Abstract: A semiconductor device is provided that includes an array of imaging cells realized from a plurality of layers formed on a substrate, wherein the plurality of layers includes at least one modulation doped quantum well structure spaced from at least one quantum dot structure. Each respective imaging cell includes an imaging region spaced from a corresponding charge storage region. The at least one quantum dot structure of the imaging region generates photocurrent arising from absorption of incident electromagnetic radiation. The at least one modulation doped quantum well structure defines a buried channel for lateral transfer of the photocurrent for charge accumulation in the charge storage region and output therefrom. The at least one modulation doped quantum well structure and the at least one quantum dot structure of each imaging cell can be disposed within a resonant cavity that receives the incident electromagnetic radiation or below a structured metal film having a periodic array of holes.

Abstract: A lighting panel includes a tile having a first side parallel to a principal plane of the lighting panel, a plurality of solid state lighting devices arranged on the first side of the tile and configured to emit light, a reflector sheet on the first side of the tile, and a brightness enhancement film on the reflector sheet. The reflector sheet may be arranged between the tile and the brightness enhancement film and the brightness enhancement film may be configured to increase the on-axis intensity of emitted light. A luminaire adapted for general illumination includes a lighting panel as described above, a current supply circuit configured to supply an on-state drive current to a string of lighting devices in response to a control signal, a photosensor arranged to receive light from one of the solid state lighting devices, and a control system configured to receive an output signal from the photosensor and to adjust the control signal responsive to the output signal of the photosensor.

Abstract: Systems and methods for synchronous operation of debris-mitigation devices (DMDs) in an EUV radiation source that emits EUV radiation and debris particles are disclosed. The methods include establishing a select relative angular orientation between the first and second DMDs that provides a maximum amount of transmission of EUV radiation between respective first and second rotatable vanes of the first and second DMDs. The methods also include rotating the first and second sets of vanes to capture at least some of the debris particles while substantially maintaining the select relative angular orientation. The systems employ DMD drive units, and an optical-based encoder disc in one of the DMD drive units measures and controls the rotational speed of the rotatable DMD vanes. Systems and methods for optimally aligning the DMDs are also disclosed.

Abstract: A light source includes a semiconductor light emitter having an electrical drive input and operatively configured to emit a light beam; a first weakly polarizing beam splitter positioned to capture the light beam, reflecting one portion, and transmitting another portion with an output intensity P. The light source includes a second polarizing beam splitter positioned to capture the reflected portion of the light beam and split it into first and second detector light beams of orthogonal polarizations. The light source further includes first and second detectors capturing those detector light beams, and is configured to deliver corresponding first and second output signals from corresponding detector outputs. The light source includes an electronic circuit coupled to those electrical outputs and to the electrical drive input of the light emitter.

Abstract: The present disclosure is an optical filter which includes: a Fabry-Perot resonator equipped with a laminated structure including one sheet of first metal layer, one sheet of second metal layer, and a dielectric layer; and one sheet of plate-shaped wire grid polarizer. The second metal layer is parallel to the first metal layer, the dielectric layer is interposed between the first metal layer and the second metal layer, the one sheet of plate-shaped wire grid polarizer is embedded in the dielectric layer, the one sheet of plate-shaped wire grid polarizer comprises three or more metal wire layers, the metal wire layers are parallel to one another, and the one sheet of plate-shaped wire grid polarizer is parallel to the first metal layer. In the optical filter according to the present invention, the effective extinction ratio of the wire grid polarizer is increased.

Abstract: Method for detecting metals in a liquid are described. The liquid is contacted with a hexahydrotriazine and/or a hemiaminal material, and a UV absorption spectrum of the material before and after exposure to the liquid is examined to determine whether metals are present in the liquid.

Abstract: A light-receiving sensor (1) includes: a photodiode (PD) for generating a photocurrent by use of a light input; and a first current source (CS), provided in parallel to the photodiode (PD), for generating a first auxiliary current by being driven by a voltage between terminals, which are a terminal (T1) and a terminal (T2). The first current source (CS) is also driven by the voltage between the terminals which voltage is obtained when no light is inputted.

