Abstract: An in-vehicle control device includes a first sensor that acquires obstacle information in a first detection range, a second sensor that acquires obstacle information in a second detection range, the second detection range is nearer to a host vehicle than the first detection range, and a processor configured to perform predetermined control for preventing collision with an obstacle or for reducing damage at collision time based on the obstacle information received from the first sensor and the second sensor and, when the obstacle is not detected by the first sensor and the second sensor after starting the predetermined control based on the obstacle information received from the first sensor, uses positional relation information to determine whether the predetermined control is to be continued wherein the positional relation information indicates a height-direction positional relation between a predetermined part of the obstacle and the first detection range or the second detection range.

Abstract: In at least one embodiment, an apparatus includes a controller coupled to a first sensor positioned on a first object external to a vehicle and configured to receive first information indicative of a height of the first object from the first sensor via Bluetooth Low Energy (BLE) and store second information corresponding to a height of the vehicle. The controller is further configured to receive third information corresponding to a height of overhead obstacle positioned external to the vehicle and to compare at least one of the first information and the second information to the third information. The controller is further configured to generate an alert based on the comparison of the at least one of the first information and the second information to the third information.

Abstract: The possibility of a lane change of a vehicle is determined by using a first inter-vehicle distance that serves as a target for the lane change of the vehicle on an adjacent lane adjacent to a lane on which the vehicle is traveling. When the lane change is determined not to be executable, the presence or absence of a possibility that the first inter-vehicle distance will extend to a length that allows for the lane change is determined by using a second inter-vehicle distance positioned in front of or behind the first inter-vehicle distance. When it is determined that there is the possibility, waiting is determined to be necessary, and when it is determined that there is no such possibility, the waiting is determined to be unnecessary.

Abstract: Disclosed is a robotic work tool (100) for use with at least one guiding wire (250; 260) adapted to conduct electric current to generate a magnetic field around the guiding wire. The robotic work tool has a sensing system (510) adapted to detect a strength of the magnetic field, a steering system (540), a controller (530) configured to control the steering system in response to output from the sensing system by means of a feedback control loop (532) so as to cause movement of the robotic work tool along the guiding wire. The controller is configured to determine a measure indicative of a distance between the robotic work tool and the guiding wire, and adjust at least one parameter of the feedback control loop in response to the determined distance measure.

Abstract: A driving assistance apparatus to be mounted on a vehicle includes: an object detecting unit configured to detect an object outside the vehicle and acquire object information including a distance to the object; a vehicle speed detecting unit configured to detect a vehicle speed of the vehicle; and a processing unit configured to carry out driving assistance associated with an object on the basis of the object information when the object has been detected by the object detecting unit, and suppress the driving assistance when a predetermined condition that is changed on the basis of the vehicle speed detected by the vehicle speed detecting unit is satisfied.

Abstract: A vehicle has independent electric traction system (ETS) and internal combustion engine (ICE). A system controller, a data acquisition system, and a GPS system are added to the vehicle. A remote system has a data base of locations identifying emission non-attainment areas. The data acquisition system obtains the vehicle location along with parametric data related to operation of the vehicle. The remote system notifies the vehicle operator and the auxiliary control system of opportunities to obtain emission reduction credits in response to the vehicle location data and its operating status. The system controller or the operator switch between ICE operation and ETS operation in response to the vehicle location, emission reduction credit process, and parametric measurements of the vehicle operation to achieve an emissions credit result while optimizing fuel for the ICE and stored electrical potential energy for the ETS.

Abstract: A via adding method comprising: identifying a target area where a via is to be added in a printed circuit board; determining a starting point for starting a search for a location of the via in the target area; and moving a search point along a path in an intersecting direction that intersects a radial direction around the starting point while moving the search point in the radial direction and determining whether the via is to be added at a moved search point.

Abstract: An around view provision apparatus and a vehicle including the same may include at least one camera mounted on a vehicle, a direction of the at least one camera being adjustable, and a processor to control the at least one camera to capture images around the vehicle based on a movement of the vehicle. The camera may be controlled to operate in a first mode when the vehicle is moving forward at a first prescribed speed or more and in a second mode when the vehicle is moving forward at less than a second prescribed speed or is moving backward. In the first mode, the camera may capture a lateral region that cannot be observed through a side view mirror or a rear view mirror. In the second mode, the camera may capture a larger region that is angled downward relative to the lateral region in the first mode.

