Abstract: Apparatuses, storage media and methods associated with computer assisted driving (CAD), are disclosed herein. In some embodiments, an apparatus includes an autopilot engine to automatically pilot the vehicle out of a potential emergency situation, including to automatically pilot the vehicle for a period of time in view of a plurality of operational guardrails determined in real time for each of a plurality of timing windows; and a mitigation unit to conditionally activate the autopilot engine, including to activate the autopilot engine in response to analysis results indicative of the vehicle being potentially operated into the emergency situation manually. Other embodiments are also described and claimed.

Abstract: The above measurement device acquires output data from a sensor unit for detecting surrounding feature, and extracts, from the output data, data corresponding to detection result in a predetermined range in a predetermined positional relation with an own position. The predetermined range is determined in accordance with accuracy of the own position. Then, the measurement device executes predetermined processing based on the extracted data.

Abstract: The present invention provides a technique to accurately recognize a position of a vehicle even in a vicinity of a branch road or a junction road, neither of which is included in map data. The present invention provides a vehicle control device. When a vehicle is traveling on a road that is not described in map data, the vehicle control device is configured to determine whether or not the vehicle is traveling on a junction road or a branch road, based on a positional relationship between a position of the vehicle and a starting point of the junction road or a starting point of the branch road.

Abstract: Embodiments of the present disclosure provide a method and apparatus for generating information. A method may include: determining, according to received positioning request information, visiting information for a target area of interest, the visiting information including location information of at least one visiting point; determining, according to the location information of the at least one visiting point, a visiting point distribution map including the at least one visiting point; performing grid division on the visiting point distribution map, to obtain a first grid map including at least one grid; and generating, based on the first grid map, outline information for the target area of interest.

Abstract: Embodiments herein are directed to a wheelchair system that includes a wheelchair. The wheelchair includes a coupling mechanism, a processing device, and a non-transitory, processor-readable storage medium in communication with the processing device. The non-transitory, processor-readable storage medium includes one or more programming instructions that, when executed, cause the processing device to determine the location of an accessory, position the wheelchair with respect to the accessory, and couple the wheelchair to the accessory via the coupling mechanism. The positioning of the wheelchair is independent from a user physically controlling the positioning of the wheelchair with respect to the accessory.

Abstract: Disclosed subject matter relates to field of vehicle navigation system that performs a method of generating trajectory for navigating an autonomous vehicle. A trajectory generating system associated with autonomous vehicle detects Points of Interest (POIs) for a selected segment which is at predefined distance from current position of autonomous vehicle, in real-time. Further, features of each of the POIs are determined and first level trajectory is generated for selected segment based on features of POIs proximal to selected segment. Furthermore, the trajectory generating system generates second level trajectory for portions of first level trajectory from current position of autonomous vehicle by modifying each portion based on real-time environment data.

Abstract: A plurality of instances of probe data are received and used to generate a plurality of probe trajectories. A set of selected probe trajectories is defined using spatial familiarity sampling wherein a familiarity score is determined for each instance of probe data of a probe trajectory based on a familiarity model corresponding to already selected probe trajectories. A least familiar familiarity score for a probe trajectory is identified from the familiarity scores determined for the probe trajectory and a determination of whether the probe trajectory is included in the set of selected probe trajectories is performed based on the least familiar familiarity score for the probe trajectory. Only the probe trajectories of the set of selected probe trajectories are map-matched. The map-matched probe trajectories are then used to generate traffic and/or map information/data which is provided to consumer apparatuses for use in performing navigation functions, for example.

Abstract: Methods and systems for controlling a vehicle. The system includes a localization system, a memory storing a digital map, and an electronic processor. The electronic processor is configured to receive, from the localization system, a current location of the vehicle and determine a future driving segment of the vehicle based on the current location of the vehicle. The electronic processor is further configured to determine at least one performance limitation based on the future driving segment of the vehicle and modify a driving behavior of the vehicle based upon the determined at least one performance limitation.

Abstract: A tangible, non-transitory machine-readable medium includes machine-readable instructions that, when executed by one or more processors, cause the one or more processors to receive historical driver data indicative of one or more physiological parameters of one or more drivers during one or more prior driving trips, receive historical position data indicative of a respective position of a respective vehicle driven by the one or more drivers during the one or more prior driving trips, establish a correlation between the historical driver data and the historical position data, and identify one or more low-stress road segments using the correlation between the historical driver data and the historical position data.

Abstract: The present disclosure relates to a vehicle state control apparatus, a vehicle state control method, and a vehicle that make it possible to perform driving assistant in a drive-through area. In the drive-through area, a display unit, a window control unit, and the like in addition to a steering mechanism, a braking device, an engine, a driving motor, and a headlamp (not shown) are appropriately controlled on the basis of a result of image recognition output from an MCU to a bus, information supplied from another unit such as a radar and a lidar, and a sensing result from an in-vehicle sensor. That is, in the drive-through area, the state of the vehicle, which includes operations (such as presentation and opening/closing of the window) in addition to driving (travelling), is controlled. The present disclosure is applicable to, for example, a drive-through area drive control system.

