Abstract: An optical sensor assembly in which a four axis gimbal and dual coelostat mirror configuration provide pointing of the sensor line of sight in azimuth and elevation, stabilized for platform pitch. One example of a sensor system includes a first optical sub-system including a first plurality of optical elements, and a second optical sub-system configured to rotate about a first axis relative to the first optical sub-system. The second optical sub-system includes afocal foreoptics configured to direct a collimated beam of electromagnetic radiation to the first optical sub-system, a first coelostat minor configured to rotate about a second axis substantially perpendicular to the first axis, and a second coelostat mirror configured to rotate about a third axis substantially perpendicular to both the first axis and the second axis, and to receive electromagnetic radiation reflected by the first coelostat minor and to direct the electromagnetic radiation to the afocal foreoptics.

Abstract: A deformable optical lens with a lens membrane having an optically active portion that is configured to be shaped over an air-membrane interface according to a spherical cap and Zernike polynomials is provided. The spherical cap and the Zernike polynomials comprise a Zernike[4,0], (Noll[11]) polynomial and are sufficient to model the deformable optical lens to within approximately 2 micrometers.

Abstract: Systems, methods and/or techniques for processing solderbrace using one or more light wavelength filters are described. A method of processing solderbrace material may include applying solderbrace material to a wafer, placing a light wavelength filter between the solderbrace material and a broadband light source and exposing the light wavelength filter to broadband light from the broadband light source. The light wavelength filter may block some wavelengths of light and may allow other wavelengths of light to pass through and strike the solderbrace material. In some embodiments, the light wavelength filter may be an I-Line filter that is adapted to block substantially all wavelengths of light and allow passage of I-Line wavelengths of light. In some embodiments, the light wavelength filter may be an I-Line filter that is adapted to block substantially all G-Line and H-Line wavelengths of light and allow passage of substantially all I-Line wavelengths of light.

Abstract: The present invention relates to a pulse splitting device (5) adapted to receive irradiation pulses (10) with a central wavelength (1) from a pulsed irradiation source (2) and output a plurality of sub-pulses (11,12,15,17) for each incoming irradiation pulse. The received irradiation pulses and the pulse splitter (5) interacts so that a first and a second sub-pulse (11,12) are temporally separated by a first optical path length (OP1) in a first region and a second optical path length (OP2) in a second region, respectively. The first optical path length (OP1) times the group velocity dispersion (GVD1) with respect to wavelength in the first material, is balanced with the second optical path length (OP2) times the group velocity dispersion (GVD2) with respect to wavelength in the second material, so that the dispersion broadening of the first and the second sub-pulses (11,12) is substantially equal. This facilitates improved subsequent dispersion compensation by both sub-pulses.

Abstract: An electronic device that includes a sensor mechanism is described. During operation of the electronic device, the sensor mechanism provides sensor data based on measurements of an environmental condition in an external environment that includes the electronic device. Based on the sensor data, a control mechanism selects an illumination pattern from a set of illumination patterns, which are associated with illumination of the external environment. For example, at least two of the illumination patterns have: different spatial patterns in the external environment, different wavelengths of light and/or different light intensities. Moreover, an illumination mechanism illuminates at least a portion of the external environment based on the selected illumination pattern.

Abstract: An optical filter includes first and second substrates, first and second mirrors and first and second electrodes. The second substrate includes first, second and third surfaces. The second surface surrounds the first surface in a plan view, and the third surface surrounds the second surface in a plan view. A second height of the second surface is lower than a first height of the first surface, and a third height of the third surface is higher than the first height of the first surface. The first, second and third surfaces face a single flat surface of the first substrate. The first mirror is disposed on the first substrate. The second mirror is disposed on the first surface of the second substrate. The first electrode is disposed on the first substrate. The second electrode is disposed on the second surface of the second substrate and faces the first electrode.