Abstract: A microwave-frequency source, generating an output electrical signal at an output frequency fM, comprises a pump laser source, an optical resonator, and a photodetector. Free spectral range vFSR of the optical resonator equals an integer submultiple of a Brillouin shift frequency vB of the optical resonator (i.e., vB=MvFSR). The pump laser source is frequency-locked to a corresponding resonant optical mode of the optical resonator. Pumping the optical resonator with output of the pump laser source at a pump frequency vpump results in stimulated Brillouin laser oscillation in the optical resonator at respective first, second, and third Stokes Brillouin-shifted frequencies v1=vpump?vB, v2=vpump?2vB, and v3=vpump?3vB. The photodetector receives stimulated Brillouin laser outputs at the first and third Stokes Brillouin-shifted frequencies v1 and v3 and generates therefrom the output electrical signal at a beat frequency fM=v1?v3=2vB.

Abstract: An optical apparatus and a method for identifying wood species of a raw wooden log involve directing light onto a representative portion of a peripheral surface of the wooden log, sensing light reflected on the illuminated representative log portion to generate reflection intensity image data including color image data, subdividing the reflection intensity image data into a plurality of image data regions each containing a preset number of image pixels, analyzing the image data regions to generate associated texture data, analyzing the color and texture data associated with each image data region to assign thereto a probable one of a plurality of species indications, and selecting a majority species indication for the inspected wooden log.

Abstract: An optical pointing device for detecting the direction of the user's finger is provided. The optical pointing device comprises a cover, a light source and a sensor. The cover comprises a press portion with a first surface and a second surface opposite the first surface, as well as a side wall extending downwards from the periphery of the second surface. The light source projects a main beam onto the press portion of the cover. The main beam then forms a first beam passing through the press portion and a second beam reflected by the second surface. The sensor is adapted to receive the second beam reflected by the second surface, and detect the second beam by an algorithm to output the first displacement position. In addition, the light source and the sensor are covered by the cover, while the side wall is a flexible side wall.

Abstract: The system may include a pixel array, a selector, a sampler, and a converter. The pixel array may generate output signals representing radiation incident upon the pixel array. The selector may select one of the output signals. The sampler may sample the selected output signal. The converter may generate a digital signal based upon the selected output signal. The sampler may include a charge integrator that compensates for parasitic capacitance of the selector by selecting a first feedback capacitance to obtain a first sample, and after obtaining the first sample, selecting a second feedback capacitance to obtain a second sample. The first feedback capacitance may be greater than the second feedback capacitance.

Abstract: The invention relates to an optical measuring apparatus (1) for a vehicle (6), having at least one optical transmitter, at least one optical receiver (12) and a deflection mirror arrangement having at least one deflection mirror (11), wherein the edge contour (27, 28) of a deflection mirror (11) of a reception unit of the measuring apparatus (1) matches the contour (41) formed by marginal rays (40) in a received beam (38). The invention also relates to a vehicle having such an apparatus (1).

Abstract: A solid state photonics circuit having a liquid crystal (LC) layer for beam steering. The LC layer can provide tuning of an array of waveguides by controlling the application of voltage to the liquid crystal. The application of voltage to the liquid crystal can be controlled to perform beam steering with the light signal based on different tuning in each of the waveguides of the array. The waveguides are disposed in a substrate having an oxide or other insulating layer with an opening. The opening in the oxide layer exposes a portion of a path of the array of waveguides. The waveguides are exposed to the liquid crystal through the oxide opening, which allows the voltage changes to the liquid crystal to tune the optical signals in the waveguides.

Abstract: A spatiotemporally resolved far-field pulse contrast measuring device includes a plano-convex cylindrical lens, a nonlinear correlation crystal, a plano-convex imaging lens and a signal-receiving system. The signal-receiving system includes a fiber array, a photomultiplier and a digital oscilloscope.

