding second balls 10c and 10d so as to permit a rolling motion of the second balls in the optical axis direction.

Abstract: The invention relates to improving optical properties of optical instruments with variable magnification, such as zoom binoculars, reducing the weight thereof, and enabling the user to change magnifications quickly. The invention provides an optical instrument with a focal length-varying lens 4 disposed on the optical axis between an objective lens 7 and an eyepiece 3, further having an adjusting lens 5 for adjusting optical properties when the focal length-varying lens is in an area to provide high magnification. The adjusting lens is supported so that it is capable of moving between a location on the optical axis and a location off the path of light beams. Interlocked with a magnification-varying mechanism that controls the position of the focal length-varying lens, the adjusting lens is moved to the on-the-axis location when the focal length-varying lens is in an area to provide high magnification, and to the off-the-axis location when low magnification.

Abstract: A night vision goggle system is shown, including optical modules, a heads-up display (HUD) module, and a camera module. Each module may be added to and removed from the system without structural, electrical, or optical damage to itself or the remaining modules. Each optical module takes input light at one end and provides an intensified image at the other. A heads-up display module (HUD) can provide an informational display in any of at least two of the optical modules or both. A camera module is capable of recording both the intensified image produced by a particular optical module, as well as the HUD information shown through that module with substantially no offset from the original display. Both the camera module and the HUD module are installable onto the same optical module at the same time, and can be installed on either (or in some embodiments, any) optical module.

Abstract: A telescope optical system TL comprising, in order from an object side: an objective lens 1; an erecting prism 2; and an eyepiece 3; the objective lens 1 comprising, in order from the object side, a first lens group G1 having positive refractive power, a second lens group G2 having negative refractive power, and a third lens group G3 having positive refractive power, focusing being carried out by moving the second lens group G2 along an optical axis, and an image position being movable by moving the third lens group G3 in a direction perpendicular to the optical axis, thereby providing a telescope optical system having optimum optical performance for a telescope.

Abstract: An optical apparatus 101 includes shake detecting means 102a, 102b, 103a, 103b, and 105 that detect a shake, an image stabilizing means 108a that operates so as to suppress an image shake, a drive means 115 that drives the image stabilizing means based on an output from the shake detecting means, a control means 104 that stops power supply to the drive means while continuing power supply to the shake detecting means in accordance with elapse of a predetermined time after the image stabilizing means starts the operation, and a power detecting means 116 that detects a remaining amount of a power source. The controller changes the predetermined time in accordance with the remaining amount of the power source detected by the power detecting means.

Abstract: A tripod-connecting adapter for connecting a pair of binoculars to a tripod comprising: a base portion that has a width in which a left and a right lens barrels of the pair of binoculars to be placed thereon come into contact therewith, and restricts rotation of the pair of binoculars around a joint shaft that connects the pair of lens barrels of the pair of binoculars; and a holding device that is provided on the base portion and is connected to the joint shaft to support the pair of lens barrels so that said pair of lens barrels may be placed on an upper surface of the base portion to come in contact therewith, and restricts movement of the pair of binoculars in an optical axis direction of the pair of binoculars.

Abstract: The apparatus includes a supporting member disposed at an outer circumference of the ocular optical system and an eyepiece cup. A first member thereof includes a cam follower and a second member thereof includes a cam groove to move the eyepiece cup in an optical axis direction with rotation of the eyepiece cup and an introducing groove through which the cam follower is introduced to the cam groove. One member of the first and second members includes an engaging portion, and another member thereof includes a stopper engaging with the engaging portion to prevent rotation of the eyepiece cup in a direction in which the cam follower is returned from the cam groove toward the introducing groove. The stopper formed integrally with another member is elastically movable so as to be located at and retreated from an engaging position to be engageable with the engaging portion.

Abstract: Binoculars have two tubes connected to each other via a folding bridge and an Abbe-König prism system is arranged in each tube and the Abbe-König prism systems are provided for image reversal of respective visual viewing beam paths. Each Abbe-König system includes an isosceles prism and a roof prism adjacent thereto. A laser transmitter (21) in the first tube (3a) and a corresponding laser receiver (22) in the second tube (3b) can be changed in parallel with respect to the distance to each other by means of the folding bridge (37). One of the two prisms (9, 10) of each Abbe-König prism system (6) is configured with a splitter layer (12, 12?, 12?) or is connected via a cement layer for splitting the viewing beam (7) and laser beam (24) into separate beams with the beams (7, 24) running part way in common in the respective tubes (3a, 3b).

Abstract: A telescope 110 includes: a single objective optical system 113; and a binocular body member (111, 112); the binocular body member including a mount portion 116 for connecting to the objective optical system 113, and a controller 114 for controlling the objective optical system, thereby providing a telescope capable of making binocular observation of an image of an object formed by a single objective lens.

Abstract: The appearance of a color print viewed under UV illumination is predicted using a target comprising color patches each printed using a known coverage of printer colorant(s). In one case, the target is illuminated using a UV light source and an electronic image of the target is captured using a digital camera or the like. In another case, a spectrophotometer is used both with and without a UV cutoff filter to measure the target. The captured image data or the spectrophotometric measurements are used to derive a UV printer characterization model that relates any arbitrary combination of printer colorants to a predicted UV color appearance value. Metameric colorant mixture pairs for visible light and UV light viewing can be determined using the UV model together with a conventional visible light printer characterization model. A visual matching task is used to determine a correction factor for the UV printer characterization model.

