Abstract: A method and apparatus for monitoring MEMS-based optical switches and cross-connects. A plurality of partial reflectors are introduced into optical paths of the switch for reflecting light transmitted along the optical paths through a transparent substrate of the switch, without disturbing transmission of the light along the optical paths. The reflected light is transmitted through the substrate, which is preferably made of silicon and transparent to wavelengths of light used in DWDM systems. A photodetector array bonded to the underside of the substrate detects the light reflected by the plurality of partial reflectors through the substrate. The light detected by the photodetector array indicates the switching states and functionality of the switch, and can be processed by circuitry associated with the array.

Abstract: A CMOS image sensor performing an analog correlated double sampling is disclosed. The CMOS image sensor may include an image capture device for capturing an image for analog image signal from an object an analog-to-digital converter for converting the analog image signal to a digital value using a ramp signal. In such an arrangement the analog-to-digital converter may includes a chopper-type comparator receiving the analog image signal and the ramp signal and a capacitor for receiving a start voltage of the ramp signal and charging a voltage level corresponding the start voltage of the ramp signal in a reset mode and for receiving a down-ramping signal of the ramp signal in a count mode in order to remove an device offset voltage. The analog-to-digital converter may also include a ramp signal generator providing the ramp signal to the analog-to-digital converter.

Abstract: A ribbon-like sensor assembly is described wherein a length of an optical fiber embedded within a similar lengths of a prepreg tow. The fiber is “sandwiched” by two layers of the prepreg tow which are merged to form a single consolidated ribbon. The consolidated ribbon achieving a generally uniform distribution of composite filaments near the embedded fiber such that excess resin does not “pool” around the periphery of the embedded fiber.

Abstract: A photoelectric sensor is disclosed that comprises a sensor unit having a casing. The casing includes one surface having a first display and a second display. The first display is structured and arranged to display a threshold value that may be set by an operator of the photoelectric sensor. The second display is structured and arranged to display the actual conditions sensed by said photoelectric sensor. The sensor also includes a selection device for selecting different operational values to display on the second display. The selection device can include a mechanism disposed on the casing for changing the different operational values on the second display. The selection device can also include an adjustment switch disposed on the casing. The adjustment switch allows the operator to adjust the threshold value shown on the first display while the second display shows at least one of the actual conditions sensed by the photoelectric sensor.

Abstract: A scanning method for detecting documents is provided an optical scanning device. The optical scanning device is capable of scanning an object by a reflective scanning mode or a transmittal scanning mode. Then obtaining an image signal of the object by either the reflective scanning mode or a transmittal scanning mode with the retrieved scanning mod. Comparing the image signal with a pre-determined signal will result in an implementation from one of the reflective scanning mode or the transmittal scanning mode.

Abstract: An optoelectronic micromodule (201) comprises an optoelectronic component (204), which is fixed on a main carrier (202) and can emit light in an emission direction (206) directed parallel to a main carrier surface (203) of the main carrier (202), and a radiation variation unit (208), which is arranged in the emission direction (206) and fixed to an auxiliary carrier (209), which has an auxiliary carrier surface (210) which is oriented plane-parallel to the main carrier surface (203) and is in touching contact with the latter. The auxiliary carrier (209) is arranged such that it is shiftable plane-parallel to the auxiliary carrier surface (210) relative to the emission direction (206), thereby enabling a two-dimensional adjustment of the radiation variation unit (208). The radiation variation unit (208) can be adjusted both parallel and perpendicularly to the emission direction (206).

Abstract: Near-field optical microscope with a probe tip which is arranged on one side of a light-transmitting specimen and moved in a scanning manner. The probe tip serves as a point light source. Optics for collecting light transmitted through the specimen and transmitting it to a detection unit or for collecting illumination light are provided on the other side of the specimen. The movement of the probe tip is adapted to on the detection side, or the probe serves to detect specimen light. A detection unit is arranged following the probe in the direction of illumination, and a scanning illumination adapted to the probe movement is carried out on the other side of the specimen.

Abstract: The present invention provides a microprobe capable of simplifying constitution, capable of promoting measurement accuracy of sample face and capable of dispensing with alignment adjustment at each measurement and a scanning type probe apparatus using thereof. The present invention includes a low resolution cantilever portion supported by a support portion and integrally formed with heater laminating portions, heater portions formed at the heater laminating portions, piezoresistive elements provided at bending portions and a movable portion having a low resolution stylus and a high resolution cantilever portion supported by the support portion and integrally formed with piezoresistive elements provided at the bending portions and a movable portion having a high resolution stylus.

Abstract: An apparatus for sensing mis-alignment between an aircraft inertial reference frame and a reference frame of an attached sensor is disclosed. The apparatus includes a first laser mounted on the sensor and in the center of and normal to a first measuring surface; and, a second laser also mounted on the sensor perpendicular to the first laser and in the center of and normal to a second measuring surface. A first reflector is mounted to and aligned with the inertial reference frame of the aircraft and is disposed for reflecting a beam of light from the first laser, whereby misalignment in roll and yaw between the sensor and the aircraft is reflected on the first measuring surface.

Abstract: A signal processing apparatus includes a photoelectric conversion element, a compression device which logarithmically compresses an output from the photoelectric conversion element, an expansion device which exponentially expands an output from the compression device, and an integral device which integrates an output from the expansion device, wherein each of a transistor which performs logarithmic compression in the compression device and a transistor which performs exponential expansion in the expansion device is a MOS transistor, where a gate and drain of the MOS transistor of the compression device are connected together, and a source potential and a well potential of the MOS transistor of the compression device are provided with a common potential.