Abstract: A vehicle control apparatus that switches an operating condition of a vehicle to a manual operation when the vehicle reaches a preset initial switch position while an automatic operation is underway includes: a driver condition determination unit configured to determine whether or not a driver is in a manual operation acceptance condition; an evacuation space identification unit configured to identify an evacuation space provided on a path of the vehicle before the initial switch position on the basis of map information; and a switch position setting unit configured to set a switch position in which the operating condition of the vehicle is to be switched from the automatic operation to the manual operation, in a position between the vehicle and the evacuation space when the driver is not in the manual operation acceptance condition.

Abstract: A four-wheel-drive vehicle includes a first driving force transmission system and a second driving force transmission system. A control device controls the second driving force transmission system. The control device includes a road surface state determination section that determines whether a coefficient of friction of a road surface is equal to or higher than a predetermined value based on an index value regarding the coefficient of friction of the road surface, controls a dog clutch such that the dog clutch is engaged irrespective of the index value regarding the coefficient of friction of the road surface when an ignition switch is brought into the on-state, and controls the dog clutch such that the dog clutch is brought into the disengaged state when it is determined that the coefficient of friction of the road surface is equal to or higher than the predetermined value.

Abstract: A method for operating a machine on a worksite is disclosed. The method includes detecting a forward worksite condition and a rearward worksite condition relative to the machine, respectively by a first image capturing module and a second image capturing module. Thereafter, the method includes determination of a measure of effect of the machine on the worksite by comparing the rearward worksite condition with the forward worksite condition. The measure of effect is one of a deviation of an actual machine path with a baseline operational path or an impression left by the machine on the worksite. Finally, controlling one or more parameters related to a movement of the machine over the worksite, based on the measure of effect, is carried out.

Abstract: A method of assessing an area for parking a vehicle includes ultrasonically scanning the area to obtain ultrasonic data, radar scanning the area to obtain radar data, and determining whether to park the vehicle in the area based on both the ultrasonic data and the radar data.

Abstract: A border-signal generating and wire winding device for border recognition of a self-propelled mower includes a seat; a reel rotatably installed on the seat; a lever provided at one end of the reel for a user to operate and rotate the reel; two power sockets provided on the seat or on the reel; an electric wire removably wound around the reel and having two plugs at two ends thereof for being detachably plugged into the two power sockets; and a signal-generating module provided on the seat or on the reel and electrically connected to the two power sockets. When the electric wire is connected to the two power sockets through the two plugs, the signal-generating module continuously generates a border signal that is continuously transmitted to the electric wire through the two power sockets.

Abstract: A method of operation of a navigation system includes: receiving an entry for a destination, a sub-destination, or a combination thereof with the sub-destination located within the destination; receiving a road obstacle image while traveling along a route to reach the destination; generating an operation direction based on the road obstacle image; and generating a destination image representing the destination for displaying on a device.

Abstract: Methods, apparatus, systems, and computer-readable media are provided for determining and assigning intermediate handoff checkpoints for low-resolution robot planning. In various implementations, a global path planner may identify a task to be performed by a robot in an environment. In various implementations, the global path planner may determine, based at least in part on one or more attributes of the environment or the task, an intermediate handoff checkpoint for the robot to reach by a scheduled time while the robot performs the task. In various implementations, the global path planner may determine that a measure of reactivity that would be attributable to the robot upon the robot being assigned the intermediate handoff checkpoint satisfies a reactivity threshold. In various implementations, the global path planner may provide, to a local path planner associated with the robot, data indicative of the intermediate handoff checkpoint.

Abstract: A feature for a motor vehicle that takes precautionary actions in response to conditions on the road network in the vicinity ahead of the vehicle. The feature uses a data representation of the road network extending from the current vehicle position out to an extent. The data representation of the road network is used to identify conditions, if any, that warrant taking a precautionary action. The type of conditions about which actions are to be taken may be identified in a data file. A precautionary action is taken as the vehicle approaches the location of the condition. The precautionary action may be a message provided to the vehicle driver to alert the driver about the condition. Alternatively, the action may be a modification of the vehicle operation, such as slowing down or stopping the vehicle, speeding up the vehicle, changing direction, and so on.

Abstract: A driving support device performs collision avoidance support on a vehicle relative to a leading vehicle present in a travelling direction based on a time-to-collision Ta as a time that the vehicle takes to collide with the leading vehicle. A lateral change amount calculation portion detects relative lateral velocity Vy, which is a relative time-dependent change amount between the vehicle and the leading vehicle. A storage portion stores steering time T1, which is a time required for the vehicle to avoid the leading vehicle by steering. The storage portion stores activation threshold TH1, which is a threshold to determine activation of the driving support based on the relative lateral velocity Vy. When a relative lateral velocity Vy at a time when the time-to-collision Ta is the steering time T1 or more is the activation threshold TH1 or more, a support management portion restrains the activation of the driving support.

