Abstract: Systems and methods relating to automated handline of aerial vehicles are disclosed. The described systems and methods can include a plurality of robots operating on a continuous, closed-loop track. A plurality of aerial vehicle handling stations can be disposed along the continuous, closed-loop track, and each of the plurality of robots can engage an aerial vehicles and transport it to the aerial vehicle handling station, as needed, in accordance with a workflow associated with the aerial vehicle. The described systems and methods can provide a fully automated system for the ground handling of multiple aerial vehicles simultaneously.

Abstract: There is provided a method for optically scanning a region according to a plurality of scanning directions, comprising: receiving an interleave sequence defining a scanning order for the plurality of scanning directions; sequentially propagating optical pulses according to the interleave sequence; detecting pulse echoes corresponding to a reflection of the propagated optical pulses on at least one object present within the region; and outputting the detected pulse echoes. There is further described a computer-implemented method for correcting a temporal slippage of an optical echo.

Abstract: Systems and methods for creating electronic indoor maps for emergency services are provided. The system has a processor operatively coupled to at least one storage unit and a communication component, the processor being configured for: receiving a service provider identifier from a computing device of at least one computing device; granting the computing device access to an annotation layer of an electronic map of at least one electronic map based on the service provider identifier; generating at least one annotation in response to receiving at least one selection of a service resource within a facility from the computing device; and storing the at least one annotation in the annotation layer.

Abstract: A method for pushing multimedia information, an electronic device, and a non-transitory computer readable storage medium are provided. The method includes the following. Upon detecting that a vehicle is in a traveling state and the vehicle is traveling at a speed lower than a preset speed threshold within a preset time period, navigation data of the vehicle is provided. Duration that the vehicle is in a congestion state is estimated according to the navigation data. Collect scene information in the vehicle. Push multimedia information according to the duration that the vehicle is in the congestion state and the scene information in the vehicle.

Abstract: Methods and systems are provided for belief space planning for multiple robots at an initial belief state, for reducing belief space uncertainty, including receiving multiple, candidate, multi-robot paths, each including one or more pose constraints; generating a candidate factor graph for each candidate multi-robot path, and generating from each candidate factor graph a topology graph; calculating a signature metric from each topology graph, wherein the signature metric is one of a Von Neumann (VN) metric and a spanning tree (ST) metric; selecting a multi-robot path having the greatest signature metric from among the candidate, multi-robot paths; and instructing the multiple robots to proceed according to the selected multi-robot path.

Abstract: The invention relates to a method for estimating a current wheel circumference of at least one wheel arranged on a vehicle, said method comprising: determining a reference speed of the vehicle at a point in time by means of a reference apparatus, detecting a wheel rotational speed of the at least one wheel at said point in time by means of a wheel rotational speed sensor, estimating a single wheel-circumference value based on the determined reference speed and the detected wheel rotational speed for said point in time by means of a calculation apparatus, storing at least the estimated single wheel-circumference value in a circular buffer for said point in time, estimating a current wheel circumference based on the single wheel-circumference values stored in the circular buffer by the calculation apparatus, outputting the estimated current wheel circumference as a wheel circumference signal.

Abstract: In certain embodiments, a vehicle may obtain a video stream via a camera system of the vehicle. The video stream may be processed to extract one or more feature vectors from the video stream. Based on the feature vectors extracted from the video stream, vehicle description information related to one or more parked vehicles in the parking area may be determined. Space information indicating locations of the parked vehicles relative to available parking spaces in the parking area may also be determined based on the feature vectors extracted from the video stream. A mapping of the parking area may then be generated based on the vehicle description information and the space information.

Abstract: Product transport is facilitated by a processor(s) obtaining data related to a planned transport event, and analyzing the data to predict energy usage of a transport vehicle in performing the planned transport event, including transporting one or more transport containers. The processor(s) determine, based at least in part on the predicted energy usage, an energy source size for a transport container of the transport container(s) to be transported by the transport vehicle, and determine whether the transport vehicle is to proceed with the transport event. The determining whether to proceed is based, at least in part, on the processor(s) determining that an energy source of the determined energy source size is integrated within the transport container, with the integrated energy source being adapted in the container to contribute energy to the transport vehicle when the transport container is positioned within the transport vehicle for transport.

Abstract: The present disclosure provides a method for identifying a confidence level of an autonomous driving system in an autonomous driving vehicle.

Abstract: A method is described for ascertaining particular pieces of status information for at least one geographical position with the aid of autonomous or semi-autonomous vehicles, at least one autonomous or semi-autonomous vehicle detecting pieces of information from its surroundings during a drive with using at least one surroundings sensor and carrying out a planning of its instantaneous travel trajectory based on the obtained pieces of information, and the vehicle detecting additional pieces of information from its surroundings with using its surroundings sensor during a stop, which are not used for planning its instantaneous travel trajectory. The vehicle conveys the ascertained additional pieces of information, with a geographical position at which the additional pieces of information have been detected, to an external server. The external server uses the data received from the vehicle to ascertain at least one piece of status information for the respective geographical position.

Abstract: A distributed integrated sensing and communication (DISC) module for an autonomous vehicle is described herein. The DISC module includes at least a first sensor system, a second sensor system, a processor, and memory. The first sensor system and the second sensor system are different types of sensor systems. The first sensor system outputs a first sensor signal, and the second sensor system outputs a second sensor signal. The DISC module can detect and track an object (or objects) based on the first sensor signal and the second sensor signal. Moreover, the DISC module can output data indicative of the object as detected. In the DISC module, the first sensor system, at least a portion of the second sensor system, the processor, and the memory are integrated on a single substrate.

