Abstract: A vehicular tracking system and a method are provided. The system includes: a sensor configured to emit a sensor beam toward a vehicle to be tracked; an information calculator configured to calculate, through the sensor, sensor beam emission information and movement information of the vehicle to be tracked; and a tracking setter configured to receive the movement information and the emission information from the information calculator and set, through the movement information and the emission information, a tracking gate for the vehicle to be tracked.

Abstract: A method for tracking a maximum temperature point includes acquiring a first pair of coordinates of a maximum temperature point in a current frame of image sensed by an infrared camera, determining a rotation angle of a gimbal equipped with the infrared camera according to the first pair of coordinates of the maximum temperature point in the current frame of image and a pair of coordinates of a target position of the maximum temperature point in a subsequent frame of image, and controlling the gimbal to rotate according to the rotation angle, so as to adjust the maximum temperature point in the subsequent frame of image captured by the infrared camera to be located at the target position.

Abstract: An optical sensor device has a transmission unit for emitting light, a receiving unit for light emitted by the transmission unit, and an evaluation unit for evaluating a receive signal, which is based on the received light, wherein the emitted light is designed as a light pulse which is based on a transmission signal, which has a signal shape with a rising and/or falling flank, wherein the receive signal has substantially the same signal shape as the transmission signal, wherein the evaluation unit is suitable for scanning the receive signal at at least one scanning point in its rising and/or falling flank.

Abstract: In the method, a first pair of coordinates of a maximum temperature point in an image sensed by an infrared camera is acquired, where the image is an image captured by the infrared camera. A rotation angle of a gimbal equipped with the infrared camera is then determined according to the first pair of coordinates of the maximum temperature point and a pair of coordinates of a target position in the image. The gimbal is then controlled to rotate according to the determined rotation angle, so as to adjust the maximum temperature point in the image captured by the infrared camera to be located at the target position.

Abstract: In a wireless distribution system, a test signal(s) having a first power level is injected from a first contact point. The test signal(s) is configured to propagate from the first contact point to a second contact point over a downlink path and an uplink path, thus creating a signal loop(s). A second power level of the test signal(s) is measured at the second contact point, and an actual loop gain of the wireless distribution system is determined by subtracting the first power level from the second power level. By determining the actual loop gain of the wireless distribution system, it is possible to further determine a gain margin of the wireless distribution system. Based on the gain margin, it is possible to determine optimization possibilities for the wireless distribution system to maximize capacity and performance of the wireless distribution system.

Abstract: Embodiments of the disclosure relate to determining actual loop gain in a distributed antenna system (DAS). In this regard, a test signal(s) having a first power level is injected into a DAS from a first contact point. The test signal(s) is configured to propagate from the first contact point to a second contact point over a downlink path and an uplink path, thus creating a signal loop(s). A second power level of the test signal(s) is measured at the second contact point, and an actual loop gain of the DAS is determined by subtracting the first power level from the second power level. By determining the actual loop gain of the DAS, it is possible to further determine a gain margin of the DAS. Based on the gain margin, it is possible to determine optimization possibilities for the DAS to maximize capacity and performance of the DAS.

Abstract: Provided are a method for measuring tool dimensions and a measurement device, whereby if a machine tool (10) cannot fit the overall outline of a tool (20) inside the field of vision (V) for an image from an imaging device (33), the field of vision (V) of the imaging device (33) is moved by relatively moving the imaging device (33) and the tool (20). In addition, the imaging device (33) can follow the outline (54) of the tool (20) by moving the field of vision (V), because the movement direction (53) for the field of vision (V) is determined on the basis of the partial outline (51) specified based on image data. In this way, even when measuring dimensions for a tool (20) with a larger diameter than the field of vision (V) of the imaging device (33), a partial outline (51) of a desired range, for example, is specified. An outline of a desired range for the tool (20) is extracted if a plurality of specified partial outlines (51) are combined.

Abstract: Disclosed herein is a solar cell system including: a plurality of power generation panels that differ in the range of wavelengths of light they absorb from each other and convert light into power; a voltage detection section adapted to detect the voltage of power generated by each of the plurality of power generation panels; a reproduction section adapted to compare the voltages of the plurality of power generation panels detected by the voltage detection section so as to reproduce an audio or music signal appropriate to the comparison result; and an output section adapted to output audio or music reproduced by the reproduction section.

Abstract: An apparatus and method of integrating optics into an IC package is for detecting light from at least one light source is disclosed. The apparatus has a housing, which has a predetermined spectral transmittance. A sensor is positioned within the housing. An opaque mask is applied to the housing, where the opaque mask has a hole aligned with the sensor such that the light's centroid is detected by the sensor. In one embodiment, the apparatus further comprises a substrate for positioning and stabilizing the sensor in the housing, an analog filter and amplification module (“AFA”) for filtering and amplifying signals from the sensor and generating a second signal, and a digital signal processor (“DSP”) for generating a coordinate system by extracting frequency components from the AFA output signal.

Abstract: A three-dimensional location measurement sensor including first and second rotation plates to rotate about a fixed axial member independently of each other, a camera, formed inside the fixed axial member in the middle of the second rotation plate, a mirror, to be supported by a mirror supporting unit so as to be disposed over the camera, the mirror supporting unit being fixed to the first rotation plate, at least one light source, to be supported by a light source supporting unit so as to be disposed between the mirror and the second rotation plate, the light source supporting unit being fixed to the first rotation plate, a mark, to be supported by a mark supporting unit so as to be disposed between the mirror and the second rotation plate, the mark supporting unit being formed on the second rotation plate, and a gear unit, which is formed at an outer circumference of the second rotation plate and adjusts an inclination angle of the mirror.

Abstract: A method and apparatus are provided for testing a photodetector (20) that has a narrow field of view (A) and an alignment surface (50), to determine whether the field of view and the axis (52) of the field of view are precisely what is expected or deviates therefrom. While the photodetector views a region or zone (102), a narrow spot of light (82) is moved into and out of the zone and across the zone, while the output of the photodetector is monitored. The narrow spot of light is generated by focusing a small spot of light onto a surface. The small spot of light can be a spot of light on an oscilloscope monitor (80) which scans the spot back and forth in a raster pattern. To create a very small spot, the image on the oscilloscope monitor is focused to a greatly reduced size spot image (124) onto the surface that the photodetector views.

Abstract: An infrared imaging device including a quantum device positioned and configured to detect infrared transmission at ambient temperature, a cooler thermally coupled to the quantum device, and controller for controlling the cooler based on a function of plural image-taking parameters as a command.