A light detection and ranging (LIDAR) device includes a substrate layer, a cladding layer, a waveguide, and an ohmic element. The cladding layer is disposed with the substrate layer. The waveguide runs through the cladding layer. The ohmic element runs through the cladding layer. The ohmic element is arranged to impart heat to the waveguide when an electrical current is driven through the ohmic element.

A object detection apparatus may include: an object detection sensor having a cover for protecting the object detection sensor from foreign matter, and configured to sense a target object by transmitting a scan signal to the target object and receiving a sensing signal reflected from the target object; a protection film part including a protection film disposed on an outer surface of the cover to prevent contamination of the cover by foreign matter; and a control unit configured to replace the protection film disposed on the outer surface of the cover through a winding operation for the protection film part when a protection film replacement condition is satisfied due to contamination of the protection film, in order to prevent a reduction in sensing performance of the object detection sensor due to contamination by foreign matter.

The present disclosure provides a range-finding system capable of data communication. The range-finding system includes a rangefinder for acquiring ranging data, a magnetic ring unit having at least two communication channels, and a data processing and control unit. Each communication channel includes a magnetic ring. The magnetic ring unit transmits the ranging data as downlink data from the rangefinder to the data processing and control unit via one or more of the communication channels.

Techniques are disclosed to enable a system for wide-range scanning of objects in three-dimensions. A broad-beam, laser-based transmitter is provided that is adapted to generate a scanning signal to be transmitted in a scanning direction toward an object to be scanned, a portion of the scanning signal being reflected by the object to be scanned. Additionally, a scanning signal collection lens is provided that is adapted to receive the portion of reflected scanning signal and to direct the reflected scanning signal to a mirror array, the mirror array adapted to selectively direct a directed portion of the reflected scanning signal as well as a detector lens adapted to receive the directed scanning signal, the collection lens adapted to focus the directed scanning signal resulting in a focused directed signal and a photoelectric detector adapted to convert the focused directed scanning signal into at least one electronic representation of a two-dimensional image. A rotational motor is provided that is adapted to rotate the system with respect to the area being scanned.

Various measurement systems and methods are disclosed to enable characterizing the optical characteristics of light beams emitted by a light detection and range finding (LIDAR) system or sensor and evaluating the range finding function of user selected lidar channels while the lidar operates under a real operational condition and is exposed to a range of user defined environmental conditions.

Various measurement systems and methods are disclosed to enable characterizing the optical characteristics of light beams emitted by a light detection and range finding (LIDAR) system or sensor and evaluating the range finding function of user selected lidar channels while the lidar operates under a real operational condition and is exposed to a range of user defined environmental conditions.

A sensor module includes a window structure configured to permit the passage of transmitted light and received light between an inside of the sensor module and a field-of-view; a transmitter configured to transmit a transmit light beam; a scanning structure configured to rotate about at least one scanning axis, the scanning structure configured to receive the transmit light beam from the transmitter and direct the transmit light beam towards the window structure and the field-of-view; a light detector configured to detect a reflected light beam that corresponds to the transmit light beam; and at least one processor configured to measure a time-of-flight of a round trip light beam comprising of the transmit light beam and the reflected light beam, compare the time-of-flight to a threshold time, and detect a dirt formation on the window structure on a condition that the time-of-flight is less than the threshold time.

In one embodiment, a modular sensor assembly configured for mounting on a vehicle includes a first set of sensors and a second set of sensors. The modular sensor assembly includes a coordinate frame baseplate including a continuous surface, and sensor mounting elements coupled to the continuous surface for mounting the first set of sensors at a first height. The coordinate frame baseplate includes a sensor platform configured for mounting the second set of sensors at a second height. The first set of sensors and the second set of sensors are coupled to the coordinate frame baseplate so as to impart a common coordinate frame for the first set of sensors mounted at the first height and the second set of sensors mounted at the second height. The modular sensor assembly includes a bridging support structure coupled to the coordinate frame baseplate and capable of being mounted on a vehicle.

An autonomous articulated soil compactor machine can include: a machine frame; at least one cylindrical roller drum rotatably coupled to the machine frame and rotatable about a drum axis oriented generally transverse to a direction of travel of the compactor machine; a first lidar sensor on a front of the machine; a second lidar sensor on a first side of the machine; and a third lidar sensor on a second side of the machine; wherein the first, second and the third lidar sensors are positioned such that 360 degree lidar coverage is provided around the articulated compactor machine.

A LiDAR system includes a light source and an arrayed micro-optic configured to receive light from the light source so as to produce and project a two-dimensional array of light spots on a scene. The LiDAR system also includes receiver optics having an array of optical detection sites configured so as to be suitable for establishing a one-to-one correspondence between light spots in the two-dimensional array and optical detection sites in the receiver optics. The LiDAR system further includes a birefringent prism and a lens. The LiDAR system may also include a mask placed in the light path between the birefringent prism and the receiver optics. Alternatively, the LiDAR system may include a controller programmed to activate or deactivate each optical detection site.