Abstract: In a visual target acquisition scope system for an adjustable connection is provided between a zero magnification scope viewed by a first eye of a user and a power scope viewed by a second eye of the user. The system includes first and second movable sections connected and controlled by an adjustment locking mechanisms. According to the system, while the user is looking at the object through said zero magnification power scope by the first eye and looking at the object through the high power scope by the second eye, the target visible to the first eye is simultaneously visible to the second eye, so as to provide immediate acquisition and viewing of the object through the high power scope by the second eye.

Abstract: An optical device for viewing distant objects. The device includes an objective system and at least one ocular and achieves a magnifying power of greater than 0.6 mm?1 times the entrance pupil diameter in millimeters with an exit pupil of at least 2 mm. Images from the objective system are detected by a sensor, processed and recorded. The images are displayed on a display which is observed by the user through one or more oculars. The optical device works well at low light levels. The device also has a slide mechanism for adjusting the interpupillary distance between the oculars.

Abstract: A hand-held telescope or binocular built into a bottle or consumable drink container includes a high quality objective lens; an adjustable focus eye lens; and, optionally, a connector ring to form a binocular; a jacket, sleeve or cuzzi containing information regarding, for example, sporting or scientific events; a baffle to minimize extraneous light from disturbing observational clarity; and a holographic bottle label that portrays sporting or scientific figures in three dimensions.

Abstract: An optical viewing arrangement has an image recording function and each telescope tube thereof has a beam path through an objective and an ocular and has a sensor component assembly for outcoupling and converting a component light beam into digital data. A camera electronic component assembly (9) converts and compresses the digital image data of the sensor component assembly. The assembly (9) has a communications interface (10) for coacting with a communications interface (16) of an external remote-control unit (11) for digital data transmission. The interface (16) coacts with the interface (10) of the external optical viewing arrangement (1) for digital data transmission as well as a touch operator-controlled panel (15) for inputting and/or selecting operator-controlled functions, a microprocessor (24) for data processing incoming and outgoing data, a storage unit (17) for storing the digital data and a display (14).

Abstract: The invention describes a long-range optical device (1) with two observation parts (3, 4) and a first observation beam path (11; 12) and a measurement beam path (25), in which the two observation parts (3,4) are arranged essentially parallel next to each other and spaced a predefinable distance (10) apart via at least one connection element (7). In a plan view of the device 1 with respect to a plane, in which the longitudinal axes (8, 9) of the observation parts (3, 4) are arranged, the sub-regions of the observation parts (3, 4) facing each other lie directly opposite each other over a length aligned parallel to the longitudinal axis (8, 9) of the observation parts (3, 4) of 20% to 90%, preferably 30% to 80% of a length (24) of the observation parts (3, 4). In addition, the observation beam path (11, 12) and the measurement beam path (25) are arranged outside the sub-regions (22, 23) of the observation parts (3, 4).

Abstract: Provided is a device for improving the focus of an object viewed using a night vision instrument.

Abstract: An observation device has an ocular lens and an objective lens and is adapted to observe through the ocular lens an intermediate image of an object formed by the objective lens. The observation device further includes a display section provided either on a light path connecting the ocular lens and the objective lens or on a light path branched off from the light path and displaying an image, and a light path switching section provided on the light path connecting the ocular lens and the objective lens and switching the light to be guided from the ocular lens to the objective lens and the image displayed on the display section to be guided to the ocular lens or the objective lens, thereby providing a small-sized observation device and binoculars having a display function.

Abstract: An optical system includes two lens systems, one that provides viewing of an object with relatively no spherical aberration, and another that provides viewing of the object with significant spherical aberration. Preferably, both lens systems provide viewing of the object with relatively no chromatic aberration. The optical system may have the configuration of binoculars.

Abstract: The invention describes an observation device (1), having at least two observation parts (3, 4) with an ocular side (6) and an objective side (5). In a position of use the longitudinal axes (40, 41) of the observation parts (3, 4) in the region of the ocular sides (6) are spaced apart by a distance (47) of at least 54 mm and the two longitudinal axes (40, 41) define a plane of reference (49).

Abstract: A color-filtering device for enhancing color from a binocular view includes a first variable color filter element a second variable color filter element: and a mechanical assembly for communication of axial rotation to the first and second filter elements.

Abstract: A head-mounted display system is provided. According to one example of an implementation, the head-mounted display system includes at least one sensor detecting surrounding information, a processing unit processing the surrounding information received from the at least one sensor, a display control unit generating display information to be displayed to a user of the system from the processed surrounding information received from the processing unit, and a head-mounted display capable of displaying information received from the display control unit to the user.

Abstract: Binoculars include first and second lens barrels. A bridge interconnects the lens barrels. First and second optical systems are accommodated in respectively the lens barrels. First and second focus lenses are included in respectively the first and second optical systems, for focus adjustment by moving in an optical axis direction. An operation barrel is secured to the bridge, and externally rotatable and movable in the optical axis direction between a focus adjusting position and a diopter adjusting position. A focus adjuster with gear teeth and screw threads moves the first and second focus lenses simultaneously in the optical axis direction when the operation barrel is rotated in the focus adjusting position. A diopter adjuster, including gear teeth, an intermediate rod and screw threads, moves the second focus lens in the optical axis direction when the operation barrel is rotated in the diopter adjusting position.

Abstract: A telescope 110 includes: a single objective optical system 113; and a binocular body member (111, 112); the binocular body member including a mount portion 116 for connecting to the objective optical system 113, and a controller 114 for controlling the objective optical system, thereby providing a telescope capable of making binocular observation of an image of an object formed by a single objective lens.