Abstract: A solid-state imaging device according to an embodiment includes: an imaging element including a semiconductor substrate and a plurality of pixel blocks, each of the pixel blocks including at least two of R pixels, G pixels, B pixels, and W pixels; a first optical system configured to form an image of an object on an imaging plane; and a second optical system including a microlens array having a plurality of microlenses provided for the respective pixels blocks, the second optical system being located between the imaging element and the first optical system, the second optical system being configured to reduce and re-image the image formed on the imaging plane onto each of the pixel blocks. A proportion of the W pixels to be provided increases in a direction from a center of each pixel block toward an outer periphery thereof.

Abstract: An optical element is provided, which is small in distortion when at least three optical members including a resin layer sandwiched by the optical members are cemented together, has a high environmental resistance and optical performance, and has an excellent chromatic aberration correction effect. In the optical element, the resin layer is formed on one of light incident/exit surfaces of a first optical member, and a second optical member is cemented to the resin layer by a bonding material. A condition of ?g<?r is satisfied where ?r indicates an outer diameter of the resin layer and ?g indicates an effective region diameter of a surface of the second optical member which is cemented to the resin layer.

Abstract: Provided is a high-reliability, compact, and low-cost optical sensor device. The optical sensor device includes a glass lid substrate (2), a glass substrate (9) with a cavity having divided and exposed through-hole electrodes (5) on the periphery thereof, and an optical sensor element (3) mounted on the glass lid substrate, and has a structure in which the glass lid substrate and the glass substrate with a cavity are bonded together. By hermetically sealing with the glass substrates, high reliability is secured. By using the divided through-hole electrodes, the package size is reduced and the number of devices which can be produced in a batch in the manufacture increases, which enables cost reduction.

Abstract: An optical filter for filtering an electromagnetic radiation of variable angle of incidence, includes a stack of at least one dielectric or semi-conductor layer arranged between two partially reflective layers, said stack defining a set of Fabry-Pérot cavities set to a predetermined wavelength. The average refractive index of the dielectric or semi-conductor layer is variable in a plane orthogonal to the direction of the stack so as to compensate the effects of the variation in the angle of incidence of the electromagnetic radiation on the transmission spectrum of the cavities.

Abstract: A method for detecting mentholated tobacco, comprising irradiating tobacco containing menthol and a fluorescent taggant with radiation and observing the tobacco for fluorescence from the taggant. A system and method for detecting and separating mentholated tobacco from non-mentholated tobacco within a product stream is also provided.

Abstract: An exemplary optical sensor element for use in an optical sample analyzing apparatus, includes a housing that includes at least one optical sensor component. A housing body and a housing lid are removably connected to the housing body so that in an assembled state, the housing body and the housing lid form a fluid-tight housing. The housing lid is equipped with replaceable moisture control elements.

Abstract: An outer part for a device which is attachable thereto as a housing and/or an attachment part, a first reflective surface and a second reflective surface being formed on the outer part so that at least one signal emitted by an optical and/or acoustic source is directly or indirectly deflectable onto at least one detector surface of an optical and/or acoustic detector, an optical path being configured as a cavern or continuous recess in the outer part or as a depression of a boundary surface of the outer part, the optical path having at least one opening via which at least one substance is transferable into the optical path, and the at least one signal being deflectable into the optical path to the second reflective surface which is formed at a second end of the optical path with the first reflective surface at a first end of the optical path.

Abstract: According to an embodiment of the disclosure, an optical sensor system comprises a mast, a mast mirror, a navigation unit, one or more faceted mirrors, and at least two beam-steering mirrors. The mast is elevated from a vehicle. The mast mirror reflects signals either to or from object space along a line of sight. The navigation unit determines a location and attitude of the mast mirror. The one or more faceted mirrors reflect an error sensing beam to reveal a flexure of the mast mirror. The at least two beam-steering mirrors prevent the line of sight for the signals reflected off the mast mirror from walking off the mast mirror by adjusting an angle and translation of the signals reflected off the mast mirror.

