Abstract: Apparatus and methods are disclosed herein for providing a sensing reservoir having one or more sensors integrated with the reservoir for measuring one or more properties of the fluid contained in the reservoir. The sensing reservoir may comprise one or more sensors configured to measure an amount of the fluid contained in the reservoir, an optical property of the fluid contained inside the reservoir, and/or a conductivity of the fluid contained inside the reservoir. The various properties or characteristics of the fluid contained in the reservoir, as determined by the one or more fluid sensors as disclosed herein, may be used to derive information about the composition or nutritional value of the fluid.

Abstract: An image capture device, such as a smartphone or point of sale scanner, is adapted for use as an imaging spectrometer, by synchronized pulsing of different LED light sources as different image frames are captured by the image sensor. A particular implementation employs the CIE color matching functions, and/or their orthogonally transformed functions, to enable direct chromaticity capture. These and various other configurations of spectral capture devices are employed to capture spectral images comprised of spectral vectors having multi-dimensions per pixel. These spectral images are processed for use in object identification, classification, and a variety of other applications. Particular applications include produce (e.g., fruit or vegetable) identification. A great variety of other features and arrangements are also detailed.

Abstract: An illumination system uses a plurality of lamps with each lamp including a modular connector configured for connecting to a streaming data signal. Each lamp further includes an enumerating feature, with a second modular connector, so that a series or array of such lamps can be daisy-chained and thus connected to a control signal such as using the DMX512 standard. Each lamp is intended to retrofit a border light fixture in a stage, studio or entertainment lighting application. The enumeration of each lamp can be done by fixed assignment in the microprocessor nonvolatile memory, or by means of a dual-inline packaged switch bank (DIP switch), or by other electronic or electro-mechanical means. Such numbering is needed to allow each retrofit lamp to have a unique unit number so that it can be specifically addressed and get dimming instructions independently from other retrofit bulbs that share the same data stream.

Abstract: An image capture device, such as a smartphone or point of sale scanner, is adapted for use as an imaging spectrometer, by synchronized pulsing of different LED light sources as different image frames are captured by the image sensor. A particular implementation employs the CIE color matching functions, and/or their orthogonally transformed functions, to enable direct chromaticity capture. These and various other configurations of spectral capture devices are employed to capture spectral images comprised of spectral vectors having multi-dimensions per pixel. These spectral images are processed for use in object identification, classification, and a variety of other applications. Particular applications include produce (e.g., fruit or vegetable) identification. A great variety of other features and arrangements are also detailed.

Abstract: A multiple junction photovoltaic cell is optically coupled to the Fresnel lens with teeth. The set of teeth within a given ring of a ringed pattern of teeth on the Fresnel lens may have 1) varying surface angles of different teeth across the lens, 2) varying refractive indexes of the different teeth or 3) a combination of both. The differing surface angles or refractive indexes of different teeth within a given ring of a ringed pattern of teeth establish multiple focal lengths aimed at five or more different axial target focal points within an anticipated zone of operation relative to the multiple junction photovoltaic cell to create a window of averaged intensity of light defined by the five or more different axial target focal points.

Abstract: Light emitting diodes (LEDs) emit light at a first wavelength. A phosphor material close to LEDs converts at least some of the light to a second wavelength. The light at both wavelengths passes through a light collecting unit. A reflecting polarizer transmits both wavelengths in a first polarization state and reflects light at both wavelengths in a second, orthogonal, polarization state. Light reflected by the reflective polarizer is directed back towards the phosphor material without any substantial increase in angular range. The resulting output light beam contains polarized light at the first and second wavelengths. In some embodiments, an array of LEDs includes LEDs that emit light at a first wavelength and others that emit light at a second wavelength. The phosphor material is disposed on the LEDs emitting the light at the first wavelength.

Abstract: A projection display system includes a projection lens assembly that has multiple projection lens elements that are configured to receive light imparted with display information by a pixelated display device. The projection lens elements project the light toward a display screen. A pixel-shifting element is included within the projection lens assembly to cyclically shift between at least two positions within the projection lens assembly to form at a display screen at least two interlaced arrays of pixels. An electro-mechanical transducer is coupled to the pixel-shifting element to impart on it the cyclic shifting between positions.

Abstract: A microdisplay projection system employs blue, red and green LED illuminators. Optics are provided to direct light from the blue LED illuminator to a blue LCD panel, to direct light from the red LED illuminator to a red LCD panel, and to direct light from the green LED illuminator to first and second green LCD panels.

Abstract: An illumination system and a projection system incorporating same are disclosed. The illumination system includes a two-dimensional array of independently operable light sources. Each light source illuminates substantially the entire active area of a pixelated optical light modulator. Each light source emits light in different emission directions. Each emission direction is directed to a respective location in the active area. Each pixel in the active area is illuminated by an incident cone of light from the two-dimensional array of independently operable light sources. The cone has a cone angle and includes at least one light ray from each light source. The cone angle of at least one such cone of light can be controlled by adjusting the intensity of one or more of the independently operable light sources.

