Abstract: A photoelectric coupling module includes a substrate, a photoelectric unit, and a lens module. The substrate carries at least two alignment marks for correct and absolute positioning of the lens module on the substrate. The photoelectric unit is positioned on the substrate. The lens module defines at least two through holes aligned with the alignment marks.

Abstract: A photoelectric coupling module includes a substrate, a photoelectric unit, and a lens module. The substrate defines a positioning recess. The photoelectric unit is positioned on the substrate. The lens module includes a reflection surface, a plurality of first lenses, and a plurality of second lens. Optical axes of the first lenses cross optical axes of the second lenses on the reflection surface. The lens module further includes a positioning portion extending downward from a bottom surface, and the positioning portion is received in the positioning recess. The first lenses are aligned with the photoelectric unit.

Abstract: The illumination apparatus includes a light collector directing light from a light source, radially inward further than the light source, and a light guider provided radially inside further than the light source so as to circumferentially extend and guiding the light from the light source toward an area extending to a side away from the light source and causing the light from the light source to exit toward a light projecting direction. The light collector includes two reflective surfaces on a light projecting direction side and on an opposite side thereto in the thickness direction, and a light exiting opening between the two reflective surfaces. In a sectional plane along the thickness direction, a direction of a center of a light exit range from the light collector tilts to the opposite side to the light projecting direction side.

Abstract: An apparatus includes an image sensor having N image sensor regions arranged thereon. A lens array having a including N lens structures is disposed proximate to the image sensor. Each one of the N lens structures is arranged to focus a single image onto a respective one of the N image sensor regions. The N lens structures include a first lens structure having a first focal length and positioned the first focal length away from the respective one of the N image sensor regions. A second lens structure having a second focal length is positioned the second focal length away from the respective one of the N image sensor regions. A third lens structure having a third focal length is positioned the third focal length away from the respective one of the N image sensor regions. The first, second and third focal lengths are different.

Abstract: This focus sensor is readily usable in a system using pupil obscuration to measure the state of focus of a light beam. A scattering volumetric filter modifies a three-dimensional wavefront so that focus can be detected by a two-dimensional detector for conversion to a one-dimensional signal having values of plus, zero and minus. This diffusing filter comprises sub wavelength particles having a high index of refraction suspended in an adhesive to produce a solid diffuser. This focus sensor enables a well-behaved focus curve having a constant slope near best focus, while maintaining a slope that is either constant or monotonic at a minimal rate over an extended distance to support a long capture-range over which a focus-controlling servo-mechanism can acquire and maintain focus in the presence of corrupting target surface topography or optical defects.

Abstract: An optical proximity sensor is provided that comprises an infrared light emitter an infrared light detector, a first molded optically transmissive infrared light pass component disposed over and covering the light emitter and a second molded optically transmissive infrared light pass component disposed over and covering the light detector. Located in-between the light emitter and the first molded optically transmissive infrared light pass component, and the light detector and the second molded optically transmissive infrared light pass component is a substantially optically non-transmissive infrared light barrier component. The infrared light barrier component substantially attenuates or blocks the transmission of undesired direct, scattered or reflected light between the light emitter and the light detector, and thereby minimizes optical crosstalk and interference between the light emitter and the light detector.

Abstract: A fluorescence spectrophotometer according to the present invention includes: a light source 1; a sample cell 3; an excitation-side light-dispersing system 2 for dispersing a light from the light source 1 and for casting a desired wavelength of light into the sample cell 3; an emission-side light-dispersing system 4 for dispersing a light emitted from the sample cell 3, the emission-side light-dispersing system 4 being located off an optical path of a transmitted light exiting from the sample cell 3 after being cast from the excitation-side light-dispersing system 2 into the sample cell 3; and a photodetector 5 capable of detecting, among the light from the emission-side light-dispersing system 4, an emission light having the same wavelength as the light cast from the excitation-side light-dispersing system 2 into the sample cell 3.

Abstract: A light scattering type smoke sensor includes a sensor body, light-emitter for emitting light toward an open smoke-sensing space and outputting a light-received signal according to the amount of scattering light received, and a fire judging unit for judging whether fire occurs or not on the basis of the amount of received light determined on the basis of the outputted light-received signal.

