Abstract: One embodiment provides a computing device comprising a computing device body, a display coupled with the computing device body, a first set of computing components incorporated into the computing device body, and a securing system configured to secure the body to a wrist, the securing system comprising a plurality of detachable modular segments joined together to form a second set of computing components that is modifiable by changing segments. Each modular segment comprises a first mechanical connector and a second mechanical connector, a first set of electrical connectors and a second set of electrical connectors, and one or more electrical components incorporated into the modular segment, such that a functionality of the computing device is modifiable by changing modular segments.

Abstract: Technology is disclosed for optimizing a near-eye display using a waveguide. A first waveband for a first color narrower than the full spectral bandwidth for the first color and a second waveband for a second color adjacent to the first color in the visible spectrum are generated in image light of an image generation unit like a microdisplay. The first waveband and the second waveband are coupled into a same layer of a diffractive waveguide. An input grating of the same layer of the waveguide has a grating wavelength band approximately matching a waveband extensive with the first waveband and the second waveband. A converted green light emitting diode (LED) may be used for obtaining a first waveband centered around 515 nm in some examples. One of more of the wavebands may be obtained using filters, for example filters using dichroic mirrors, quantum dots or a combination of these.

Abstract: A binocular head mounted display includes a first binocular eye piece including a first torsional brace and a second binocular eye piece including a second torsional brace configured to engage the first torsional brace. The binocular head mounted also includes a frame assembly holding the first binocular eye piece and the second binocular eye piece at an adjustable interpupillary distance. The frame assembly includes a torsional support to directly or indirectly engage the first torsional brace and the second torsional brace. Such engagement resists rotational movement of the first binocular eye piece relative to the second binocular eye piece.

Abstract: Examples are disclosed that relate to obtaining high-resolution images of regions of interest in a physical space. One disclosed example provides an imaging system, comprising a first camera, a second line-scan camera configured to capture a higher-resolution image than the first camera, a logic subsystem, and a storage subsystem. The storage subsystem holds instructions executable by the logic subsystem to, obtain, via the first camera, a lower-resolution image of a physical space, identify one or more regions of interest in the physical space based on the lower-resolution image, and, for each of the one or more regions of interest, obtain, via the second line-scan camera, a higher-resolution image of at least a portion of the region of interest.

Abstract: A scroll wheel assembly for computer input device having a housing. The scroll wheel assembly includes a housing and an engagable scroll wheel. The scroll wheel is rotatable with a shaft to preferably cause vertical scrolling of an image on a display. The scroll wheel is laterally tiltable relative to the housing and the shaft. A sensor is preferably positioned within the housing for sensing tilting of the rotatable member. In response to sensed tilting movement of the rotatable member, the image is horizontally scrolled, preferably in the direction of the lateral movement. The computer input device having the rotatable member may take the form of a keyboard, a mouse, a trackball device, or another type of computer input device.

Abstract: In embodiments of a transparent display backlight assembly, a backlight panel is operable as a transparent panel, and a light source generates light that the backlight panel directs from the light source to illuminate a display panel of a display device. Light refraction features refract and scatter the light, where the light refraction features are spaced for approximate transparency of the backlight panel and to illuminate the display panel. An active diffuser can be implemented as an additional transparent panel and operable for activation to diffuse the light from the backlight panel that illuminates the display panel.

Abstract: An activity monitoring apparatus is provided. The activity monitoring apparatus includes a retention feature configured to removably secure the monitoring apparatus to a participant performing a physical activity. The activity monitoring apparatus further includes a clasping mechanism configured to receive a mobile electronic device and removably secure the mobile electronic device to the monitoring apparatus. The activity monitoring apparatus further includes a physiological data collector and electronic circuitry. The physiological data collector is configured to collect physiological data associated with the participant performing the physical activity. The electronic circuitry is configured to receive the physiological data associated with the participant from the physiological data collector, process the physiological data, and wirelessly transmit the processed physiological data to the mobile electronic device for display on the mobile electronic device.

Abstract: In embodiments of imaging structure emitter calibration, an imaging unit includes an emitter structure that direct emits light, and optics direct the light along a light path in the imaging unit to illuminate a projection surface. A reflective panel reflects a portion of the light to illuminate a light sensor. An imaging application receives the sensor data from the light sensor, where the sensor data corresponds to emitted light output from the emitter structure. The imaging application can then initiate a calibration input to the emitter structure to adjust the emitted light output from the emitter structure.

Abstract: In embodiments of a transparent display backlight assembly, a backlight panel is operable as a transparent panel, and a light source generates light that the backlight panel directs from the light source to illuminate a display panel of a display device. Light refraction features refract and scatter the light, where the light refraction features are spaced for approximate transparency of the backlight panel and to illuminate the display panel. An active diffuser can be implemented as an additional transparent panel and operable for activation to diffuse the light from the backlight panel that illuminates the display panel.

Abstract: In embodiments of a hinge electrical interconnection guide, a portable device includes a first housing integrated with a display device, and a second housing movably coupled to the first housing. A hinge assembly includes a hinge link to couple hinge mechanisms that are movably operable to open and close the first and second housings of the portable device relative to each other. An electrical interconnection guide is integrated with the hinge link and designed to route an electrical interconnection in a first configuration between the first and second housings of the device when closed relative to each other. The electrical interconnection guide is also designed to route the electrical interconnection in a second configuration between the first and second housings of the device when open relative to each other.

