Abstract: A solid-state imaging device including pixel photododes on a light-receiving surface of a substrate; a first insulating film on the substrate covering a multilayer wiring on and in contact with the substrate. The first insulating film comprises material of a first refractive index lower than a refractive index of the substrate for at least bottom and top surface portions of the first insulating film. A second insulating film with a second refractive index higher than the first refractive index is on the first insulating film. A third insulating film with a third refractive index higher than the second refractive index is on the second insulating film. For each pixel, a color filter is on the third insulating film.

Abstract: A non-saturating receiver design and clamping structure for high power laser rangefinders of especial utility with respect to pumped, monoblock lasers. The receiver comprises a photodiode and a transimpedance amplifier having at least first and second stages. The first stage comprises a field effect transistor and the second stage comprises a non-saturating, non-inverting amplification stage including a differential pair of bipolar transistors having a feedback path coupling the second stage to the input of the first stage. A clamping structure for the receiver comprises a resistor coupling a cathode of the photodiode to a first voltage input and a clamping diode also coupling the cathode to a second lower voltage input. A capacitor having a capacitance Cs couples the cathode of the photodiode to a reference voltage line, wherein the capacitance Cs is greater than the capacitance of the photodiode CD.

Abstract: An automated shutter for dark acclimating a sample, comprising a base and a head mounted to the base and movable between an open and closed position. The automated shutter further comprises one or more artificial light sources and one or more optical detectors disposed in said head or base, and wherein the head is contiguous with the sample when moved into the closed position. Another embodiment comprises an enclosure placed over a sample to be dark acclimatized, with one or more artificial light sources and optical detectors disposed within or closely adjacent to said enclosure which is configured to be transformed between an optically transparent state and an optically opaque state.

Abstract: Certain embodiments described herein are directed to optical detector and optical systems. In some examples, the optical detector can include a plurality of dynodes, in which one or more of the dynodes are coupled to an electrometer. In other configurations, each dynode can be coupled to a respective electrometer. Methods using the optical detectors are also described.

Abstract: An optical sensor comprising a light source; a sensor substrate, arranged to receive a force to be detected, the sensor substrate including an interference pattern generator, optically coupled to the light source for receiving light from the light source, and generating an interference pattern, and a detector, optically coupled to the sensor substrate for receiving the interference pattern and providing a signal which can be used to determine the force applied to the sensor substrate.

Abstract: Optical computing devices are disclosed. One exemplary optical computing device includes an electromagnetic radiation source configured to optically interact with a sample and at least two integrated computational elements. The at least two integrated computational elements are configured to produce optically interacted light and further configured to be associated with a characteristic of the sample. The optical computing device further includes a first detector arranged to receive the optically interacted light from the at least two integrated computational elements and thereby generate a first signal corresponding to the characteristic of the sample.

Abstract: A confocal image generation apparatus includes a laser, an objective, an optical path branch element which branches an optical path of an excitation light and an optical path of fluorescence, a scanning optics which shifts alight collecting position of the excitation light on a focal plane of the objective in an orthogonal direction to an optical axis of the objective, an optical detector in which a plurality of light-receiving elements are two-dimensionally arrayed with a shorter pitch than a diameter of a fluorescence Airy disk formed on an imaging plane that is optically conjugated with the focal plane, and an image operation unit which generates a confocal image of the sample in which a super-resolution component is emphasized on the basis of a signal that is output from the plurality of light-receiving elements, the super-resolution component being a frequency component that exceeds a cut-off frequency of the objective.

Abstract: An image flow cytometer has a flow chamber with a flow channel formed therein to permit a microparticulate sample to flow through the flow channel. An irradiation optical system irradiates the sample in the channel with incident light in an irradiation spot smaller than a selected representative size, e.g., smaller than the sample. The system scans an irradiation position perpendicular to the flow direction of the sample. A detection optical system is opposed to the irradiation optical system through the flow chamber, or is off the optical axis of the incident light. The detection system detects a light intensity of resultant light from the flow chamber. A control unit detects the microparticulate sample according to a change of the light intensity of the resultant light detected by the detection optical system.

Abstract: A vertical shift register section includes M logic circuits for outputting row selection control signals respectively to M row selection wiring lines and shift register circuits disposed for every two row selection wiring lines. The M logic circuits, when a binning control signal Vbin1 or Vbin2 and an output signal of the shift register circuit both have significant values, output a row selection control signal Vsel so as to close a readout switch. The vertical shift register section, by controlling the timing at which the binning control signals Vbin1 and Vbin2 take significant values, realizes a normal operation mode for successively selecting the two row selection wiring lines and a binning operation mode for simultaneously selecting the two row selection wiring lines. Accordingly, a vertical binning operation is realized by a small vertical shift register.