Abstract: Capacitance between a detection capacitor and a reset transistor is the largest among the capacitances between the detection capacitor and transistors placed around the detection capacitor. In order to reduce this capacitance, it is effective to reduce the channel width of the reset transistor. It is possible to reduce the effective channel width by distributing, in the vicinity of the channel of the reset transistor and the boundary line between an active region and an element isolation region, ions which enhance the generation of carriers of an opposite polarity to the channel.

Abstract: An apparatus for detecting small field circular collimators when connected to a linear accelerator machine (LINAC). Each small field circular collimator is provided with some uniquely identifying trait depending upon its size. The adaptor of LINAC includes sensors to detect the uniquely identifying trait of the small field circular collimator. The information from the sensor about the small field circular collimator is conveyed to the LINAC to verify that the collimator is properly installed and the correct size collimator is being used.

Abstract: The present invention relates to a reflective mask blank containing in this order, a substrate, a multilayer reflective film that reflects exposure light, and an absorber layer that absorbs the exposure light, in which the reflective mask blank further contains a fiducial mark indicating a reference position of the multilayer reflective film, which is formed in a concave shape or in a convex shape on a surface of the multilayer reflective film or on a surface of one layer formed between the multilayer reflective film and the absorber layer, and the fiducial mark is formed so as to have a reflectivity different from an area surrounding the fiducial mark with respect to a light with a prescribed wavelength and is transferred to a layer formed on the fiducial mark.

Abstract: This technique provides a display device including an optical unit that is located at a lower section of a housing accommodating a display panel. The optical unit has a unit main body that includes a plurality of light guide members integrally provided at a base, and a case accommodating the unit main body. The light guide members of the unit main body include a receiving light guide member that has an incident surface exposed to a front surface of the housing, an emitting surface for emitting light to a light receiving sensor, and a reflective surface provided between the incident surface and the emitting surface, and an emitting light guide member for guiding light from a light emitting diode to the front surface of the housing.

Abstract: An electronic device is provided with a display and a light sensor that receives light that passes through the display. The display includes features that increase the amount of light that passes through the display. The features may be translucency enhancement features that allow light to pass directly through the display onto a light sensor mounted behind the display or may include a light-guiding layer that guides light through the display onto a light sensor mounted along an edge of the display. The translucency enhancement features may be formed in a reflector layer or an electrode layer for the display. The translucency enhancement features may include microperforations in a reflector layer of the display, a light-filtering reflector layer of the display, or a reflector layer of the display that passes a portion of the light and reflects an additional portion of the light.

Abstract: A photoelectric conversion device includes a circuit board, light emitting modules, light receiving modules, and an optical coupling lens. The light emitting modules and the light receiving modules are mounted on the circuit board. The optical coupling lens is mounted on the circuit board and includes a first mounting surface. The first mounting surface defines a first recess at a central portion thereof and four receiving grooves at four peripheral edges thereof apart from the first recess. The receiving grooves are exposed to the peripheral edges of the first mounting surface.

Abstract: Described is a portable dosimeter reader that is small in size and light in weight.

Abstract: A pattern method is provided for testing an optical lens. The method provides a lens for test, including a first lens surface with a focal plane in object space and a second lens surface with a focal plane in image space. Also provided is a pattern test fixture including an imaging device and a target pattern. The lens is positioned so that the imaging device is located outside the object space focal plane and the target pattern located is outside the image space focal plane. The imaging device, such as a microscope, magnification device, human eye, or camera, is used to view the target pattern. A viewed image representation of the target pattern is received in the imaging device and compared to the target pattern. More typically, the viewed image representation is compared to a target pattern copy.

Abstract: A production method of a solid-state imaging device in which microlenses are arranged adjacent to each other on a substrate, includes: a first process of forming first microlenses on a surface of the substrate leaving space therebetween for providing second microlenses; and a second process of applying an overcoating material onto the surface of the substrate on which the first microlenses are formed, drying the overcoating material, exposing the overcoating material to light using a gray scale mask, and developing the exposed overcoating material, so as to form second microlenses in the space between the first microlenses adjacent to each other.

