Abstract: A system for image enhancement on digital display device is disclosed. The system includes an image processing subsystem including a digital art metadata collection module to measure the ambient condition on a digital art piece using sensors. The digital art metadata collection module collects a set of metadata corresponding to the digital art piece by analysing the ambient condition. The image processing subsystem includes an image adjustment module to modify parameters on digital display device based on the set of metadata using one or more image processing techniques. The image adjustment module generates a target digital image representative of a printed image quality based on the modified parameters.

Abstract: Provided are computing devices that use a module and can exhibit different interfaces. In one embodiment provided is a mobile computing device comprising: a body in shape of a module having two parallel flat surfaces; a processor and a memory placed inside the body; and a docking port at end of the body between the parallel flat surfaces for detachably attaching to a monitor to obtain an electronic connection wherein the computing device is attached to the monitor by resting on one of the flat surfaces to provide one or more of a cellular phone, a laptop computer, a personal computer, a tablet computer, or a watch.

Abstract: A dressing for wounds includes a useful material, such as dye or biocide, trapped within or behind a gelatin barrier. On application to a wound, metalloproteinases naturally present in the wound diffuse into the dressing and degrade the gelatin, releasing the trapped material. The released material serves various useful purposes, such as indicating the status of the wound or improving wound healing.

Abstract: A polarization based medical device for optically stimulating the formation of collagen in tissue comprises a light source for providing a beam of light. A polarizer polarizes the beam of light. A first beam shaping optics directs the polarized beam of light to a spatial light modulator. A second beam shaping optics directs the polarized beam from the spatial light modulator to an area of interest within the tissue. A spatially controlled pattern of polarized light is directed onto the tissue, thereby affecting the orientation of formation of collagen within the tissue.

Abstract: A polarization based medical device for optically stimulating the formation of collagen in tissue comprises a light source for providing a beam of light. A polarizer polarizes the beam of light. A first beam shaping optics directs the polarized beam of light to a spatial light modulator. A second beam shaping optics directs the polarized beam from the spatial light modulator to an area of interest within the tissue. A spatially controlled pattern of polarized light is directed onto the tissue, thereby affecting the orientation of formation of collagen within the tissue.

Abstract: A tissue imaging system (200) for examining the medical condition of tissue (290) has an illumination optical system (205), which comprises a light source (220), having one or more light emitters, beam shaping optics, and polarizing optics. An optical beamsplitter (260) directs illumination light to an imaging sub-system, containing a spatial light modulator array (300). An objective lens (325) images illumination light from the spatial light modulator array to the tissue. An optical detection system (210) images the spatial light modulator to an optical detector array. A controller (360) drives the spatial light modulator to provide time variable arrangements of on-state pixels. The objective lens operates in a nominally telecentric manner relative to both the spatial light modulator and the tissue. The polarizing optics are independently and iteratively rotated to define variable polarization states relative to the tissue.

Abstract: A light therapy device (40) for delivering light energy to treat medical conditions in tissues (200) includes a light source (300) with one or more light emitters, which provides input light (305). A light coupling means comprised of one or more optical fibers (310) for coupling the input light into a bandage portion (100) comprising a flexible optical substrate (50). A light extraction means (30) directs a portion of the input light out of the bandage and towards one or more localized areas of the tissues. A semi-permeable transparent membrane (400), attached directly or indirectly to the substrate, controls a flow of moisture and moisture vapor to and from the tissues. A controller (16) means controls a light dosage emitted from the light therapy device.

Abstract: A light therapy bandage (300) for treating medical conditions comprises a plurality of flexible sheet circuitry (350), each of which is fabricated with a serpentine pattern provided with one or more surface mounted light emitting devices (372). A flexible transparent material (470) included within the substrate (410) and the surface mounted light emitting devices are imbedded in the flexible transparent material. A semi-permeable transparent membrane (450) controls the flow of moisture and moisture vapor to and from the tissues (200). A plurality of vapor channels (460) extend from the semi-permeable transparent membrane and through the substrate.

Abstract: A dressing for wounds (10) contains a useful material (40), such as dye or biocide, trapped within or behind a gelatin barrier (36). On application to a wound, metalloproteinases naturally present in the wound diffuse into the dressing and degrade the gelatin, releasing the trapped material. The released material serves various useful purposes, such as indicating the status of the wound or improving wound healing.

Abstract: A polarization based medical device (300) for optically stimulating the formation of collagen in tissue (100) comprises a light source (310) for providing a beam of light. A polarizer polarizes the beam of light. A first beam shaping optics (320) directs the polarized beam of light to a spatial light modulator (340). A second beam shaping optics (350) directs the polarized beam from the spatial light modulator to an area of interest within the tissue. A spatially controlled pattern of polarized light is directed onto the tissue, thereby affecting the orientation of formation of collagen within the tissue.