Abstract: The vehicle includes an operation switch for manually operating the operation state of the accessories. The vehicle control system includes a first controller that performs an evacuation traveling in response to a decrease in the driver's consciousness level, and a second controller that controls an operation state of the accessories based on a request from the first controller or operation information of the operation switch. The first controller is configured to transmit, to the second controller, a specific operation rejection request for performing a specific operation rejection process of rejecting the control of the accessories based on the specific operation of the operation switch in response to a decrease in the driver's consciousness level. The second controller is configured to perform the specific operation rejection process when the specific operation rejection request is received from the first controller.

Abstract: A lawn mower including a housing; a walking mechanism, supporting the housing and driving the housing to move, and including at least one drive wheel; at least one motor to drive the at least one drive wheel to rotate; and a control apparatus, preset with a first and a second torque threshold. And when the motor is switched from a stopped state to a running state, the control apparatus controls a difference between a maximum operating output torque of the motor and the first threshold to be within a predetermined range, when the motor is in the running state, the control apparatus controls an operating output torque of the at least one motor to at most increase to the second threshold, the first threshold is less than or equal to a maximum output torque of the motor, and the second threshold is less than the first threshold.

Abstract: An aircraft landing gear shock absorber assembly having: an outer cylinder having a bore which extends into the outer cylinder, the bore defining an opening in the outer cylinder; a sliding tube having a first end region slidably coupled within the bore and a second end region which projects out of opening; a ground fitting distinct from the sliding tube; and a mechanical fixing arranged to mechanically couple the ground fitting to the second end region of the sliding tube, wherein the sliding tube comprises a tubular body portion formed from a ceramic coated fibre composite tube.

Abstract: An approach is provided for detecting lane-level dangerous slowdown events based on probe data and/or sensor data. The approach, for example, involves splitting probe data, sensor data, or a combination thereof into at least one vehicle trajectory, wherein the data is collected from one or more vehicles traveling on a road segment. For each vehicle trajectory of the at least one vehicle trajectory, the approach also involves processing said each vehicle trajectory to detect a slowdown event based on a speed reduction greater than a threshold reduction. The approach further involves classifying a slowdown event type of the slowdown event based on a final driving location, a final driving speed, or a combination thereof of the at least one vehicle trajectory. The approach further involves providing the slowdown event, the slowdown event type, or a combination thereof as an output for the road segment.

Abstract: In some examples, a vehicle suspension for supporting, at least in part, a sprung mass, includes a damper connected to the sprung mass, the damper including a movable piston. The vehicle suspension further includes an actuator and a controller. The controller may be configured to determine a frequency of motion associated with the sprung mass. When the frequency of motion is below a first frequency threshold, the controller may send a control signal to cause the actuator to apply a deceleration force to the sprung mass. Further, when the frequency of motion associated with the sprung mass exceeds the first frequency threshold, the controller may send a control signal to cause the actuator to apply a compensatory force to the sprung mass. For instance, a magnitude of the compensatory force may be based on a friction force determined for the damper.

Abstract: An autonomous vehicle, system and method of operating an autonomous vehicle. The system includes a communication module and a processor. The communication module sends a first set of Global Positioning Satellite (GPS) data over a first communication channel and a second set of GPS data over a second communication channel. The second set of GPS data is an authenticated data set. The processor operates the autonomous vehicle using the first set of GPS data, and compares the first set of GPS data to the second set of GPS data to verify the integrity of the first set of GPS data. A first value for a vehicle parameter based on the first set of GPS data is compared to a second value for the vehicle parameter based on data from a vehicle-based sensor. The first set of GPS data is rational when the difference is less than a selected threshold.

Abstract: A computer-implemented method of tracking vessel movement which comprises receiving a first vessel data message comprising a first vessel identifier, the first vessel data message having been transmitted at a first time and being associated with a first position; and receiving a second vessel data message comprising a second vessel identifier, the second vessel data message having been transmitted at a second time and being associated with a second position. The method also comprises determining if the first vessel identifier and the second vessel identifier are related. If the first vessel identifier and the second vessel identifier are related, a speed required for a vessel to have moved from the first position to the second position is determined; which is then determined if the speed is below a speed threshold; and if the speed is below the speed threshold, the first position is associated with the second position.

Abstract: The present disclosure relates to a system and method for updating traffic-related infrastructure. The method includes determining average traffic stream speed and average traffic density over a segment of a highway. The method further includes determining, upon analysis of the determined average traffic stream speed and average traffic density over a segment of a highway, an appropriate action in order to update the infrastructure.

Abstract: A method and system for battery management for a mobile geofence apparatus. Location information for a vehicle, temperature information for the vehicle and battery information for the internal battery on the mobile geofence apparatus is automatically, continuously and periodically collected and sent during a connection interval in real-time to an external network server network device via a communications network for tracking the vehicle in real-time. The battery information is displayed on the mobile geofence apparatus for a viewer and is also sent to an external server network device for display to a viewer. Internal battery usage is automatically managed internally on the mobile geofence apparatus using the collected location, battery and temperature information. The internal battery on the mobile geofence apparatus is also automatically managed externally via the external server network device using the collected location, battery and temperature information.