Abstract: An electrochromic device (ECD) includes an electrochromic cell and, optionally, one or more additional electrochromic cells where all cells are parallel, and where at least one of the electrodes of one of the cells comprises a single-walled carbon nanotube (SWNT) film The electrochromic cells allow the control of transmittance of two or more different portions of the electro-magnetic spectrum through the ECD. One cell can control the transmittance of visible radiation while the other cell can control the transmittance of IR radiation. The ECD can be employed as a “smart window” to control the heat and light transmission through the window. The ECD can be in the form of a laminate that can be added to an existing window.

Abstract: Techniques for producing an arbitrary broadband waveform include storing a first waveform in a circulating coherent storage device. A next waveform is generated. A shifted replica is generated by shifting, by a frequency shift one of the next waveform or the waveform in the storage device. A combined waveform is stored by coherently combining the shifted replica and one of the next waveform or the waveform in the storage device which waveform is not frequency shifted. An apparatus includes a source of a carrier frequency waveform, and a modulator configured to impose the next waveform on the carrier frequency waveform. The apparatus also includes a circulating coherent storage device configured to store a coherent interaction between multiple waveforms. The apparatus also includes a frequency shifter configured to generate a shifted replica by shifting, by a frequency shift, one of the next waveform or a waveform in the storage device.

Abstract: A disclosed system includes a light source and a nonlinear converter optically coupled to and remote from the light source. The nonlinear light converter converts a light pulse received from the light source to a broadened or spectrum-shifted light pulse. The system also includes a sensor in situ with the nonlinear light converter. The sensor performs a sense operation based on the broadened or spectrum-shifted light pulse and generates an electrical signal corresponding to the sense operation. The system also includes an electro-optical interface in situ with the sensor that transforms the electrical signal to an optical signal for conveyance to a signal collection interface A related method includes generating a light pulse and conveying the light pulse to a remote nonlinear light converter. The method also includes converting the light pulse to a broadened or spectrum-shifted light pulse.

Abstract: Various embodiments provide a sensor system including a first optical sub-system having a first plurality of optical elements, and a second optical sub-system having a second plurality of optical elements including a first mirror. The second optical sub-system is configured to rotate about a first axis relative to the first optical sub-system and the first mirror is configured to rotate about a second axis substantially perpendicular to the first axis. The first axis and the second axis are arranged so as not to intersect each other so as to maximize a field of regard of the sensor system.

Abstract: A titanium black dispersion includes titanium black particles, a dispersant, and an organic solvent. When the titanium black dispersion is for a wafer level lens, 90% or more of dispersed objects that consist of the titanium black particles have particle diameters of 30 nm or less, or dispersed objects including the titanium black particles contains Si atoms and the content ratio of Si atoms to Ti atoms (Si/Ti) in the dispersed objects is 0.05 or higher. When the titanium black dispersion is used for formation of a light-shielding film that is provided on one side of a silicon substrate having an image pickup device section on the other side, and that shields against infrared light, 90% or more of dispersed objects that consist of the titanium black particles have particle diameters of 30 nm or less.

Abstract: Device to adjust the position and/or size of a pinhole in a laser scanning microscope (LSM) where the pinhole is illuminated via a separate light source or the LSM laser and the pinhole is moved at a right angle to the optical axis until the receiver has the maximum intensity and the pinhole position is captured and saved together with the data attributed to the replaceable optical components.

Abstract: An optical device includes: a substrate having a dielectric layer and a plurality of metal particles; and an organic molecular layer formed by self-assembly on at least either the surface of the dielectric layer or the surfaces of the metal particles. In the organic molecular layer, a first organic molecule and a second organic molecule are alternately arranged in a first direction, and the chain length of an organic group of the first organic molecule and the chain length of an organic group of the second organic molecule are different from each other.

Abstract: An optoelectronic apparatus includes an optical device with an optical structure including a plurality of optical elements and a concentrator which is a hollow body having a reflective inner area, and a radiation-emitting or radiation-receiving semiconductor chip with a contact structure including a plurality of contact elements that make electrical contact with the semiconductor chip and are spaced apart vertically from the optical structure, wherein the contact elements are arranged in interspaces between the optical elements upon projection of the contact structure into a plane of the optical structure, wherein the concentrator has an aperture on a side facing the semiconductor chip that is smaller than a side facing away from the semiconductor chip, and the optical structure is arranged on a side of the concentrator facing the semiconductor chip.