Abstract: A self-location calculating device projects a patterned light onto a road surface around a vehicle, as well as thereby captures and obtains an image of the road surface around the vehicle. Furthermore, the self-location calculating device detects a running condition of the vehicle. When it is determined that the vehicle is a running stable state, the self-location calculating device calculates a current position and a current attitude angle of the vehicle by adding an amount of change in an attitude to a predetermined initial attitude angle of the vehicle.

Abstract: Geographic location data and telematics data may be collected in real-time by a mobile device within a vehicle, or the vehicle itself. The telematics data may indicate vehicle direction, speed, motion, etc., as well as traffic hazards in the surrounding environment. A remote server may receive the location and telematics data from two vehicles. If an anomalous or hazardous condition exists in the vicinity of the first vehicle, a geographic relationship with the second vehicle is determined, and if within a predetermined distance, an alert or alternate route for the second vehicle is determined and transmitted to the second vehicle. As a result, a negative impact or risk of collision caused by the anomalous condition on the second vehicle is alleviated. The amount of the insured's usage of the telematics data-based risk mitigation or prevision functionality may be used to calculate or adjust insurance premiums, rates, or discounts.

Abstract: A robot cleaner system may include a robot cleaner that may be automatically driven while performing a cleaning operation, a recharging base that receives the robot cleaner, and a remote control device that remotely controls the robot cleaner. The remote control device may also generate mapping information between an actual region and a virtual region based on image information generated by a camera provided on the robot cleaner, and/or image information generated by a camera on the recharging base.

Abstract: A system and method are provided for operating an adaptive cruise control system of a host vehicle. The method includes receiving data measured from a plurality of sensors, wherein the measured data relates to one or more target vehicles in the host vehicle's field of view. The method further includes generating a following score for each target vehicle based on the measured data and controlling the host vehicle response based on the following score.

Abstract: An operation unintended by a helper due to an incorrect operation or the like by an operator is prevented. An electric mobility includes a manual operation unit, a wireless operation unit, and a control unit that controls a driving wheel on the basis of either a first command signal output by the manual operation unit or a second command signal output by the wireless operation unit. The control unit sets a first control mode enabling an operation of the electric driving wheel by the manual operation unit and a second control mode disabling an operation of the electric driving wheel by the manual operation unit on the basis of a wireless signal transmitted from a wireless terminal.

Abstract: A vehicle configured to operate in an autonomous mode is provided. The vehicle is configured to obtain an indication of a final destination, and, if the final destination is not on a pre-approved road for travel by the vehicle, the vehicle is configured to determine a route from the vehicle's current location to an intermediary destination. The vehicle is further configured to determine a means for the vehicle user to reach the final destination from the intermediate destination.

Abstract: An image processing apparatus includes: an image color determination unit configured to determine color of overlay image data to be superimposed on captured image data of successive frames generated by capturing surroundings of a vehicle such that a first color of overlay image data of a first frame differs from a second color of the overlay image data of a second frame following the first frame; and an image synthesizing unit configured to superimpose the overlay image data in the first color and the overlay image data in the second color respectively on predetermined positions in the captured image data of the first frame and the second frame, and output images corresponding to the captured image data of the successive frames one after another to a display. Thereby, an overlay image that is easily visible regardless of background color and driver's color vision is superimposed on a captured image.

Abstract: A viewing system for a vehicle, in particular a commercial vehicle, includes an image capture unit, a computing unit, and a reproducing unit. The image capture unit includes a lens, which has an optical axis, and a digital image sensing unit, and is configured to be attached to the vehicle such that a viewing area on the side of the vehicle is sensed with at least one part of a first legally-prescribed field of view and with at least one part of a second legally-prescribed field of view. The lens is disposed with respect to the digital image sensing unit such that the optical axis extends through the part of the first legally-prescribed field of view that is reproduced on the digital image sensing unit.

Abstract: A system is provided for enhancing inertial sensing within a vehicle. The system determines measured rotational rates and translational accelerations of the vehicle using an inertial measurement unit. In addition, the system also determines estimated rotational rates and translational accelerations of the vehicle based on a remote sensing system. The system generates compensated rotational rates and translational accelerations to reduce gain errors or offset errors of the inertial measurement unit based on the estimated rotational rates and translational accelerations.

