A railroad car location, speed and heading sensor system including at least one self-powered, tie-mounted sensor node that is applicable universally to different railroad settings without using track circuits, inductive loops, radar systems, and wheel counters and associated disadvantages. Reliable and relatively low cost deterministic and redundant car presence detection is realized when multiple sensor nodes are arranged in a network, which may be a wireless mesh network, that is not affected by environmental conditions.

A detection method implementing an FMCW waveform is provided, the emitted waveform is formed of a recurring pattern of given period Tr covering an emission frequency band of given width B, each pattern being divided into a given number P of sub-patterns of duration Tr/P covering an excursion frequency band F=B/P, the sub-patterns being mutually spaced by a frequency interval equal to F. The radar performs: a first distance-compression processing operation carrying out a low-resolution distance compression at the scale of each recurring pattern on a fraction B/P of the emission band of width B corresponding to the frequency band covered by each of the sub-patterns; a Doppler processing operation on a given number N of successive recurrences so as to form P ambiguous distance-Doppler maps of low distance resolution, the maps being segmented into various speed domains; a second distance-compression processing operation of resolution that differs depending on the speed domain to which the relative speed of the target with respect to the radar belongs.

A method includes generating a target map indicative of objects around the vehicle using sensor data from sensor circuitry of the vehicle, the sensor circuitry including at least one radar sensor; and determining, by processing circuitry, if the vehicle is being towed away. Determining if the vehicle is being towed away can include comparing the target map to a previously obtained target map, determining if the vehicle is moving based on the comparison, and in response to determining the vehicle is moving, outputting an alarm message indicative of the vehicle being towed away.

Methods, systems, computer-readable media, and apparatuses for radar or LIDAR measurement are presented. Some configurations include transmitting, via a transceiver, a first beam having a first frequency characteristic; calculating a distance between the transceiver and a moving object based on information from at least one reflection of the first beam; transmitting, via the transceiver, a second beam having a second frequency characteristic that is different than the first frequency characteristic, wherein the second beam is directed such that an axis of the second beam intersects a ground plane; and calculating an ego-velocity of the transceiver based on information from at least one reflection of the second beam. Applications relating to road vehicular (e.g., automobile) use are described.

A method for determining a movement state of a rigid body relative to an environment using a multiplicity of measurement data sets relating to objects in the environment around the body. Each measurement data set includes a measurement time, a Doppler velocity, and an azimuth angle in relation to a respective sensor reference system. The method includes determining a movement state of the body relative to the environment as a velocity vector and an angular velocity vector in a body reference system. At least one set of conditions that includes a plurality of measurement data sets is created. A function dependent on Doppler velocity deviations between estimated Doppler velocities and the Doppler velocities of the measurement data sets included in the set of conditions is minimized in a regression analysis for the set of conditions. The estimated Doppler velocities are regarded as dependent variables in the regression analysis.

A system for reducing accidents caused by distracted drivers. The system may form an invisible track using material-impregnated grooves and a radar beam, preventing a vehicle from veering away from a road lane. The material-impregnated grooves (MIGs) within one or more road lanes may include scrap metal. The radar beam may be emitted from a transceiver mounted underneath the vehicle such that backscatter from the MIGs is returned to the transceiver.

A marine vessel includes a hull, a propulsion system, a control unit and a motion sensor system. The propulsion system comprises a first drive unit and a second drive unit separated by a longitudinal midship line of the hull, where each drive unit is arranged to generate thrust in a controllable thrust elevation angle and in a controllable thrust azimuth angle, where at least the thrust elevation angles are individually controllable The control unit is arranged to estimate a pitch motion and a roll motion of the hull based on input from the motion sensor system. The control unit is arranged to suppress pitch motion and roll motion by the hull by controlling the thrust elevation angles and the thrust azimuth angles of the first and second drive units.

A multisensor data fusion perception method includes receiving feature data from a plurality of types of sensors, obtaining static feature data and dynamic feature data from the feature data, constructing current static environment information based on the static feature data and reference dynamic target information, and constructing current dynamic target information based on the dynamic feature data and reference static environment information such that construction of a dynamic target and construction of a static environment are performed by referring to each other's construction results and the perception capability is for the dynamic target and the static environment that are in an environment in which the moving carrier is located.

Method and apparatus are disclosed for communication of infrastructure information to a vehicle via ground penetrating radar. A vehicle comprising an antenna positioned to broadcast radio waves below the vehicle, a ground penetrating radar system, and an active safety module. The ground penetrating radar system determines types of reflectors and a spatial relationship between the reflectors based on radar cross-sections detected by the antenna, and generates a signature based on the shapes and the spatial relationship. The active safety module determines environmental data based on the signature, and autonomously control the vehicle based on the environmental data.

Disclosed is a method for resetting the estimated position of a vehicle, including: a step of receiving by a RADAR system a real RADAR image, a step of acquiring an estimated position of the vehicle, a step of calculating by a computer equipping the vehicle a simulated RADAR image, as a function of the estimated position of the vehicle and of a cartographic model of the environment of the vehicle, a step of comparing the real RADAR image and the simulated RADAR image, and a step of correcting the estimated position of the vehicle as a function of the result of the comparison.