Abstract: Removable and/or detachable viewing devices for optical and/or other measuring equipment and methods of making and using the same are disclosed. The viewing device includes a housing, an eyepiece, and an attachment mechanism configured to releasably or detachably connect the viewing device to an optical measuring instrument. An optical measuring system includes an optical measuring instrument and the viewing device detachably connectable to the optical measuring instrument. The optical measuring kit may include one or more caps or plugs detachably connectable to the opening of the optical measuring instrument and/or the interface end of the viewing device.

Abstract: Methods, systems and apparatuses for rotational viewing systems for optical and/or other measuring equipment are disclosed. The rotational viewing device includes a housing having an interface end opposite a viewing end. The housing has one or more bends between the interface end and the viewing end, an internal mirror, and one or more rotatable joints or connections allowing at least part of the housing to be rotated in a plane parallel or orthogonal to an optical axis of an apparatus to which the viewing device interfaces at the interface end. The rotational viewing device also includes an eyepiece, located at or near the viewing end.

Abstract: There is provided a microparticle analysis apparatus including a light irradiation unit, which includes a plurality of light sources that emit laser light beams having different wavelengths, and which is configured to irradiate, with the laser light, microparticles flowing through a channel, and a light source drive control unit configured to control light emission by each light source in the light irradiation unit. The light source drive control unit is configured to supply a first current to each light source, and to supply in a time-division manner a second current to each light source while the first current is being supplied.

Abstract: A narrow-linewidth, variable-wavelength, active, absorbing LIDAR (Light Detection and Ranging) system and method. The linewidth of the source and detector is sufficiently narrow to produce a reasonable signal-to-noise ratio for the system. The central wavelength of the source and detector can be synchronously changed. The system comprises a tunable light-emitting source and uses the absorption of light to determine the chemical composition of the item being detected. A wavelength tunable filter synchronized to the tunable source reduces or eliminates background noise and thus increases the level of detection for low concentrations of the substance to be detected.

Abstract: An optical operating element comprises a light-emitting transmitter, an optical receiver, a prism, and a cover. The prism has a side surface that is an active sensor area, and the prism is arranged below the cover such that the active sensor area is oriented substantially parallel to the underside of the cover. The cover has a sensor region which is above the active sensor area and which has a transmittance of at most 99%, at most 95%, at most 90%, at most 80% or at most 50%. Light emitted by the transmitter is guided through the prism and passes through the active sensor area and the cover. The emitted light reflected at an object enters through the sensor region and the active sensor area and is guided through the prism to the receiver. A change in reflection is identified by an evaluation circuit and is interpreted as switching.

Abstract: An off-axis telescope having a primary optical element configured to reflect an energy beam from an optical reference source that emits the energy beam along an optical path. The telescope includes angle sensors arranged on a periphery of the primary optical element to determine angular motion of the energy beam from the optical reference source. The angle sensors are operable to be biased to positional settings associated with a desired pointing direction of the energy beam. A secondary optical element is arranged in the optical path and translated along three orthogonal axes. A plurality of steering mirrors arranged between the optical reference source and the secondary optical element is configured to be tilted in response to a control signal. A controller auto-aligns the telescope by at least translating the secondary optical element and tilting the steering mirrors via the control signal using at least inputs from the plurality of angle sensors.

Abstract: Various aspects of the subject technology provide systems and methods for transmitting a radio frequency (RF) signal from a desired location on the surface of a photoconversion material by simply directing a laser beam or other energy beam to the desired location on the photoconversion material. In one aspect, the laser beam causes electrons in the photoconversion material to accelerate and emit the RF signal by forming a dead region on the photoconversion material that the electrons must flow around. In one aspect, the dead region has an asymmetrical shape to prevent a cancellation effect and produce a net positive RF signal. Various aspects of the subject technology also provide systems and methods for drawing a circuit element on the photoconversion material by tracing one or more dead regions on the photoconversion material with a laser beam or other energy beam to construct the circuit element.

Abstract: A discrete wavefront measurement device uses a variable transmission filter (VTF) to decouple the dynamic range of tilt angle measurements in the wavefront from the spatial sampling resolution and the measurement sensitivity as regards the physics of the readout. This approach allows the discrete wavefront measurement device to be configured to a specified dynamic range, transverse sampling resolution and measurement sensitivity at low cost.

