Abstract: An optical system includes a light source 102 disposed for generating light preferably in a line. An optical element 104 includes a stepped reflecting surface 106 that includes reflecting surfaces 132 and step surfaces 130. The reflecting surfaces 132 have a metalized coating thereon so that the plurality of metalized reflecting surfaces reflect light therefrom. Each reflecting surface is a circular sector that increases in radius from an adjacent circular sector.

Abstract: A reflective clear coat composition. In at least one embodiment, the composition includes a clear coat composition including a polymeric binder comprised of one or more resins and reflective flakes having a reflectivity of at least 30% in at least a portion of the near infrared radiation (NIR) region of the solar spectrum and a reflectivity of 29% or less in at least a portion of the visible region of the solar radiation spectrum. The reflective clear coat composition can be cured onto an exterior cured paint surface of an automotive vehicle. The resulting cured clear coat composition may reduce the temperature generated within a vehicle passenger cabin while exposed to solar radiation.

Abstract: A thermal control system (11) for a light source (46) of a vision system (10) includes a heater (63) that is thermally coupled to the light source (46). A thermal sensor (60) is thermally coupled to the light source (46) and generates a temperature signal. A controller (50) is coupled to the heater (63) and to the thermal sensor (60). The controller (50) operates the heater (63) when the temperature signal is below a maximum temperature limit. The minimum and maximum temperature limits are obtained from the light-source wavelength-temperature characteristic.

Abstract: A thermal control system (11) for a light source (46) of a vision system (10) includes a heater (63) that is thermally coupled to the light source (46). A thermal sensor (60) is thermally coupled to the tight source (46) and generates a temperature signal. A controller (50) is coupled to the heater (63) and to the thermal sensor (60). The controller (50) operates the heater (63) when the temperature signal is below a maximum temperature limit. The minimum and maximum temperature limits are obtained from the light-source wavelength-temperature characteristic.

Abstract: A thermal control system (11) for a light source (46) of a vision system (10) includes a heater (63) that is thermally coupled to the light source (46). A thermal sensor (60) is thermally coupled to the light source (46) and generates a temperature signal. A controller (50) is coupled to the heater (63) and to the thermal sensor (60). The controller (50) operates the heater (63) when the temperature signal is below a maximum temperature limit. The minimum temperature limit corresponds to the wavelength-temperature characteristic of the light source.

Abstract: A thermal control system (11) for a light source (46) of a vision system (10) includes a heater (63) that is thermally coupled to the light source (46). A thermal sensor (60) is thermally coupled to the light source (46) and generates a temperature signal. A controller (50) is coupled to the heater (63) and to the thermal sensor (60). The controller (50) operates the heater (63) when the temperature signal is below a maximum temperature limit. The minimum temperature limit corresponds to the wavelength-temperature characteristic of the light source.

Abstract: An optical system includes a light source 102 disposed for generating light preferably in a line. An optical element 104 includes a stepped reflecting surface 106 that includes reflecting surfaces 132 and step surfaces 130. The reflecting surfaces 132 have a metalized coating thereon so that the plurality of metalized reflecting surfaces reflect light therefrom. Each reflecting surface is a circular sector that increases in radius from an adjacent circular sector.

Abstract: A thermal control system (11) for a light source (46) of a vision system (10) includes a heater (63) that is thermally coupled to the light source (46). A thermal sensor (60) is thermally coupled to the light source (46) and generates a temperature signal. A controller (50) is coupled to the heater (63) and to the thermal sensor (60). The controller (50) operates the heater (63) when the temperature signal is below a maximum temperature limit.

Abstract: A color-corrected lighting system for night vision applications includes a near infrared light source and a thin-sheet optical element disposed a distance from the near infrared source. The optical element includes an input surface for receiving light from the near infrared source and an output surface for emitting the received light in a desired emission pattern. The system also includes a visible, non-red light source in the form of a plate having a plurality of non-red LEDs arranged thereon. The plate is proximate a surface of the optical element such that the output surface of the optical element emits the visible light to mask the emitted near infrared light. A camera is adapted to receive the near infrared light from the near infrared light source reflected off an object within a camera field of view, and a display images objects detected within the camera field of view.

Abstract: A night vision system for a vehicle includes a pulsed light source for illuminating a region proximate the vehicle and a secondary trigger light source operating at a predetermined pulse timing and second wavelength. A light sensor detects light at the second wavelength. The trigger light pulses are used to indicate the pulse timing of each respective vehicle's primary NIR light source. Upon detecting another vehicle's trigger light source, the controller adjusts the pulse phase of the first light source to be exactly out-of-phase with that of the oncoming vehicle since the pulsed timing of the oncoming vehicle's NIR light source is known upon detection of the opposing vehicle's trigger light source. Each vehicle can then adjust its primary light source to be out-of-phase with the other vehicle and, hence, non-interfering.

Abstract: A vision system (10) for a vehicle (14) includes a light source (46) that generates an illumination beam (20). A receiver (62) generates a first image signal and a second image signal. The first image signal is generated in response to a reflected portion of the illumination beam (20). A controller is coupled to the light source (46) and the receiver (62). The controller generates an image in response to the first image signal and the second image signal.

Abstract: A vision system (10) for a vehicle (14) includes a light source (46) that generates an illumination beam (20). A receiver (92) generates an image signal in response to a reflected portion of the illumination beam (20). A transmission sensor (120) generates a transmission signal. A controller (50) is coupled to the light source (46), the receiver (92), and the transmission sensor (120) and enables activation of the light source (46) in response to the transmission signal.