Abstract: A method for classifying a tissue sample of a biopsy specimen into one of a plurality of classes is presented. The method includes receiving a light from at least one location of the tissue sample including a plurality of chromophores, wherein the received light comprises at least one of an attenuated illumination light and a re-emitted light. The method further includes processing a spectrum of the received light to determine a feature for each of the chromophores in the at least one location of the tissue sample. In addition, the method includes estimating a Z-score for each of the chromophores based on the determined feature. Also, the method includes classifying the tissue sample into one of the plurality of classes based on the estimated Z-score for each of the chromophores.

Abstract: The invention relates to a charged-particle multi-beamlet lithography system. The system comprises a beam generator for generating a plurality of beamlets, a beamlet blanker array for patterning the plurality of beamlets, an optical fiber arrangement, and a projection system. The beamlet blanker array comprises a substrate provided with a first area comprising one or more modulators and a second area free of modulators. The beamlet blanker array comprises one or more light sensitive elements, electrically connected to the one or more modulators, and arranged to receive light beams carrying pattern data. The optical fiber arrangement comprises a plurality of optical fibers for guiding the light beams carrying pattern data towards the one or more light sensitive elements. The projection of the optical fiber arrangement onto a surface of the beamlet blanker array in a direction perpendicular to the surface falls entirely within the second area.

Abstract: The present invention is directed toward a system and method for projecting holographic optical traps whose intensity maxima are extended along specified paths in three dimensions with specified amplitude and phase profiles along those paths. Specifying paths that constitute knotted loops and phase profiles that direct radiation pressure along the knotted paths yields optical traps that exert knotted force fields. Knotted optical force fields have uses for inducing motion along knotted paths, with applications including the generation of knotted electric current loops in plasmas.

Abstract: A package structure with a sensor chip having a first substrate with front and back opposing surfaces, a plurality of photo detectors and contact pads formed at the front surface and electrically coupled together, a plurality of first electrical contacts each extending from the back surface and through the first substrate to one of the contact pads, and a plurality of second electrical contacts each extending from the back surface and through the first substrate to the front surface. The liquid crystal lens includes a layer of liquid crystal material, one or more lead patterns adjacent the layer of liquid crystal material, and a plurality of third electrical contacts each extending from one of the one or more lead patterns. The sensor chip is mounted to the liquid crystal lens such that each of the third electrical contacts is electrically connected to one of the plurality of second electrical contacts.

Abstract: An optical power meter including a mechanical interface that establishes a predetermined air gap, while avoiding physical contact with the sensitive area of the DUT. The mechanical interface is formed such that the test instrument contacts the DUT in the non-sensitive region over an area large enough to establish contact pressure that is well within the strength of the DUT's material. Accordingly, the non-contacting optical element enables optical power to be collected and relayed with a quantifiable and repeatable power loss. A high-NA, large area optical element is used to collect and relay optical power accurately while maintaining low sensitivity to axial or radial alignment.

Abstract: An apparatus for monitoring deposition rate, an apparatus including the same, for depositing an organic layer, a method of monitoring deposition rate, and a method of manufacturing an organic light emitting display apparatus using the same, are provided. The deposition rate monitoring apparatus for measuring deposition rate of a deposition material discharged from a deposition source, includes: a light source for irradiating light having a wavelength within a photoexcitation bandwidth of the deposition material; a first optical system for irradiating the light emitted from the light source toward the discharged deposition material; a second optical system for collecting the light emitted from the deposition material; and a first light sensor for detecting the amount of the light which is emitted from the deposition material and collected in the second optical system.

Abstract: A measuring apparatus and a measuring method are provided. The measuring apparatus includes an optical system to condense light, a light receiving device to receive light condensed by the optical system at a plurality of light receiving positions and convert the light into an electric signal, a plurality of optical band-pass filters arranged near a lens stop of the optical system, each of the optical band-pass filters having a different spectral transmittance, a lens array arranged between the optical system and the light receiving device, the lens array having a plurality of lenses each of which is arranged substantially in parallel with a two-dimensional surface of the light receiving device, and a correction unit to correct the electric signal for each one of the plurality of light receiving positions of the light receiving device. The measuring method is performed by the measuring apparatus.

