Abstract: An example system includes a vehicle and a sensor connected to the vehicle. The system may receive a predetermined path for the vehicle to follow. The system may also receive a plurality of objectives, associated with a corresponding set of sensor data, for which to collect sensor data. The system may determine, for each of the plurality of objectives, a portion of the environment for the sensor to scan to acquire the corresponding set of sensor data. The system may determine, based on the portion of the environment determined for each of the plurality of objectives, a sensor trajectory through which to move the sensor. The system may cause the sensor to move through the determined sensor trajectory and scan portions of the environment corresponding to the determined sensor trajectory as the vehicle moves along the predetermined path.

Abstract: A method and device for ascertaining movement authority for track-bound vehicles allow interference with a driving operation resulting in special operational situations or disturbances to be kept as low as possible. The position of the vehicle is determined and used to check whether the vehicle is located completely in an axle-counting section of an axle-counting system. The number of axles of the vehicle is compared with the number of axles located in the relevant section according to the system. If the vehicle is located completely in the relevant section and the number of axles of the vehicle matches the number of axles located in the section according to the system, a movement authority is ascertained for the vehicle. The part of the relevant section in front of the vehicle in the driving direction is assumed to be free of other vehicles when ascertaining the movement authority.

Abstract: The present application generally relates to a method and apparatus for autonomous vehicle driver confirmation in a motor vehicle. In particular, the system is operative to determine a situation wherein driver confirmation is desired, acoustically request driver confirmation via vehicle speakers, and receive verbal driver confirmation via vehicle microphones.

Abstract: An exhaust gas sensor is diagnosed with high accuracy as much as possible while maintaining the function of an exhaust system of an internal combustion engine. In a diagnostic apparatus for an exhaust gas sensor which is applied to an internal combustion engine including an exhaust gas sensor, a fuel supplier, a controller configured to carry out predetermined fuel supply processing and predetermined oxygen concentration processing, and which diagnoses the exhaust gas sensor based on an output value thereof, provision is made for the controller that sets as a diagnostic output value a first output value, which is an output value at the side of the highest oxygen concentration in the output value of the exhaust gas sensor in a measurement period, and performs the diagnosis of the exhaust gas sensor based on the diagnostic output value, when predetermined fuel supply processing is carried out in the measurement period.

Abstract: A vehicle includes: a frame, a rotatable door; an inhibitor comprising: an arm extending through a selective gate including: upper and lower springs respectively biasing upper and lower rollers against the arm; upper and lower stoppers configured to, upon activation, compress the upper and lower rollers against the arm, thus stopping rotation of the door; sensors, processor(s) configured to: activate and deactivate the stoppers based on sensed events.

Abstract: A programmable buoy system having one or more buoys capable of connecting through the Internet to a buoy command server. The buoy command server relays commands to each of the one or more buoys in response to user commands sent from a buoys command interface application on a mobile device. The programmable buoy system includes one or more buoys each having a hull with two or more pontoons where the hull has a top side and bottom side. A stationary rudder extends downward from the bottom side of the hull to be positioned in a body of water when the one or more buoys are in use. A motor is pivotably connected on each one or more buoys, wherein the motor has a propeller positioned away from the bottom side of the hull. The propeller and motor move the select one of the one or more buoys in the body of water.

Abstract: A method for determining a safety-critical yawing motion of a vehicle includes comparing a specification signal representing an ascertained setpoint yaw rate of the vehicle for an anticipated trajectory of the vehicle to a measuring signal representing an instantaneous yaw rate of the vehicle measured based on an actual trajectory of the vehicle, thereby generating a comparison signal; checking whether an amplitude of the comparison signal exceeds a first threshold value and whether a frequency of the comparison signal exceeds a second threshold value; and, in response to the amplitude exceeding the first threshold and the frequency exceeding the second threshold, outputting a yawing-motion signal indicating presence of the safety-critical yawing motion of the vehicle.

Abstract: Methods, devices and apparatuses pertaining to U-turn assistance. The method may include receiving, by a computing device, vehicle information associated with a vehicle from a plurality of sensors that are placed on a plurality of locations of the vehicle and obtaining a length and a width of the vehicle based on the received vehicle information. The computing device may calculate a turning radius of the vehicle, and provide a recommendation for routing the vehicle based at least in part on the turning radius.

Abstract: There is provided a traveling control system. The traveling control system includes a first acquisition unit configured to acquire peripheral information of a self-vehicle, a second acquisition unit configured to acquire predetermined road information, a specifying unit configured to specify, based on the peripheral information acquired by the first acquisition unit, a width of a road on which the self-vehicle travels, and a control unit configured to perform traveling control based on a smaller one of a width of a road indicated by the road information acquired by the second acquisition unit and the width of the road specified by the specifying unit.

Abstract: An abnormal travel detecting device includes a traffic data acquiring receiver configured to acquire traffic data indicating a traffic state of a road measured by a traffic state measuring device that is installed on the road and measures the traffic state of the road. The abnormal travel detecting device includes a measured value receiver configured to acquire a measured value indicating a behavior of a vehicle measured by a behavior measuring device that is mounted on the vehicle and measures the behavior of the vehicle, and a detector configured to detect, based on the traffic data and the measured values, abnormal travel of a vehicle.