Abstract: A polarization based diagnostic device (200) for optically examining the medical condition of tissue (290) comprises an illumination optical system (205), comprising a light source (220) and beam shaping optics. An optical detection system (210) comprises imaging optics and an optical detector array, which detects light from the tissue. Polarizing optics provided in both the illumination optical system and the optical detection system are crossed and pass orthogonal polarization states. Iterative rotational means rotate the orthogonal polarization states relative to the tissue being examined. Image enhancement means includes image processing, sequential multi-spectral illumination and imaging, and image focus control to facilitate quality imaging at varying depths within the tissue. A controller (215) operates the light source, the detector array, the multi-spectral illumination and imaging, image focus control, and image processing.

Abstract: A light therapy device (40) for delivering light energy to a portion of a patient's body comprises a light source (115). The light source comprises one or more light emitters (122) for providing input light. A light coupling means (80) directs the input light into a light guide (140). A flexible optically transparent light guide material comprises the light guide. A light extraction means (75) is applied to a surface of the light guide material. The light extraction means is positioned to provide light therapy treatment to one or more localized areas of the patient's body. A control means controls a light dosage relative to intensity, wavelength, modulation frequency, repetition, and timing of treatments.

Abstract: A system for creating a patterned polarization compensator (550) has a retardance characterization system (560) for optically scanning the spatially variant retardance of a spatial light modulator (210). A compensator patterning system (565) writes a spatially variant photo-alignment pattern on a substrate (555) of a polarization compensator. The patterned polarization compensator is completed by a process that includes providing a photo-alignment layer onto which spatially variant photo-alignment layer is formed, providing a liquid crystal polymer layer onto the photo-alignment layer, and then fixing the liquid crystal polymer layer to form a spatially variant retardance pattern into the structure of the patterned polarization compensator.

Abstract: Disclosed is an optical device comprising a polarizer package comprising an integrated combination of an absorbing layer and a compensator. Two of the identical polarizer packages can be crossed and used in a transmissive optical device. This polarizer package can also be used in combination with a reflective plate and a quarter wave plate in a reflective optical device. Such polarizer packages exhibit an improved viewing angle characteristic across all wavelengths of interest, has a large tolerance for compensators to be aligned relative to their preferred directions, and can be used within an LCD or emissive display system.

Abstract: A projection display apparatus (10) uses a modulation optical system (200) that includes a liquid crystal device (210) in combination with a wire grid polarization beamsplitter (240), a wire grid polarization analyzer (270) and a projection lens (285) to form an image. In order to achieve high contrast and maintain high brightness levels, a compensator (260) is provided for minimizing leakage light for pixels in the black (OFF) state. A number of configurations are possible, such as with the compensator (260) disposed in the optical path between the liquid crystal device (210) and the wire grid polarization beamsplitter (240) and with a secondary compensator (265) disposed between wire grid polarization analyzer (270) and the wire grid polarization beamsplitter (240).

Abstract: A modulation optical system (40) provides modulation of an incident light beam. A wire grid polarization beamsplitter (240) receives the beam of light (130) and transmits a beam of light having a first polarization, and reflects a beam of light having a second polarization orthogonal to the first polarization. Sub-wavelength wires (250) on the wire grid polarization beamsplitter face a reflective spatial light modulator. The reflective spatial light modulator receives the polarized beam of light and selectively modulates the polarized beam of light to encode data thereon. The reflective spatial light modulator reflects back both the modulated light and the unmodulated light to the wire grid polarization beamsplitter. The wire grid polarization beamsplitter separates the modulated light from the unmodulated light. A compensator (260) is located between the wire grid polarization beamsplitter and the reflective spatial light modulator (210).

Abstract: An organic vertical cavity laser light producing device (10) comprises a substrate (20). A plurality of laser emitters (200) emits laser light in a direction orthogonal to the substrate. Each laser emitter within the plurality of laser emitters has a first lateral mode structure in a first axis orthogonal to the laser light direction and has a second lateral mode structure in a second axis orthogonal to both the laser light direction and the first axis. Each laser emitter comprises a first mirror provided on a top surface of the substrate (20) and is reflective to light over a predetermined range of wavelengths. An organic active region (40) produces laser light (350). A second mirror is provided above the organic active region and is reflective to light over a predetermined range of wavelengths. A pumping means excites the plurality of laser emitters.

Abstract: A modulation optical system (40) provides modulation of an incident light beam. A wire grid polarization beamsplitter (240) receives the beam of light (130) and transmits a beam of light having a first polarization, and reflects a beam of light having a second polarization orthogonal to the first polarization. Sub-wavelength wires (250) on the wire grid polarization beamsplitter face a reflective spatial light modulator. The reflective spatial light modulator receives the polarized beam of light and selectively modulates the polarized beam of light to encode data thereon. The reflective spatial light modulator reflects back both the modulated light and the unmodulated light to the wire grid polarization beamsplitter. The wire grid polarization beamsplitter separates the modulated light from the unmodulated light. A compensator (260) is located between the wire grid polarization beamsplitter and the reflective spatial light modulator (210).