A measurement apparatus mounted to a vehicle includes a light emitting unit, at least one light receiving element, a measurement unit, a monitor circuit, and an adjustment unit. An adjustment unit adjusts the sensitivity of the at least one light receiving element, based on a monitor signal generated by the monitor circuit based on a light reception signal from the at least one light receiving element having received reference light.

A method and an apparatus for calibrating a parameter of a laser radar are provided. The cost function used to determine the predicted value of the first parameter is determined based on the three-dimensional coordinates of the sampling points and the fitting function for the sampling points. The fitting function for the plurality of sampling points uses the first parameter as an independent variable.

A method and an apparatus for calibrating a parameter of a laser radar are provided. The cost function used to determine the predicted value of the first parameter is determined based on the three-dimensional coordinates of the sampling points and the fitting function for the sampling points. The fitting function for the plurality of sampling points uses the first parameter as an independent variable.

A distance measurement apparatus measures a distance to an object by irradiating emission light and detecting reflected light from the object onto which the emission light is irradiated. This apparatus includes a transmission window, a heater wire, and a flexible substrate that is provided in the transmission window. The flexible substrate includes: a surface-mounted-type electronic component; a land to which an electrode of the electronic component is electrically connected, and a conductive adhesive that is formed on the land and adheres the electrode of the electronic component and the land. When a longitudinal direction of a surface of the electronic component that opposes the land is a reference direction, a length along the reference direction of a contact surface between the land and the conductive adhesive is equal to or greater than twice a length along the reference direction of a mounting surface of the electrode of the electronic component.

A distance measurement apparatus measures a distance to an object by irradiating emission light and detecting reflected light from the object onto which the emission light is irradiated. This apparatus includes a transmission window, a heater wire, and a flexible substrate that is provided in the transmission window. The flexible substrate includes: a surface-mounted-type electronic component; a land to which an electrode of the electronic component is electrically connected, and a conductive adhesive that is formed on the land and adheres the electrode of the electronic component and the land. When a longitudinal direction of a surface of the electronic component that opposes the land is a reference direction, a length along the reference direction of a contact surface between the land and the conductive adhesive is equal to or greater than twice a length along the reference direction of a mounting surface of the electrode of the electronic component.

Methods and systems are disclosed for cross-validating a second sensor with a first sensor. Cross-validating the second sensor may include obtaining sensor readings from the first sensor and comparing the sensor readings from the first sensor with sensor readings obtained from the second sensor. In particular, the comparison of the sensor readings may include comparing state information about a vehicle detected by the first sensor and the second sensor. In addition, comparing the sensor readings may include obtaining a first image from the first sensor, obtaining a second image from the second sensor, and then comparing various characteristics of the images. One characteristic that may be compared are object labels applied to the vehicle detected by the first and second sensor. The first and second sensors may be different types of sensors.

The invention relates to a method for detecting a functional impairment of a laser scanner (2) of a motor vehicle (1), in which a laser beam (12) of the laser scanner (2) is transmitted through a protective screen (6) of the laser scanner (2) into a surrounding area (4) of the motor vehicle (1), wherein an echo (16) of the transmitted laser beam (12) at least partially reflected at the protective screen (6) is received by a reception unit (9) of the laser scanner (2) with an intensity value (19), and the functional impairment of the laser scanner (2) is detected if the intensity value (19) is different from a reference intensity value.

The invention relates to a method for detecting a functional impairment of a laser scanner (2) of a motor vehicle (1), in which a laser beam (12) of the laser scanner (2) is transmitted through a protective screen (6) of the laser scanner (2) into a surrounding area (4) of the motor vehicle (1), wherein an echo (16) of the transmitted laser beam (12) at least partially reflected at the protective screen (6) is received by a reception unit (9) of the laser scanner (2) with an intensity value (19), and the functional impairment of the laser scanner (2) is detected if the intensity value (19) is different from a reference intensity value.

Embodiments discussed herein refer to LiDAR systems and methods that monitor for fault conditions that could potentially result in unsafe operation of a laser. The systems and methods can monitor for faulty conditions involving a transmitter system and movement of mirrors in a scanning system. When a fault condition is monitored, a shutdown command is sent to the transmitter system to cease laser transmission. The timing by which the laser should cease transmission is critical in preventing unsafe laser exposure, and embodiments discussed herein enable fault detection and laser shutoff to comply with laser safety standards.

Embodiments discussed herein refer to LiDAR systems and methods that monitor for fault conditions that could potentially result in unsafe operation of a laser. The systems and methods can monitor for faulty conditions involving a transmitter system and movement of mirrors in a scanning system. When a fault condition is monitored, a shutdown command is sent to the transmitter system to cease laser transmission. The timing by which the laser should cease transmission is critical in preventing unsafe laser exposure, and embodiments discussed herein enable fault detection and laser shutoff to comply with laser safety standards.