Abstract: A mobile robot is configured for operation in a commercial or industrial setting, such as an office building or retail store. The mobile robot can have a motorized base and a robot body on the motorized base, the robot body including a rotatable ring that rotates horizontally around the robot body. A mechanical arm that can contract and extend relative to the robot body is coupled to the rotatable ring and performs a plurality of actions. A controller of the mobile robot provides instructions to the rotatable ring and the mechanical arm and can cause the mechanical arm to open a door, take an elevator to move to a different floor, and test whether a door is locked properly.

Abstract: Resolving an exception situation in autonomous driving includes receiving an assistance request to resolve the exception situation from an autonomous vehicle (AV); identifying a solution to the exception situation; forwarding the solution to a tele-operator; receiving a request for playback data from the tele-operator; receiving, from the AV, the playback data; and obtaining, from the tele-operator, a validated solution based on the tele-operator using the playback data. The playback data includes snapshots ni of data related to autonomous driving stored at the AV at respective consecutive times ti, for i=1, . . . , N.

Abstract: A tracking vehicle control system includes a drive section, a drive control section, a recognition section, a first judgement section, and a second judgement section. After the drive control section controls the drive section to get a tracking vehicle to track a tracking object according to a result of recognition of the tracking object performed by the recognition section, the drive control section controls the drive section to stop the tracking vehicle from tracking the tracking object when the first judgement section judges that the tracking object has started access to the tracking vehicle. The drive control section controls the drive section to get the tracking vehicle to restart tracking the tracking object when the second judgement section judges that the tracking object has ended access to the tracking vehicle. The recognition section recognizes the tracking object even when tracking of the tracking object by the tracking vehicle is suspended.

Abstract: Detecting potential safety issues is provided. An image is received from an imaging device located on a vehicle. The image is analyzed to identify an object. The object identified in the image is compared with images of objects stored in a database to determine a potential safety issue associated with the object. A set of protective roadway barriers is identified in an area of the vehicle and the object. An adjustment to operation of the vehicle is calculated based on the potential safety issue and the set of protective roadway barriers. The operation of the vehicle is adjusted based on the calculated adjustment.

Abstract: Methods and systems are provided for a vehicle speed limiter. In one example, a method may include decreasing a vehicle top speed in response to the vehicle being arranged in a geofenced area via the vehicle speed limiter. In at least one example, adjusting a magnitude of the vehicle top speed limiter to decrease a limiting of the vehicle top speed may be in response to an override request, where the override request is signaled via one or more of depression of a pedal of the vehicle in a pattern and a siren of the vehicle being activated. Further, in one or more examples, the vehicle may be the only vehicle of a plurality of vehicles comprising one or more of a solar cell and a wireless modem.

Abstract: A manual steering command value generation unit generates a manual steering command value using steering torque. An integrated angle command value computation unit computes an integrated angle command value by adding the manual steering command value to an automatic steering command value. A control unit performs angle control on an electric motor on the basis of the integrated angle command value. The control unit includes: a basic torque command value computation unit that computes a basic torque command value on the basis of the integrated angle command value; a disturbance torque estimation unit that estimates disturbance torque other than motor torque that is generated by the electric motor and acts on an object to be driven by the electric motor; and a disturbance torque compensation unit that corrects the basic torque command value in accordance with the disturbance torque.

Abstract: Provided are embodiments drone flight optimization using drone to drone permissioning. The embodiments include determining a potential route for a first drone, and broadcasting the potential route to one or more drones of a network of drones. The embodiments also include receiving path information and routing condition information associated with the potential route from the one or more drones of the network of drones, and updating the potential route of the first drone based at least in part on the path information and routing condition information.

Abstract: A method for synchronizing movement of transport vehicles in a storage facility is provided. A server determines first and second paths in the storage facility to be traversed by first and second transport vehicles, respectively. The server identifies a common path that corresponds to an overlap between the first and second paths. The server determines a safe distance to be maintained between the first and second transport vehicles, for avoiding a collision therebetween, when the first and second transport vehicles traverse the common path in the same direction. The server communicates a message, indicative of the safe distance, to the second transport vehicle for synchronizing movement of the first and second transport vehicles. Based on the message, the second transport vehicle follows the first transport vehicle along the common path and maintains a distance greater than or equal to the safe distance from the first transport vehicle.

Abstract: An aircraft management system includes a sensor, a diagnosis executor, and an outputter. The sensor is loaded onto an aircraft. The diagnosis executor diagnoses health of a part of the aircraft on the basis of output from the sensor while the aircraft is flying. The outputter outputs predetermined recommendation information to an outside of the aircraft through wireless communication, in the case where the part satisfies a preset maintenance recommendation condition as a result of the diagnosis of the health.

Abstract: The invention is provided with: a turning determination unit 13 and an image reproducing unit 14. The turning determination unit 13 determines a section in which an automobile travels with turning, not travels straight, based on road-route information regarding a traveling route and a road on the traveling route. The image reproducing unit 14 displays a selected-virtual space image that is selected in advance in a straight section in which the automobile travels straight, and displays a turning-virtual space image for a view field turning in accordance with a turning pattern determined by a road shape and a traveling direction in a turning section, in the turning section in which the automobile travels with turning.