Described herein is a detector for detecting optical radiation, especially within the infrared spectral range, specifically with regard to sensing at least one of transmissivity, absorption, emission and reflectivity, being capable of avoiding or diminishing a cross detection between sensor areas, specifically between adjacent sensor areas, thus, avoiding or diminishing a deterioration of a measurement based on the at least one sensor signal.

A photodetector including: a case including a light receiving surface provided on an upper surface and having a first region that transmits visible light and a second region that transmits less visible light than the first region; a printed circuit board provided to face the light receiving surface; and a plurality of electronic components provided on a light receiving surface side of the printed circuit board and including a first light receiving element configured to detect visible light. The first light receiving element is disposed at a first position of the printed circuit board exposed to the visible light transmitted through the first region. The number of mounted electronic components disposed at the first position is smaller than the number of mounted electronic components disposed at a second position of the printed circuit board other than the first position.

A determination method determines a difference voltage between a breakdown voltage and a bias voltage. A temperature compensation unit provides temperature compensation for the gain of the APD by controlling the bias voltage based on the difference voltage. The bias voltage is “V.sub.r”, and the gain of the APD to which the bias voltage is applied is “M”. The slope and intercept of the regression line having “(1/M)×(dM/dV.sub.r)” as an objective variable and “M” as an explanatory variable in data indicating the correlation between the bias voltage and the gain are obtained. “ΔV” calculated by substituting the slope into “a” in the Equation (1), substituting the intercept into “b” in the Equation (1), and substituting a gain to be set in an avalanche photodiode of a light detection device into “M.sub.d” in the Equation (1) is determined as the difference voltage.

[00001]$\left[\mathrm{Equation}1\right]$$\begin{array}{cc}\Delta V=\frac{1}{b}\log \left(\frac{b\text{/}a}{M_d}+1\right)& \left(1\right)\end{array}$

In one aspect, luminaires are described herein having sensor modules integrated therein. In one aspect, a luminaire described herein comprises a light emitting face including a LED assembly. A sensor module is integrated into the luminaire at a position at least partially overlapping the light emitting face. In another aspect, a luminaire described herein comprises a LED assembly and a driver assembly. A sensor module is integrated into the luminaire along or more convective air current pathways cooling the LED assembly or driver assembly.

A security light having optional connection to multiple power supplies. The lighting controller can sense the appropriate connected supply and automatically connect to three different power supplies which include house voltage connection through a typical junction box, a remote solar charging station, and on board batteries that can be used as a third backup power supply. Additional implementations include power outage detection and backup illumination along with low voltage power supply from a mounting structure.

An electronic device including an optical component and an enclosure comprising a glass ceramic region is disclosed. The optical properties of the glass ceramic region and the positioning of the glass ceramic region with respect to the optical component can affect the performance of the optical component, the visual appearance of the optical component, or both.

In a light detection device 1 the plurality of pad electrodes are arranged on the semiconductor substrate. Each of the plurality of wires is connected to the pad electrode corresponding thereto. A stitch bond of a corresponding wire is formed on each pad electrode. A distance between each pad electrode and a cell corresponding to the pad electrode is smaller than a distance between the pad electrodes connected to mutually different cells of the cells. The plurality of pad electrodes are arranged in a first region and a second region that are spaced apart from each other with a light receiving region interposed therebetween. The pad electrode corresponding to a cell is arranged in the first region. The pad electrode corresponding to a cell is arranged in the second region.

In a light detection device, the semiconductor substrate has first and second main surfaces facing each other. The semiconductor substrate includes a plurality of cells. Each of the plurality of cells includes at least one avalanche photodiode. The plurality of pad electrodes are arranged on the first main surface so as to be spaced apart from the plurality of cells. The plurality of wiring portions are arranged on the first main surface. Each of the plurality of wiring portions connects the cell and the pad electrode corresponding to each other. The semiconductor substrate includes a peripheral carrier absorbing portion configured to absorb carriers located at a periphery of the peripheral carrier absorbing portion. The peripheral carrier absorbing portion is provided around each pad electrode and each wiring portion when viewed from a direction perpendicular to the first main surface.

An optical seeker assembly having an optical detector located within the wing or canards of a precision guided munition. The optical seeker provides on-wing processing that generates low bandwidth detection data that can be easily transferred to a primary CPU located within the main body or fuselage of the precision guided munition. The on-wing processing reduces or eliminates the need for optical fibers extending between an optical wedge and an optical detector to reduce the likelihood of optical fibers from impeding in the mechanical deployment of the wing and reduces losses. The reduction or elimination of optical fibers between the optical wedge and the optical detector further enables the optical detection assembly to have a higher pixel ratio or transmitting raw data between the wedge and the detector by sending sampled detection data across a low bandwidth link to a CPU in the main body.

A light barrel configured to filter out stray light of a test light includes a casing and a number of light shield plates arranged within the casing. The light shield plates are parallel to each other and arranged within the casing along a direction in which the light source emits the test light. Each of the light shield plates defines a through hole for light from the test light to pass through. The through holes of the light shield plates are a same size and aligned. The light shield plates sequentially filter out stray light that does not pass through the through holes.