Abstract: A biosensor includes light emitting elements and a light receiving element disposed on a principal surface of a wiring board; a light shielding portion disposed between a light-emitting-element sealing portion and a light-receiving-element sealing portion; a base medium having light transmitting properties, disposed in parallel with the wiring board with the light shielding portion therebetween; an adhesion layer having light transmitting properties, configured to bond the base medium with the light-emitting-element sealing portion, the light-receiving-element sealing portion, and the light shielding portion; and a first electrocardiograph electrode attached to a principal surface of the base medium. The refractive index of the base medium is set to be higher than that of the adhesion layer, and a surface of the first electrocardiograph electrode which is adjacent to the base medium is roughened so that stray light passing through the base medium will be scattered.

Abstract: The present disclosure relates to paper-based substrates and apparatus comprising such substrates. The apparatus may include a patterned conductive structure coupled to the paper-based substrate, wherein the patterned conductive structure responds to electromagnetic radiation.

Abstract: An optical communication module includes a lens unit and an optical-electrical converter. The optical-electrical converter includes a circuit board and the lens unit is fixed on the circuit board. The lens unit has an extension portion, and the extension portion extends outwards from the lens unit and is parallel to the circuit board. Glue is located between the extension portion and the circuit board to secure the lens unit on the circuit board.

Abstract: A semiconductor module including a semiconductor chip having a light receiving device formed at a front thereof and a light permeable cover having a front, a back, and a side. The light permeable cover is disposed opposite to the front of the semiconductor chip such that the front of the semiconductor chip is covered by the back of the light permeable cover. The light permeable cover is provided at the outer circumferential region of the front thereof and at the side thereof with a light shielding layer. It is possible to prevent the incidence of unnecessary light from the side of the light permeable cover of a CSP and to easily adjust the distance between a lens and the front of the semiconductor chip within tolerance.

Abstract: A photoelectric conversion device includes a circuit board, a light emitting module, a light receiving module, and an optical coupling lens. Two protrusions apart from each other extend from the circuit board. The light emitting module and the light receiving module are mounted on the circuit board and apart from each other. The optical coupling lens includes an oblique reflection surface and a recess having a bottom surface parallel to the circuit board. Two distanced posts perpendicularly extend from the bottom surface and engage with the centers of the protrusions upon assembly to ensure automatic and alignment of the light emitting module with the first converging lens, and alignment of the light receiving module with the second converging lens.

Abstract: A fluorescent material may include a medium, carbon nanotubes dispersed in the medium, and a fluorescent surfactant. The fluorescent surfactant may be adsorbed to a surface of some of the carbon nanotubes in a concentration sufficient to make the material fluoresce in the presence of radiation. The material may be applied to a material and tested for fluorescence, electrical conductivity, or carbon nanotube structure.

Abstract: A light harvesting system employing a focusing array and a photoresponsive layer in which a plurality of microstructured areas is formed. Light received by the focusing array is injected transmissively into the photoresponsive layer through the microstructured areas. The injected light is retained in the photoresponsive layer by at least a total internal reflection and is propagated within the layer until it is substantially absorbed.

Abstract: An energy output measuring device including a main body having a light reflecting exterior and a window portion formed in the main body and produced from infrared-reflecting glass. At least one visible light sensor is disposed adjacent the window. The energy output measuring device is configured to pass through a heating device. An energy output of the heating device is determined from measurements taken by the heating device.

Abstract: An antenna system is disclosed. The system comprises a first end-fire antenna element and a second end-fire antenna element facing each other in a planar arrangement, the antenna elements being configured such as to cause destructive interference between individual end-fire radiations of the elements, while maintaining constructive interference generally perpendicular to the planar arrangement.