Abstract: The resolution of conventional imaging devices is restricted by the diffraction limit ‘Perfect’ imaging devices which can achieve a resolution beyond the diffraction limit have been considered impossible to implement. However, the present disclosure provides an imaging device which can achieve improved resolution beyond the diffraction limit and which can be implemented in practice. Said imaging device comprises: a. a lens having a refractive index that varies according to a predetermined refractive index profile; b. a source; c. an outlet for decoupling waves from the device; and d. a reflector provided around the lens, the source and the outlet, wherein the reflector and the refractive index profile of the lens are together arranged to direct waves transmitted in any of a plurality of directions from the source to the outlet.

Abstract: In exemplary implementations of this invention, a camera can capture multiple millions of frames per second, such that each frame is 2D image, rather than a streak. A light source in the camera emits ultrashort pulses of light to illuminate a scene. Scattered light from the scene returns to the camera. This incoming light strikes a photocathode, which emits electrons, which are detected by a set of phosphor blocks, which emit light, which is detected by a light sensor. Voltage is applied to plates to create an electric field that deflects the electrons. The voltage varies in a temporal “stepladder” pattern, deflecting the electrons by different amounts, such that the electrons hit different phosphor blocks at different times during the sequence. Each phosphor block (together with the light sensor) captures a separate frame in the sequence. A mask may be used to increase resolution.

Abstract: A method for determining the position of an object, includes: respectively detecting a light beam of a light emitting module emitted from a reference point and respectively reflected and retro-reflected by a stripped L-shaped reflecting mirror and retroreflector to obtain a first signal and a second signal; processing the first signal and the second signal to obtain a plurality of included angles A1 and a plurality of included angles A2 formed by respectively intercepting the light beam emitted from the reference point and blocked directly or indirectly by the object with the first reflecting unit and second unit; and respectively combining the plurality of included angles A1 with each included angle A2, respectively converting the combinations to obtain a plurality of coordinates, and selecting at least two coordinates with the same value among the plurality of coordinates, thereby confirming a relative coordinate of the objects on a work area.

Abstract: The present invention relates to various improvements relating to automatic vehicle equipment control systems.

Abstract: The opto-electronic module comprises a substrate member (P); at least one emission member (E1; E2) mounted on said substrate (P); at least one detecting member (D) mounted on said substrate (P); at least one optics member (O) comprising at least one passive optical component (L); at least one spacer member (S) arranged between said substrate member (P) and said optics member (O). The opto-electronic modules can be very small and can be produced in high quality in high volumes. In particular, at least two emission members (E1, E2), e.g., two LEDs, are provided, for emitting light of variable color. This can improve illumination of a scene.

Abstract: A photoelectric conversion module includes: a substrate having a wiring layer and a through hole; a photoelectric conversion element having a light emitting unit or light receiving unit and mounted on the substrate such that the light emitting unit or light receiving unit faces the through hole; a protruding portion that has a hole portion communicating with the through hole, and protrudes from one of principal surfaces of one of the substrate and the photoelectric conversion element, one of the principal surfaces facing the other one of the substrate and the photoelectric conversion element; and an adhesive that is filled in a part of a region between the substrate and the photoelectric conversion element, the region being a region outside an inner peripheral surface of the hole portion, and that bonds the substrate to the photoelectric conversion element.

Abstract: A flow cytometry system includes a flow element through which a cell is transported in a flowing fluid. The flow element includes a bore bounded by a wall. A light source is configured to illuminate the cell. An optical system receives light emanating from the cell and directs at least some of the received light to a light sensor. The optical system includes a numerical-aperture-increasing lens at a wall of the flow element. At least some of the received light passes through the numerical-aperture-increasing lens. The flow cytometry system may also include a beam splitter that directs two wavelength bands of the emanating light such that light in two wavelength band preferentially reach different sensing locations via different paths. The system may also include an optical element placed in one of the paths, shifting a focal location of the affected path to compensate for chromatic aberration of the numerical-aperture-increasing lens.