Abstract: A binocular display includes a waveguide. A convex spherical mount has a fixed position relative to the waveguide. A light engine includes a concave spherical mount that adjustably mates with the convex spherical mount.

Abstract: In embodiments of selective illumination of a region within a field of view, an illumination system includes light sources implemented for selective illumination of a target within a field of view of an imaging system. The illumination system also includes optics that can be positioned to direct light that is generated by a subset of the light sources to illuminate a region within the field of view. An imaging application can activate the subset of the light sources and position the optics to illuminate the region within the field of view that includes the target of the selective illumination.

Abstract: In embodiments of an imaging structure with embedded light sources, an imaging structure includes a silicon backplane with a driver pad array. The embedded light sources are formed on the driver pad array in an emitter material layer, and the embedded light sources can be individually controlled at the driver pad array to generate and emit light. A conductive material layer over the embedded light sources forms a p-n junction between the emitter material layer and the conductive material layer. Micro lens optics can be positioned over the conductive material layer to direct the light that is emitted from the embedded light sources. Further, the micro lens optics may be implemented as parabolic optics to concentrate the light that is emitted from the embedded light sources.

Abstract: In embodiments of selective illumination, an illumination system includes light sources implemented for selective illumination of a target within a field of view of an imaging system. The illumination system also includes optics that can be positioned to direct light that is generated by a subset of the light sources to illuminate a region within the field of view. An imaging application can activate the subset of the light sources and position the optics to illuminate the region within the field of view that includes the target of the selective illumination.

Abstract: In embodiments, an encoded micro pattern includes segments of encoded bits that can be optically-imaged by a digitizer. The position of each segment in the encoded micro pattern can be determined from the encoded bits in a segment. Each of the segments of the encoded micro pattern also includes a fiducial marker that indicates an orientation of a segment in the encoded pattern. The encoded bits of the encoded micro pattern can be integrated into a display surface of a display device, or integrated in a display screen that is positioned over the display surface of a display device.

Abstract: In embodiments of an imaging structure with embedded light sources, an imaging structure includes a silicon backplane with a driver pad array. The embedded light sources are formed on the driver pad array in an emitter material layer, and the embedded light sources can be individually controlled at the driver pad array to generate and emit light. A conductive material layer over the embedded light sources forms a p-n junction between the emitter material layer and the conductive material layer. Micro lens optics can be positioned over the conductive material layer to direct the light that is emitted from the embedded light sources. Further, the micro lens optics may be implemented as parabolic optics to concentrate the light that is emitted from the embedded light sources.

Abstract: In embodiments of a flexible display extendable assembly, an extendable assembly includes a slideable display guide integrated in a first housing part of an extendable electronic device. The extendable electronic device includes a flexible display that slide-engages into the first housing part of the extendable electronic device. The extendable assembly includes an extendable mechanism that is coupled in a second housing part of the extendable electronic device and to the slideable display guide. The first and second housing parts of the extendable electronic device slide-engage relative to each other. The extendable mechanism is implemented to extend as the first and second housing parts slide apart relative to each other, and also to retract as the first and second housing parts slide together relative to each other.

Abstract: An apparatus for determining a location of an object on a planar surface is provided. The apparatus includes a retractable emitter strip, a retractable detector strip, and electrical circuitry. The retractable emitter strip is extendable from the apparatus and includes electro-optical emitters for generating optical energy and directing the optical energy across a planar surface. The retractable detector strip is extendable from the apparatus and includes optical detectors for receiving other optical energy directed across the planar surface from another instance of the apparatus. The retractable emitter strip and the retractable detector strip extend in different directions from the apparatus. The electrical circuitry drives the electro-optical emitters to produce the optical energy according to a pre-defined pattern and processes electrical signals received from the optical detectors to generate object location information.

Abstract: In embodiments of a folded imaging path camera, a device includes a camera lens module that focuses an image, which is received as reflected light. An image sensor captures the image from the reflected light that is directed at the image sensor. The device also includes one or more optics that fold the reflected light of the image along an imaging path directed through the camera lens module and directed at the image sensor. The imaging path directed through the camera lens module can be approximately perpendicular to an axis along which the reflected light of the image is received via an aperture in the device. Alternatively, the imaging path directed through the camera lens module is approximately parallel to the axis along which the reflected light of the image is received via the aperture in the device.

Abstract: In embodiments of laser illumination scanning, an imaging unit includes a linear array of spatial light modulators that direct light in a direction perpendicular to an imaging scan direction. The lasers each emit the light through a diffractive optic that uniformly illuminates the spatial light modulators, and a scanning mirror then scans the spatial light modulators to generate a two-dimensional image for display. The lasers can include red, green, and blue lasers for RGB illumination of the spatial light modulators, which can be implemented as reflective liquid crystal on silicon (LCOS), transmissive LCOS, or as micro-electro-mechanical systems (MEMS) mirrors.