Abstract: A matrix array of photo elements (pixels) arranged in rows and columns with at least one row conductor per row of the matrix and a column conductor per column of the matrix for selectively the pixels. Each pixel of the matrix array includes: (a) a photodetector for detecting light pulses incident on the pixel and producing an output signal indicative of an incident light pulse; (b) signal processing circuitry coupled to the photodetector and responsive to its output signal for generating an electrical pulse corresponding to each incident light pulse; and (c) counting circuitry coupled to the signal processing circuitry for storing information indicative of the number of light pulses incident on the photodector during a sensing period. Row and column decoders are respectively coupled to the row and column conductors of the matrix array for reading out the contents of the array a row at time and for resetting the pixels of each row after their contents have been read out.

Abstract: An optical position detecting device includes side frames on three sides, which are composed of slide parts and guide parts for guiding the slide parts and provided with light retro-reflectors; and a side frame on one side, which is composed of a slide part and a guide part for guiding the slide part and incorporates two optical units including light emitting elements, polygon mirrors and light receiving elements, and the optical position detecting device is externally fixed to a display apparatus by moving the slide parts.

Abstract: A thin image sensor package includes an image sensor having an active area which is responsive to radiation. The image sensor is mounted to a substrate which is transparent to the radiation. The image sensor is mounted such that the active area of the image sensor faces the substrate. Of importance, the substrate serves a dual function. In particular, the substrate is the window which covers the active area of the image sensor. Further, the substrate is the platform upon which the image sensor package is fabricated. As a result, the image sensor package is thin, lightweight and inexpensive to manufacture.

Abstract: A photoelectric conversion apparatus is comprised of a light-receiving element having a first semiconductor region of a first conduction type, and a second semiconductor region of a second conduction type for storing a charge generated by photoelectric conversion adjacent to the first semiconductor region, a readout electrode for reading a signal based on the charge stored in the second semiconductor region; and at least a pair of electrode portions spaced from each other along a photoreceptive surface so as to place a photoreceptive portion of the second semiconductor region in between, and connected to the first semiconductor region. Applied to the pair of electrode portions is a voltage that completely depletes the photoreceptive portion of the second semiconductor region and that can create a potential gradient for moving the charge stored in the second semiconductor region, to the readout electrode side.

Abstract: A range finder includes an improved module structure, that facilitates injecting a transparent filler uniformly into the entire light guide spaces neither leaving any unfilled region nor impairing the characteristics thereof. A channel of flow (or U-groove) is formed across a partition wall, connecting light guide spaces arranged side by side. This feature allows smooth flow of transparent filler into the range finder module without an unfilled region and consequently no overflow of the transparent filler onto outer wall of the plastic module and onto terminal portion of the lead frame. Another feature of this invention is the presence of shield walls along the channel of flow protruding from the side walls of the channel of flow in an inter-digitated fashion, to prevent the stray light from one light guide space entering the other light guide space through the channel of flow.

Abstract: There is disclosed a photodetector which is capable of attaining an enhanced detection accuracy, and at the same time permits reduction in the size and manufacturing costs thereof. An avalanche photodiode detects an incident light, in a state of a predetermined bias voltage set thereto. A cooler cools the avalanche photodiode to a predetermined cooling temperature. An amount of an incident signal light incident on the avalanche photodiode is detected based on a detection signal from the avalanche photodiode. A control block adjusts at least one of the bias voltage and the predetermined cooling temperature, thereby holding a value of the detection signal from the avalanche photodiode generated in a state of the incident light being blocked from impinging on the avalanche photodiode, within a predetermined tolerance range.

Abstract: The image input apparatus picks up the image of the object moved in the predetermined direction by the conveying means and illuminated by illuminating means having an light source, an internal window glass and an outermost window glass. The internal window glass serves as a heat ray absorbing glass, and an outermost window glass serves as a heat ray transmitting glass. The image input apparatus comprises the air cooling means for generating an air flow to forcedly cool the front and the rear surface of the internal window glass.

Abstract: A headlamp control system for a motor vehicle includes an imaging array sensor operable to sense light in a field of view forward of the motor vehicle and a control that is responsive to the imaging array sensor. The control is operable to identify at least one object of interest in the field of view by a spectral signature and/or a geometric organization of the object. The control is operable to control a headlamp of the motor vehicle in response to identifying the object as being at least one of a headlamp of another vehicle, a taillight of another vehicle, a traffic sign, a lane marker and a traffic light. The control may be operable to identify a headlamp and/or taillight of another vehicle in response to light sensed by the imaging array sensor during different exposure periods of the imaging array sensor.

Abstract: Source light of unknown polarization is input into a polarization controller. The polarization controller transforms the polarization of the source light to a plurality of different polarizations. The transformed source light output by the polarization controller is input to a fixed polarizer, which passes a maximal transmitted intensity of the transformed source light at a given transformation perpendicular to an axis of propagation of the source light. The polarizer passes a minimal transmitted intensity of the transformed source light at a transformation orthogonal to the transformation at which the maximal transmitted intensity is passed. The discriminated transformed source light output by the fixed polarizer is input to a light-wave power meter, which measures the intensity thereof. The maximal and minimal measured transmitted intensities of the discriminated transformed source light can be used to determine the DOP of the source light.

Abstract: An optical position measuring system that includes a light source, a measuring graduation, a scanning unit movable relative to the measuring graduation in at least one measurement direction. A projection graduation has periodic amplitude and phase structures disposed in alternation in the measurement direction. The arrangement further includes a detection graduation and a plurality of optoelectronic detector elements, wherein light from the light source interacts with the projection graduation so as to project a fringe pattern onto the detection graduation, so that via the plurality of optoelectronic detector elements, displacement-dependent output signals are detectable, and wherein the projection graduation has a structure such that in addition to even orders of diffraction and the zero order of diffraction, at least some of the (2n+1)th orders of diffraction are suppressed, where n=1, 2, 3, . . .