Abstract: A method and system for generating an image utilizing entangled quantum particle pairs comprising at least one processor; at least one source of entangled quantum particles having first and second channels, the first and second channel s outputting first and second pairs of entangled quantum particles, respectively, a first beam splitter operatively connected to the first channel; the first beam splitter configured to split the first pairs of entangled particles for entry into first and second spatial detectors; at least one focusing device operatively connected to the second channel configured to direct the second pairs of entangled quantum particles towards a distant target; each of the first and second spatial detectors detecting one particle of the first pairs of entangled quantum particles; the at least one processor operating to record the detection of entangled quantum particles by the first and second spatial detectors and create image data for display

Abstract: A test apparatus includes a biopsy needle for sampling a biopsy specimen. The biopsy needle includes a specimen holder that holds the sampled biopsy specimen, and an optical window disposed in the specimen holder and configured to allow optical detection. A biopsy specimen held by the specimen holder of the test apparatus is measured by using a third-order nonlinear Raman microscope.

Abstract: A sensor device for detecting moisture on a windscreen has a transmitter and a receiver and optics arranged between the transmitter and the receiver. The optics have an upper plane for connection to a windscreen, a decoupling region serving to decouple the electromagnetic rays from the optics into the windscreen, and a coupling region serving to couple the electromagnetic radiation from the windscreen into the optics, and which even for a small construction shall supply a usable signal. The decoupling region has at least one surface inclined relative to the upper plane of the optics.

Abstract: An optical sensor includes: first and second light receiving elements on a semiconductor substrate; a light blocking film over the semiconductor substrate via a light transmitting film; and first and second openings corresponding to the light receiving elements and disposed in the light blocking film. First and second virtual lines are defined to extend from the centers of the first and second light receiving elements and pass through the centers of the first and second openings, respectively. At least one of elevation angles and left-right angles of the first and second virtual lines are different. The photosensitive area of the first light receiving element is larger than the aperture area of the first opening. The photosensitive area of the second light receiving element is larger than the aperture area of the second opening.

Abstract: A light transmitting optical fiber shines light at a side edge portion of a hemispherical lens. The light is transmitted along the periphery of the lens to a second side edge portion located opposite the first side edge portion. A light sensitive component detects light at the second edge portion which light resulted from the light transmitted at the first side edge portion. The intensity of light detected at the second side edge portion is indicative of the fluid to which the lens is exposed, and can be evaluated and signaled by a microprocessor.

Abstract: A projection optical system that is used for an image display device having an image display element, includes a refractive optical system that includes a plurality of lenses; an aperture that limits a quantity of light led to the refractive optical system from the image display element; a lens group that is arranged between the image display element and the aperture, has a positive refractive power, and has low field curvature with respect to the image display element; and a mirror optical system that has a concave mirror arranged on an opposite side from the image display element across the refractive optical system, the aperture, and the lens group.

Abstract: An image displaying apparatus including a light source, a light condenser for condensing light to form a condensed light image, a light mixing element, a reflective image displaying element having plural micro-mirrors for changing an inclination angle of an individual micro-mirror between an on-state and an off-state, an illumination optical system including a condenser lens and a mirror for illumination, and a projection optical system for projecting reflected light from a micro-mirror being at an on-state among plural micro-mirrors constituting the reflective image displaying element, wherein the mirror for illumination is at a position nearest the reflective image displaying element on an optical path from the light mixing element to the reflective image displaying element and a reflection surface of this mirror for illumination is positioned at a side of the reflective image displaying element with respect to a projection lens system constituting a part of the projection optical system.

Abstract: An electro-optical (EO) radiation collector for collecting and/or transmitting EO radiation (which may include EO radiation in the visible wavelengths) for transmission to an EO sensor. The EO radiation collector may be used with an arc flash detection device or other protective system, such as an intelligent electronic device (IED). The arc flash detection device may detect an arc flash event based upon EO radiation collected by and/or transmitted from the EO radiation collector. The EO radiation collector may receive an EO conductor cable, an end of which may be configured to receive EO radiation. A portion of the EO radiation received by the EO radiation collector may be transmitted into the EO conductor cable and transmitted to the arc flash detection device. The EO radiation collector may be adapted to receive a second EO conductor cable, which may be used to provide redundant EO transmission and/or self-test capabilities.