Abstract: A window has a pane of transparent material. A first set of microfluidic channels pass through a first area of the pane, and a second set of microfluidic channels pass through a second area of the pane. Microfluidic planes are in fluid communication with the first and second sets of microfluidic channels. A first pump is in fluid communication with the first set of microfluidic channels, and selectively moves a first fluid having a first level of opacity through the microfluidic planes via the first set of microfluidic channels. A second pump is in fluid communication with the second set of microfluidic channels, and selectively moves a second fluid having a second level of opacity through the microfluidic planes via the second set of microfluidic channels. Moving the second fluid into the microfluidic planes pushes the first fluid out of the microfluidic planes, thereby adjusting an opacity of the window.

Abstract: An array of solar collectors track the sun based on measured values of power output from the array and from a sun sensor on the array. The sun is tracked by periodically adjusting the altitude and azimuth of the array so the collectors remain pointed at the sun to maximize an amount of solar flux reflected from the collectors. The sun sensor, which detects alignment of the sun, recognizes when relative movement of the sun causes about a 10% reduction in power output of the array. The altitude and azimuth of the array are readjusted based on output from the sun sensor. While the array is being reoriented, power output from the array is monitored, and values for power output versus orientation of the array are recorded. Offset values between the power output, sun sensor output, and the ephemeral equations are calculated by comparing these values during operation.

Abstract: An illumination device and method is provided herein for calibrating individual LEDs in the illumination device, so as to obtain a desired luminous flux and a desired chromaticity of the device over changes in drive current, temperature, and over time as the LEDs age. The calibration method may include subjecting the illumination device to a first ambient temperature, successively applying at least three different drive currents to a first LED to produce illumination at three or more different levels of brightness, obtaining a plurality of optical measurements from the illumination produced by the first LED at each of the at least three different drive currents, obtaining a plurality of electrical measurements from the photodetector and storing results of the obtaining steps within the illumination device to calibrate the first LED at the first ambient temperature.

Abstract: One disclosed optical computing device includes a sampling window arranged on a housing, an electromagnetic radiation source configured to emit electromagnetic radiation, the electromagnetic radiation being configured to optically interact with a substance outside of the sampling window, at least one integrated computational element (ICE) core arranged to optically interact with the electromagnetic radiation, and a detector arranged to receive the electromagnetic radiation following its optical interaction with the substance and the at least one ICE core and generate an output signal corresponding to a characteristic of the substance, wherein the electromagnetic radiation impinges upon the surfaces of the sampling window at an angle of incidence from normal to the sampling window, and wherein specular reflected light reflects off the sampling window at an opposing angle of incidence, the specular reflected light emanating away from the sampling window such that it is not detected by the detector.

Abstract: Disclosed herein is an imaging device including: a plurality of pixels disposed to form a matrix having pixel rows, the pixels including a pixel electrode formed on a silicon substrate for one of the pixels by being separated away from another pixel electrodes formed for one of the other pixels, a photoelectric conversion film formed on the pixel electrode, and an opposite electrode formed on the photoelectric conversion film; and a driving section configured to apply an electric potential to the photoelectric conversion film on each of the pixel rows at least having read timings different from each other with a predetermined timing outside an exposure period of the pixels in a direction opposite to that of an electric potential applied to the photoelectric conversion film during the exposure period of the pixels.

Abstract: In some aspects, a flow cytometer system is provided that includes beam shaping optics positioned to manipulate a light beam and produce a resulting light beam that irradiates the core stream at the interrogation zone of the flow cell. The beam shaping optics include an acylindrical lens positioned to receive and focus light in a direction of a first axis orthogonal to a direction of light travel, and a cylindrical lens positioned to receive the light output from the acylindrical lens and to focus the light output from the acylindrical lens in a direction of a second axis orthogonal to the first axis and to the direction of light travel. The resulting light beam output has a flat-top shaped intensity profile along the first axis, and a Gaussian-shaped intensity profile along the second axis. Related methods of shaping a light beam at an interrogation zone of a flow cell are also provided.