Abstract: A proximity sensor may be mounted below a display cover layer in an electronic device. The proximity sensor may have a light source that emits light and a detector configured to detect reflections of the emitted light from nearby external objects. Optical structures may be interposed between the proximity sensor and the window in the display cover layer. The optical structures may include a first portion such as a convex lens that is configured to collimate light from the light source so that the light propagates along a surface normal to the display cover layer. The optical structures may also include a second portion such as a prism structure for deflecting uncollimated light away from the propagation axis of the collimated light.

Abstract: An integrated image sensor circuit with multiple power modes is disclosed. The integrated circuit comprises a pixel array, an analog block to process analog signal associated with the pixel array, where the analog block comprises an analog to digital convertor (ADC), and a first control circuit to enable/disable the analog block or to configure the analog block to a high/low-power mode depending on whether the pixel array is in a readout frame or in a reset frame with no active readout. The integrated image sensor circuit may further comprise a post-processing block and a second control circuit to enable/disable the post-processing block or to configure the post-processing block to the high-power mode or the low-power mode depending on whether the pixel array is in the readout frame or in the reset frame with no active readout.

Abstract: An imager may include an imaging die that is stacked with an image processing die. The imaging die may generate output signals from received light. The image processing die may process the output signals. Through-silicon vias of the imaging die or solder balls may electrically couple the imaging die to the image processing die and convey the output signals to the image processing die. The imaging die may include a pixel array that generates pixel signals from the received light. The image processing die may generate control signals that control the imaging die and are conveyed to the imaging die over the through-silicon vias or solder balls.

Abstract: In order to suppress a variation of a signal held by each signal holding unit, a solid-state imaging apparatus of the present invention is characterized in that, when a clamp operation of a pixel output signal is performed in the signal holding unit, a time changing rate of an amplitude of a drive pulse supplied to the selecting unit for turning from a non-conducting state to a conducting state is not larger than a time changing rate of the amplitude of the drive pulse supplied to the selecting unit for turning from the conducting state to the non-conducting state.

Abstract: A sensor includes an enclosure having a housing and a lower cassette that cooperate to provide a sealed volume in which an optical sensor assembly is enclosed and protected. The optical sensor assembly includes a circuit board with a light source and a light detector. The sensor assembly further includes a light pipe that guides light from the sensor onto a target and a lens guides reflected light from the target onto the light detector. Lower ends of the light pipe and the lens are supported by a recess in the lower cassette. Upper ends of the light pipe and the lens are supported by an upper cassette. The upper cassette is positively located and mounted to the circuit board and received in an internal receptacle in the lower cassette. Mounting the lower cassette to the housing encloses the optical sensor assembly in the proper alignment.

Abstract: A plasmonic detector and method for manufacturing a plasmonic detector. The plasmonic detector comprises two nanoscale metallic rods coupled to a bias voltage; a nanoscale cavity formed between adjacent ends of the two nanoscale metallic rods; and an absorption material disposed in the nanoscale cavity for converting an electromagnetic field to an electric current for outputting via the nanoscale metallic rods.

Abstract: An image sensor array has a tiling unit comprising a source follower stage coupled to buffer signals from a photodiode when the unit is read onto a sense line, the source follower stage differs from conventional sensor arrays because it uses an N-channel transistor having a P-doped polysilicon gate. In embodiments, other transistors of the array have conventional N-channel transistors with N-doped polysilicon gates.

Abstract: A fluid level gauge includes a housing having a first end and a second end, and a window disposed in the housing, proximate to the first end. The fluid level gauge further includes an optical sensor disposed in the housing, proximate to the second end. A prism is disposed in the housing, between the optical sensor and the window, such that the prism and the window define a fluid chamber therebetween. The housing further includes a plurality of through holes that provides a fluid path from outside the housing to the fluid chamber.

Abstract: A fluid level gauge includes a housing having a first end and a second end, and a window disposed in the housing, proximate to the first end. The fluid level gauge further includes an optical sensor disposed in the housing, proximate to the second end. A prism is disposed in the housing, between the optical sensor and the window, such that the prism and the window define a fluid chamber therebetween. The housing further includes a plurality of through holes that provides a fluid path from outside the housing to the fluid chamber.

Abstract: A single-plate color imaging element including color filters in a predetermined color filter array arranged on a plurality of pixels formed by photoelectric conversion elements arranged in horizontal and vertical directions, wherein in the color filter array, the first filters are vertically and horizontally arranged across a filter at a center of a 3×3 pixel group, and the 3×3 pixel group is repeatedly arranged in the horizontal and vertical directions.

Abstract: The invention is based on an autofocus method in which light from a light source (12) is focused at a measurement light focus (52) in a sample (6) and is reflected from there and the reflected light is guided through an optical system (22) in two light paths (48, 50) onto at least two detector elements (72, 74). In order to achieve fast and accurate automatic focusing on the sample, it is proposed that the measurement light focus (52) is moved in layers of the sample (6) which reflect light to different extents, and the detector elements (72, 74) are arranged in such a way that, in this case, profiles of a radiation property registered by the detector elements (72, 74) are different and a focus position is set in a manner dependent on the profiles.