Abstract: The invention relates to a reflector used in a reflex mode detection device, said reflector being intended to be positioned in alignment with a detector and comprising a reflective region (Z) for reflecting a light beam (F1) so as to send it back towards the detector (1). The reflector (2) is arranged to fulfil: a signalling function using a signalling interface (20), said signalling interface (20) being arranged to indicate a state of alignment of the reflective region (Z) of the reflector (2) with respect to the emitter, a detection function so as to detect the presence of the light beam against the reflector, an interpretation function using an interpretation unit (22), said interpretation unit (22) being arranged to operate on the signalling interface with the aim of indicating the state of alignment, a power supply function with autonomous electric power, so as to supply electric power to the signalling interface (20) and the interpretation unit (22).

Abstract: Fluorescing gel formulations are disclosed for monitoring cleaning of a surface. The fluorescing gel formulations are stable, fluoresce under UV light, and do not leave a mark after drying and removal. The compositions include an oppositely charged complexing agent which is used in combination with an anionic or cationic optical brightener. In some embodiments, the compositions include a cationic optical brightener with no complexing agent.

Abstract: A nonlinear optical microscope is provided, including source of a pulsed laser beam; a spatial light modulator for modulating the spatial profile of the pulsed laser beam; an objective for guiding the modulated beam towards a slide intended to carry a specimen; and a detector for collecting signals originating from the specimen, wherein the spatial light modulator is designed to modulate the intensity and/or the phase of the pulsed laser beam on the rear pupil of the objective to produce a beam that is axially extended and confined in one or two lateral directions after focusing by the objective, and wherein the slide is placed on a motorized stage of a histology slide scanner assembly.

Abstract: An extended depth of field three-dimensional nano-resolution imaging method includes: creating an optical module with a double helix point spread function and multi-stage imaging properties of a defocus optical grating; obtaining double helix image of a molecule by imaging a molecule using the optical module; determining a lateral position of the molecule according to a position of a midpoint of double helix sidelobes on the imaging plane in the double helix image; determining an axial position of the molecule according to a rotation angle of a line of centers of the double helix sidelobes on the imaging plane and the position of the midpoint of the double helix sidelobes on the imaging plane in the double helix image. The double helix point spread function and the defocus optical grating multi-stage imaging are combined to implement three-dimensional imaging to extended the depth of field and to improve the resolution.

Abstract: An optical element for condensing light is provided, wherein the optical element has a first cylindrical face and a second cylindrical face at one side and a third cylindrical face at an other side and a plane including an axis of the first cylindrical face and an axis of the third cylindrical face intersects with a plane including an axis of the second cylindrical face and the axis of the third cylindrical face. A light detection device for detecting light is provided, wherein the light detection device includes the optical element as described above and an element for detecting light condensed by the optical element.

Abstract: The present invention relates to devices and methods for spectrometric analysis of light-emitting samples. The device comprises a particle beam source, which generates a primary particle beam directed to the sample in such a way that the primary particle beam is incident on the sample and photons are released from the sample due to the interaction between primary particle beam and sample material. Moreover, the device comprises a plurality of light-pickup elements, which are suitable for capturing the photons released from the sample, wherein the light-pickup elements capture the photons emitted in the respectively assigned solid-angle range. Furthermore, the device comprises conduction elements, which are embodied to forward captured photons to an evaluation unit, and an analysis system, which comprises a plurality of evaluation units in such a way that photons captured by each light-pickup element are analyzed spectrally.

Abstract: The present disclosure relates to microfluidic devices adapted for facilitating cytometry analysis of particles flowing therethrough. In certain embodiments, the microfluidic devices allow light collection from multiple directions. In certain other embodiments, the microfluidic devices use spatial intensity modulation. In certain other embodiments, the microfluidic devices have magnetic field separators. In certain other embodiments, the microfluidic devices have the ability to stack. In certain other embodiments, the microfluidic devices have 3-D hydrodynamic focusing to align sperm cells. In certain other embodiments, the microfluidic devices have acoustic energy couplers. In certain other embodiments, the microfluidic devices have phase variation producing lenses. In certain other embodiments, the microfluidic devices have transmissive and reflective lenses. In certain other embodiments, the microfluidic devices have integrally-formed optics.

