A vehicular camera includes a lens assembly and a circuit board having a first side and a second side opposite the first side. The circuit board has a first coefficient of thermal expansion (CTE). An imager is disposed at the first side of the circuit board and optically aligned with the lens assembly. A bend-countering element is disposed at the second side of the circuit board. The bend-countering element has a second CTE that is greater than the first CTE of the circuit board. The bend-countering element counters temperature-induced bending of the circuit board. With the camera disposed at the vehicle, temperature-induced bending of the bend-countering element is in an opposite direction from temperature-induced bending of the circuit board.

An infrared sensor cover includes a decorative layer, a transparent first base, and a transparent second base. The decorative layer includes a first surface and a second surface opposite the first surface. The first base is made of a resin molded body and disposed on the first surface of the decorative layer. The second base is made of a resin molded body and disposed on the second surface of the decorative layer. An absolute value of a difference between refractive indices of a first resin material of the first base and a second resin material of the second base is less than or equal to 0.05. An absolute value of a difference between heat deflection temperatures of the first resin material and the second resin material is greater than or equal to 15 degrees.

Disclosed herein are methods, systems, and devices for monitoring cumulative radiation. In one embodiment, a device includes a photodiode; an integrating capacitor electrically coupled with the photodiode; a voltage discharge switch electrically coupled with the integrating capacitor; and amplifier circuitry electrically coupled with the photodiode and the integrating capacitor. The amplifier circuitry is configured to maintain a substantially zero bias voltage between an anode and a cathode of the photodiode monitoring the cumulative radiation. The integrating capacitor is configured to provide a delta voltage representative of radiation received since the beginning of a charge cycle of the integrating capacitor.

A light detection device includes an APD, a plurality of temperature compensation diodes, and a circuit unit. The plurality of temperature compensation diodes have different breakdown voltages lower than a breakdown voltage of the APD. The circuit unit puts any one of the plurality of temperature compensation diodes into a breakdown state. The circuit unit includes a plurality of terminals and a terminal. The plurality of terminals are respectively connected to electrodes of the mutually different temperature compensation diodes. The terminal is electrically connected to the APD and electrodes of the temperature compensation diodes.

The present disclosure describes subassemblies and optoelectronic modules in which an optics system, or a spacer laterally surrounding a cover glass, includes a flange which facilitates mechanical attachment of the optics system to the spacer.

A temperature compensation circuit for a light source (e.g., light emitting diode (LED)) whose radiant energy output decreases when ambient temperature increases includes a first circuit element for generating a first current that increases proportional to an increase in the ambient temperature, and a second circuit element for generating a second current that is first order independent of the ambient temperature. The circuit further includes a weighted current adder for generating a third current by combining the first and second currents with first and second weights applied to the first and second currents respectively. The circuit further includes a third circuit element responsive to the third current for supplying a fourth current to the light source to maintain a radiant energy output of the light source constant independent of the ambient temperature.

To achieve a substantially uniform microstructure across a continuously cast thin metal strip, it is beneficial to cool a width of the strip to a substantially constant temperature before further cooling the strip to reach any desired phase transformation temperature. Accordingly, methods of continuously casting a thin metal strip may include moving the thin strip to a cooling section, the cooling section having a plurality of coolant discharge ports configured to discharge a flow of coolant along the thin strip; initially sensing the temperature of the thin strip to determine a temperature distribution across the width of the thin strip, and producing a sensor signal corresponding to a sensed temperature at each of the first plurality of locations; and individually controlling the cooling across a width of the thin strip by way of the plurality coolant discharge ports in each zone of a first row using the determined temperature distribution.

An electronic arrangement includes a first bias terminal, a ground terminal, a photodiode including an anode terminal and a cathode terminal, and a transimpedance amplifier including an operational amplifier. The electronic arrangement is selectively switchable to a photocurrent measurement mode and a temperature measurement mode. In the photocurrent measurement mode: the anode terminal is connected to a first input of the operational amplifier; the cathode terminal is connected to a second input of the operational amplifier; and the first bias terminal is connected to the first input of the operational amplifier and the anode terminal. In the temperature measurement mode: the anode terminal is connected to the ground terminal; the cathode terminal is connected to the second input of the operational amplifier; and the first bias terminal is connected to the first input of the operational amplifier and disconnected from the anode terminal.

Methods, systems, and apparatus, including computer programs encoded on a computer storage medium, for generating a first light wave by an emitter of the sensor system and detecting a second light wave by a detector of the sensor system. The second light wave is detected in response to the first light wave being reflected from a target object. The sensor system includes a first converter that obtains a first temperature measurement from a temperature sensor of the sensor system at least when the first light wave is generated or when the second light wave is detected. A temperature controller computes temperature coefficients to regulate a temperature of the sensor system. Each of the temperature coefficients are computed based on a difference between the first temperature and a reference temperature. The temperature controller generates a control signal to regulate the temperature of the sensor system based on the computed temperature coefficients.

A method for operating a sensor device for determining a road condition. Beams of at least one beam source are generated and emitted into a scanning area. Beams that are scattered or reflected back from the scanning area are ascertained by at least one detector and evaluated for determining the road condition with the aid of the control unit coupled to the detector. Temperature-dependent influences on at least one component of the sensor device are ascertained with the aid of at least one sensor. The temperature-dependent influences on the component of the sensor device are compensated for by a heating device and/or a cooling device and/or during the evaluation by the control unit. A control unit and a computer program are also described.