This application provides a device positioning method, which is applied to a vehicle and includes: obtaining location information of at least one landmark and feature information of the at least one landmark, where the feature information includes pattern information and/or identification information; obtaining feature information of a first landmark, where the feature information of the first landmark includes pattern information and/or identification information of the first landmark, and the at least one landmark includes the first landmark; determining location information of the first landmark based on the feature information of the first landmark; and determining a location of a device based on the location information of the first landmark. According to the device positioning method provided in this application, a vehicle can be positioned without a need to equip the vehicle with a high-resolution sensing unit and excessively improve an area where the vehicle locates.

The present disclosure is directed to checking and updating the calibration of a sensing apparatus at an autonomous vehicle (AV). After a sensing apparatus of an AV has been initially calibrated (e.g., when the AV is manufactured) calibration of that sensing apparatus may be checked or updated using data collected from similar vehicles of a fleet of vehicles. Each of the different vehicles of this fleet may identity its location and report that location. A first of these vehicles may receive data that identifies the location of a second vehicle. A sensing apparatus of the first vehicle may then identify locations of features at the second vehicle and a processor of the sensing apparatus may perform calculations to identify whether calibration of the sensing apparatus has changed. Parameters that adjust the calibration of the sensing apparatus may then be updated to maintain calibration of a sensing apparatus within acceptable tolerances.

The present technology relates to a signal processing device, a signal processing method, a program, and an information processing device capable of reducing processing of folding correction of velocity measured by a radar.

The signal processing device includes a measurement unit that measures, on the basis of an output signal from a radar, a distance and relative velocity of a reflector that reflects a transmission signal from the radar, and a correction unit that performs folding correction of measured velocity of the reflector on the basis of correlation between a measured distance and measured velocity of the reflector at a certain measurement time, and a measured distance and measured velocity of the reflector at a time before the measurement time. The present technology can be applied to, for example, a system that senses an object around a vehicle.

A driver assistance system (DAS) configured to determine a lane provided with a radar reflector includes a radar configured to emit radio wave in front of the vehicle and obtain radar data by receiving reflected wave reflected from an object in front of the vehicle; a controller configured to determine whether the object is the radar reflector based on the magnitude of energy of the reflected wave included in the obtained radar data, and to determine a line connecting the determined radar reflector as a lane. It is an object of the present invention to provide a driver assistance system and a driver assistance method capable of obtaining lane information based on a radar track.

A mobile robot is configured for operation in a commercial or industrial setting, such as an office building or retail store. The robot can patrol one or more routes within a building, and can detect violations of security policies by objects, building infrastructure and security systems, or individuals. In response to the detected violations, the robot can perform one or more security operations. The robot can include a removable fabric panel, enabling sensors within the robot body to capture signals that propagate through the fabric. In addition, the robot can scan RFID tags of objects within an area, for instance coupled to store inventory. Likewise, the robot can generate or update one or more semantic maps for use by the robot in navigating an area and for measuring compliance with security policies.

A method can include sending, via a processing device, a signal to at least two of a plurality of location indicators from an autonomous vehicle in motion and transporting equipment or passengers. The method can further include receiving signals from the at least two location indicators. The method can further include determining a location of the autonomous vehicle within an indoor facility based on the received signals. The method can further include comparing the determined location to a corresponding pre-determined location. The method can further include, in response to the determined location being different than the pre-determined location, adjusting a direction of the autonomous vehicle along a predetermined path within the indoor facility.

Systems and methods to use radar systems for radio frequency identification (RFID) applications. The radar systems can be adapted to use RFID communications protocols and methods to enhance the usefulness of radar systems beyond the determination of the presence, distance, direction and/or speed of a vehicle or object, to additionally include the transmission of data such as object identification and additional messages or data.

The techniques and systems herein enable ghost object detection. Specifically, a reflection line indicative of a potential reflection surface between first and second moving objects is determined. If enough stationary objects are within an area of the reflection line, it is determined whether one or more of the stationary objects within the area are within a distance of a reflection point. An expected velocity of the second object is then determined and checked against a velocity of the second object. If the expected velocity is near the velocity, it is determined that the second object is a ghost object. By doing so, the system can effectively identify ghost objects in a wide variety of environments, thereby allowing for downstream operations to function as designed.

A radar radiation redirecting inhibition layer for reducing radar cross section (RCS) of radar radiation redirection pavement marking tapes, pavement marking cover tapes incorporating such layer and methods of use are described.

A vehicle-to-vehicle communications system utilizes passive modulation of radar signals to communicate information between vehicles. Passive radar modulators may be provided at the rear of a forward vehicle and used to enrich radar interrogation signals from a rearward vehicle with additional information. Since radar transceivers are already located on a great deal of modern vehicles, this functionality may be easily retrofitted into many vehicles without the addition of a radar transceiver. A number of vehicles in a line of vehicles may pass information back through the line by passive modulation of radar interrogation signals from each vehicle. Accordingly, a vehicle may gain information about vehicles ahead of the one directly in front of it, thereby enabling “see through radar” functionality.