Abstract: An optical-electric converting module includes a printed circuit board (PCB) and an optical-electric coupling element. The PCB includes a supporting surface, at least one laser diode, and at least one photo diode. The at least one laser diode and the at least one photo diode are positioned on the supporting surface and electrically connected to the PCB. The supporting surface defines at least one locating hole. The optical-electric coupling element includes a lower surface facing the supporting surface. The optical-electric coupling element defines a first cavity in the lower surface. The optical-electric coupling element includes at least one locating pole extending from the lower surface. The optical-electric coupling element is detachably connected to the supporting surface through the engagement of the at least one locating pole and the least one first locating hole, with each laser diode and each photo diode being received in the first cavity.

Abstract: A radiometer includes a substrate; a radiation absorber disposed on the substrate to absorb radiation; a thermal member disposed on the substrate to change electrical resistance in response to a change in temperature of the radiometer; and a thermal link to connect the radiometer to a thermal reference, wherein the radiation absorber, the thermal member, or a combination comprising at least one of the foregoing includes a plurality of carbon nanotubes, the carbon nanotubes being mutually aligned with respect to the substrate, and the radiometer being configured to detect optical power.

Abstract: An optical sensor arrangement for measuring an observable including at least one light source for generating a first light component of a first frequency including a first mode and a second light component of a second frequency including a second mode orthogonal to the first mode, an optical resonator having differing optical lengths for the first and second modes, at least one of the optical lengths being variable depending on the observable and a dependence of the respective optical length being different for the first and second modes, and a detector unit coupled to the optical resonator for coupling out the two light components and being configured for detecting a frequency difference between a resonance frequency of the optical resonator for the first mode and a resonance frequency of the optical resonator for the second mode.

Abstract: A soil tester is disclosed, and comprises a housing and a sampling apparatus. The housing includes an interior sampling chamber configured to receive a sample container. The sampling apparatus comprises a photodetector and a light source. The photodetector is mounted along a portion of the interior sampling chamber and has a variable resistance determined by a property of incident light. The light source is mounted to the interior sampling chamber in a transmissive orientation relative to the photodetector so that a beam of light can be transmitted from the light source to the photodetector through the interior sampling chamber. A display on the housing is responsive to the photodetector.

Abstract: A lens sheet is provided which is configured to create, below the lens sheet, a region not irradiated with light when light is incident on the lens sheet from above. A photoelectric conversion element is efficiently irradiated with light incident on the lens sheet. In addition, a high-efficiency photoelectric conversion module is provided. The lens sheet includes a light-transmitting substrate having lens arrays on both sides, and the lens arrays each have lens regions and non-lens regions placed alternately (in stripes), in which an end portion of each lens region on the front side overlaps with an end portion of each lens region on the back side.

Abstract: A two-dimensional solid-state image pickup device includes a plurality of pixel regions arranged in a two-dimensional matrix in X and Y directions. Each of the pixel regions includes at least a light-receiving element, and a light-condensing element. The light-condensing element is a sub-wavelength lens including protrusions each having a size equivalent to or smaller than a wavelength of an electromagnetic wave incident on the light-receiving element. Each of the protrusions has a rounded edge.

Abstract: A method and apparatus for three dimensional fluorescent analysis of a target in a liquid sample having fluorescent analyte as a target substance or fluorescent label on the target substance. A rotating carousel carries liquid samples beneath a beam having a beam spot at a horizontal plane of the sample. The carousel advances slowly a linear direction during rotation so that a pattern of overlapping spiral scans provide R-theta two-dimensional samples of the entire plane to identify locations of volumes of interest where fluorescence is measurably higher than background. These locations are probed in the depthwise direction to find locations of fluorescent analyte in three dimensions. Light from the analyte or fluorescent label is detected and processed to characterize the target by color, size or other morphology.