Abstract: This invention relates to an apparatus and system for acquiring non-standard PID corresponding to non-standard operation of a vehicle by using selection input of a user received through a user terminal and OBD data collected from an OBD (On Board Diagnostics) terminal in a vehicle, and the method thereof, and non-standard PID of non-standard operation of a vehicle may be acquired through simple operation of a user terminal regardless of types of vehicles.

Abstract: The present disclosure describes a system and method for the use of unmanned aircraft systems to detect, locate, and identify objects in, on, or near the water that may provide useful information to people in a different location, such as on a nearby vessel for purposes of ultimately locating fish. The vessel can then take action based on data collected by the unmanned aircraft system, such as move to a new location to catch fish as detected by the unmanned aircraft system.

Abstract: Autonomous vehicles may be dynamically directed to rendezvous with autonomous vehicle trains or convoys. Current location and/or route information of the Autonomous Vehicle Train (AVT) may be received by an autonomous vehicle. The autonomous vehicle may compare its current location and/or route information to determine a rendezvous point with the AVT. The autonomous vehicle may route itself to the rendezvous point with the AVT. Once there, the autonomous vehicle may verify the identification of the AVT, such as by using sensors/cameras to verifying a lead vehicle of the AVT (e.g., by verifying make/model, color, and/or license plate). The autonomous vehicle and lead vehicle may communicate to allow the autonomous vehicle to join the AVT. A minimum level of autonomous vehicle functionality may be verified prior to the autonomous vehicle being allowed to join the AVT. As a result, vehicle traffic flow and travel experience by passengers may be enhanced.

Abstract: A method and an arrangement for control of the speed of a baler includes detection and mapping of one or more of a crop property and data derived therefrom during the harvesting of a field by a combine harvester. Crop residues are deposited in a windrow in the field. The method and arrangement control the speed of the baler in the pickup of the windrow while taking into account one or more of the mapped crop property and the data derived from the crop property.

Abstract: An intelligent ultrasonic system may include: a camera sensor unit configured to take an image of a road ahead of a driving vehicle; an ultrasonic signal input unit configured to receive an ultrasonic signal sensed through one or more ultrasonic sensors mounted on the vehicle; a feature extraction unit configured to extract a feature of the received ultrasonic signal; a data collision unit configured to collect one or more data related to a surrounding situation of the road on which the vehicle is driven; and a control unit configured to divide the surrounding situation into two or more classes based on the one or more data collected through the data collection unit, and change or reset an existing parameter to a parameter corresponding to any one class of the classes when the surrounding situation corresponds to the one class or is changed to the one class.

Abstract: A rotor-based remote flying vehicle platform includes a vehicle body. The vehicle body includes a processing unit that receives positional sensor data and provides flight controls based upon the received positional sensor data. The vehicle body also includes a first frame connection interface that is configured to interface with a plurality of different arm types. The first frame connection interface comprises a physical connection and an electronic connection. Additionally, the rotor-based remote flying vehicle platform includes a first arm, of a rotor-based remote flying vehicle platform, that is selectively connectable to the vehicle body through the first frame connection interface. The first arm comprises a first arm connection interface that is selectively connectable to the first frame connection interface. Additionally, the first arm comprises a first motor mounted to the first arm.

Abstract: An advanced driver assistance system designed to receive and process motor-vehicle position-related data and motor-vehicle motion-related data of a host motor vehicle and of neighbour motor vehicles detected in the vicinity of the host motor vehicle and which have been determined as entering the same roundabout in which the host motor vehicle will enter, to provide assistance to the driver of the host motor vehicle for negotiating the roundabout. A degree of proximity of the host motor vehicle and the neighbour motor vehicle to the roundabout based on motor-vehicle position-related data is determined and a determined alert level is provided the driver.

Abstract: A method for updating an electronic card in a vehicle based on a deviation between predicted states and actual states comprises calculating a predicted state of the vehicle, establishing an actual state of the vehicle, determining a deviation between the predicted state and the actual state, and storing information in the map if the predicted state and the actual state deviate from one another.

Abstract: A controller is configured to control a system by generating a control input to an actuator changing a state of the system in accordance with the control input. The controller includes an interface configured to receive data indicative of dynamic response of the actuator and a tuner configured to determine the maximum rate of change of the control input during a control cycle using the received data indicative of dynamic response of the actuator. The controller also includes a receiver configured to receive measurements of the state of the system and a solver configured to determine a current value of the control input for controlling the controlled system based on the state of the controlled system subject to constraints on operation of the system and a constraint on the maximum rate of change of the control input, and to cause the actuator to change the state of the system according to the current value of the control input.

Abstract: An awakening support apparatus includes an acquisition portion acquiring surroundings information which indicates information of at least one of a temperature and a vibration around a driver of a movable object, a determination portion determining a drowsiness inducing level of the driver based on the surroundings information acquired by the acquisition portion, and an execution portion executing an awakening support for decreasing a possibility of induction of drowsiness of the driver based on a determination result of the drowsiness inducing level determined by the determination portion.