Abstract: An illumination system is disclosed for use with an array of imaging mirrors such as in a projection imaging system. The projection imaging system includes projection optics and first and second light source assemblies located in first and second illumination locations. The imaging mirrors are individually controllable between first and second different reflecting states to form an image, the first reflecting state causing light from the first illumination location to be reflected to the projection optics and the second reflecting state causing light from the second illumination location to be reflected to the projection optics.

Abstract: An illumination source includes a number of light emitting diodes (LEDs) operating at a first wavelength. Light from the LEDs illuminates a phosphor material that generates light at a second wavelength. A reflective polarizer transmits light at the second wavelength in a first polarization state and reflects light at the second wavelength in a second polarization state orthogonal to the first polarization state. The light at the second wavelength reflected by the reflective polarizer is directed back towards the phosphor material without an increase in angular range. In some embodiments the LEDs, having a conformal layer of phosphor material, are attached directly to the first surface of a liquid cooled plate. A liquid coolant contacts a second surface of the plate.

Abstract: An illumination system, such as may be used to illuminate an image display device in an image projection system, includes a plurality of light sources capable of emitting output light. In some embodiments, the light sources are light emitting diodes (LEDs). The light-collecting system transforms light from the plurality of light sources into a substantially telecentric illumination beam. The substantially telecentric illumination beam passes into the integrating tunnel, to produce an illumination beam having a substantially uniform brightness cross-sectional profile.

Abstract: A color display system includes a color light separator that separates incident white illumination light into red, green and blue wavelength bands to be directed to distinct color component sub-pixels (sometimes called dots) that are arranged in a dot-matrix, color triad arrangement (e.g., stripe or delta) to form individual picture elements (pixels) on a pixelated electronic image device (e.g., LCD of DMD). The entire picture is optically shifted from one set of color component sub-pixels to another in a 3-field sequence. As a result, the sets of red, green and blue color component sub-pixels appear to an observer as a single full-color image, thereby providing a dot sequential color display.

Abstract: Light sources are disclosed utilizing LED dies having at least one emitting surface. An optical element is provided for efficiently extracting light out of an LED die by controlling the angular distribution of the emitted light. The optical element is optically coupled to but is mechanically decoupled from the emitting surface of the LED die. The optical element has an input surface that is optically coupled to the emitting surface, an output surface that is larger in surface area than the input surface, and at least one intermediate surface.

Abstract: An image projection system has two illumination beams of different colors. A first polarizing beamsplitter (PBS) has first and second input faces. Light of the first color is incident on the first input face and the light of the second color is incident on second input face. At least some of the light of the first color propagates from the first PBS to a first imager unit via a second PBS. The light of the second color propagates from the first PBS to a second imager unit via, in some embodiments, the second PBS and, in other embodiments, via a third PBS. One type of PBS includes a polarizing layer and a dichroic optical layer that is substantially transparent for light of the first color in a first polarization state and is substantially reflective for light of the second color in a polarization state orthogonal to the first polarization state.

Abstract: A projection system having an imager panel uses a scrolling prism assembly to illuminate different portions of the imager panel with light of different color simultaneously. The scrolling prism assembly can split light from a white light source into two or more different color bands that propagate through the scrolling prism in different directions, and it can reflectively combine the light so that the different color bands pass out of the scrolling prism assembly parallel. The scrolling prism assembly can also compensate for chromatic aberrations in the light received from the light source.

Abstract: A table-top rear projection television employs a single large-panel (e.g., 7 inch-15 inch, 17.5 cm-38 cm, diagonal), multi-color transmissive imaging device (e.g., an amorphous silicon liquid crystal display). The rear projection television has a cabinet with a pedestal having a height and a depth that are each less than or equal to about 0.65 the height of the display screen. The display screen may have any aspect ratio of a wide format (e.g., 16:9, 15:9, 16:10) or a conventional format (i.e. 4:3).

Abstract: A projection display system includes a projection lens assembly that has multiple projection lens elements that are configured to receive light imparted with display information by a pixelated display device. The projection lens elements project the light toward a display screen. A pixel-shifting element is included within the projection lens assembly to cyclically shift between at least two positions within the projection lens assembly to form at a display screen at least two interlaced arrays of pixels. An electromechanical transducer is coupled to the pixel-shifting element to impart on it the cyclic shifting between positions.

Abstract: Light-collecting illumination systems are disclosed, which include a light source module, a first meniscus lens having a convex side and a concave side and a second meniscus lens having a convex side and a concave side. The concave side of the second meniscus lens is adjacent to the convex side of the first meniscus lens and the concave side of the first meniscus lens faces the light source module for receiving light therefrom. In addition, light-collecting illumination systems are disclosed, which include a plurality of light source modules and a system of optical elements comprising a plurality of pairs of meniscus lenses, each pair being associated with a light source module.