Abstract: The present invention relates to an optical receiver (1) for receiving alternating-light data signals and for storing electrical energy obtained from extraneous light, having a photodiode (2) for receiving light, which comprises extraneous light and an alternating-light data signal component with a higher frequency in comparison to the extraneous light, and for converting the light into a photocurrent (IP) which comprises a data signal current (IN) and an extraneous light current (IF) said receiver additionally comprises a coupling unit (3) for coupling in and separating the data signal current generated by the optical alternating-light data signal component from the extraneous light current generated by the extraneous light, an amplifying unit (4) for amplifying the data signal current and an energy storage unit (5) which is charged by the extraneous light current (IF) and which includes a circuit for increasing voltage, wherein the energy charged in the energy storage unit (5) is used for at least partially

Abstract: A detecting apparatus for determining whether liquid crystal glasses are displaced in a cartridge is disclosed. The detecting apparatus includes: a signal sensing device for sending sensing signals to an internal of the cartridge and for receiving the reflected signals from the internal of the cartridge; a reflector installed in the internal of the cartridge for receiving the sensing signals from the signal sensing device and for reflecting the sensing signals back to the signal sensing device; and wherein a determination of whether the liquid crystal glass is displaced in the cartridge is made by determining whether the reflected signals from the reflector are received after the sensing signals are sent. Upon determining whether liquid crystal glasses are displaced in the cartridge, impurities are prevented from getting into the cartridge and thus the cleanliness is enhanced and the labor power is reduced.

Abstract: An optical biosensor, and a method of manufacturing the same, includes a first layer, a second layer stacked on the first layer, a first grating coupler within the first layer and the second layer, and a second grating coupler within the first layer. The first grating coupler is configured to couple a light pattern provided to a front side of the optical biosensor. The second grating coupler is configured to output the light pattern coupled by the first grating coupler to a photoelectric conversion element on a rear side of the optical biosensor.

Abstract: A measuring apparatus, comprising at least a first light source and a second light source for transmitting light; at least one light receiver for receiving light at least of a first received wavelength and a second received wavelength; at least one dispersing element for bending and/or refracting light; wherein the light transmitted by the light sources strikes the dispersing element and is so turned by the dispersing element that it strikes the light receiver. The first light source is arranged at a first angle relative to the dispersing element and the second light source at a second angle relative to the dispersing element, wherein the second angle differs from the first angle. The first angle is so embodied that the wavelength of the light turned by the dispersing element corresponds to the first received wavelength, and wherein the second angle is so embodied that the wavelength of the light turned by the dispersing element corresponds to the second received wavelength.

Abstract: An off-axial three-mirror system includes a primary mirror, a secondary mirror, a tertiary mirror, and an image sensor. The secondary mirror is located on a reflective optical path of the primary mirror. The tertiary mirror is located on a reflective optical path of the secondary mirror. The image sensor is located on a reflecting optical path of the tertiary mirror. The primary mirror and the tertiary mirror are formed as one piece. The surface type of both the primary mirror and the tertiary mirror is a freeform surface.

Abstract: An optical device has a deformable solid substrate, and a two dimensional array of metal particles which is carried by the substrate. The array provides a controlled separation between nearest-neighbour particles. Deformation of the substrate produces corresponding variation in the controlled separation such that the two dimensional array undergoes a transition between metallic and insulator surface reflectance.

Abstract: A scanning imaging device has a spot light projecting section 101 that irradiates a first spot light for excitation and two second spot lights for focus detection onto a flow channel of a substrate 4 and an imaging section 102 for picking up an image of light emitted from a target of detection in the flow channel as it is excited by the first spot light. One of the second spot lights is reflected at the top surface of the flow channel and the other of the second spot lights is reflected at the bottom surface of the flow channel and a focus position adjustment mechanism for adjusting the focus position of each of the first and second spot lights in the depth direction of the flow channel such that the quantity of deviation of the focus positions of the first and second spot lights in the depth direction of the flow channel as determined by comparing the intensities of the one and the other of the second reflected lights reflected at the flow channel.

Abstract: In an aspect, a method and device of inspecting an electromagnetic radiation sensing panel and a method of manufacturing an electromagnetic radiation detector are provided. The method includes generating converted electromagnetic radiation by irradiating incident electromagnetic radiation onto an electromagnetic radiation conversion layer, measuring the generated converted electromagnetic radiation and evaluating data regarding the converted electromagnetic radiation, generating converted electromagnetic radiation based on the data regarding the converted electromagnetic radiation, and irradiating the generated converted electromagnetic radiation onto an electromagnetic radiation sensing panel.