Abstract: An automatic braking system for a vehicle includes an electronic brake system capable of applying wheel brakes to decelerate the vehicle and a controller. The controller includes instructions for detecting an object proximate to a vehicle with at least one sensor for a reverse collision avoidance system and determining a collision confidence value based upon the probability of collision with the object. The controller further includes instructions for determining a desired velocity profile of the vehicle that provides for deceleration of the vehicle.

Abstract: Systems and techniques are disclosed for switching a vehicle driving mode. A sensing unit senses a state of a driver of a vehicle configured to be driven automatically or manually. An intention detecting unit detects whether the driver intends to switch from an automatic driving mode to a manual driving mode based on the state of the driver. An operation detecting unit detects whether the driver is able to operate the vehicle in the manual driving mode based on the state of the driver. A driving state predicting unit predicts a driving state of the vehicle in the manual driving mode based on detecting that the driver is able to operate the vehicle in the manual driving mode. A control unit determines that the predicted driving state of the vehicle meets a preset condition and switches from the automatic to the manual driving mode.

Abstract: A method and system for auto safety verification of automatic guided vehicle (AGV) sensors is presented. An auto safety verification test can be performed autonomously by the AGV to ensure that sensors on the AGV are configured correctly and working properly. The auto safety verification test avoids human errors that exist in manual verification tests and significantly reduces the amount of time required to verify sensors on the AGV.

Abstract: A parking support device 1 includes a calculation unit 17 that calculates a speed pattern, an acceleration recognition unit 13 that recognizes driver-requested acceleration, a parking support control unit 19 that performs parking support control in a target parking position based on the speed pattern, and a determination unit 18 that determines whether a host vehicle V can stop in the target parking position at a set deceleration. When the driver-requested acceleration is recognized during the control and exceeds acceleration of the speed pattern at the time of recognition, the parking support control unit 19 accelerates the host vehicle V at the driver-requested acceleration. When the determination unit 18 determines that the host vehicle V can stop in the target parking position at the set deceleration, the host vehicle V is decelerated at the set deceleration and is stopped in the target parking position regardless of the driver-requested acceleration.

Abstract: Aspects of the invention relate generally to autonomous vehicles. The features described improve the safety, use, driver experience, and performance of these vehicles by using ground markers to determine the position of the surrounding objects. In particular, the autonomous vehicle is capable of detecting nearby objects, such as vehicles and pedestrians, and is able to determine the position of these objects based on whether they have passed over ground markers.

Abstract: A method for operating a self-propelled mobile platform includes reducing a speed of the mobile platform as a function of a distance between the mobile platform and obstacles situated along a travel route of the mobile platform. The mobile platform includes at least one first sensor configured to detect obstacles in surroundings of the mobile platform.

Abstract: A method for adapting an upper headlight beam boundary of a light cone of at least one headlight of a vehicle includes reading in at least one configuration position of an illumination unit on another vehicle and/or of a vehicle contour of the other vehicle to provide an identification signal of the other vehicle. In addition, the method includes ascertaining the type of the other vehicle, using the identification signal of the other vehicle, and outputting a control signal for adapting the upper headlight beam boundary, the control signal being output taking the ascertained type of vehicle into account.

Abstract: The claimed subject matter provides a method for navigating to dynamic destinations. The method includes associating a leader mobile device with a follower mobile device. The method also includes displaying, on the follower mobile device, a first path from a follower vehicle to a first location of a leader vehicle. The follower vehicle is associated with the follower mobile device. The leader vehicle is associated with the leader mobile device. The method further includes displaying, on the follower mobile device, a second path from the follower vehicle to a second location of the leader vehicle.

Abstract: A system, an apparatus or a process may be configured to implement an application that applies artificial intelligence and/or machine-learning techniques to predict an optimal course of action (or a subset of courses of action) for an autonomous vehicle system (e.g., one or more of a planner of an autonomous vehicle, a simulator, or a teleoperator) to undertake based on suboptimal autonomous vehicle performance and/or changes in detected sensor data (e.g., new buildings, landmarks, potholes, etc.). The application may determine a subset of trajectories based on a number of decisions and interactions when resolving an anomaly due to an event or condition. The application may use aggregated sensor data from multiple autonomous vehicles to assist in identifying events or conditions that might affect travel (e.g., using semantic scene classification). An optimal subset of trajectories may be formed based on recommendations responsive to semantic changes (e.g., road construction).

Abstract: A method and system for determining and verifying a location of a network device of an automated vehicle (i.e., driverless, etc.) and/or an occupant of an automated vehicle in emergency situations from automated vehicles. The method and system provide a current physical geographic location for the automated vehicle or mobile devices of an occupant and/or of occupant of an automated vehicle in an emergency situation such as an accident, health, fire, terrorist attack, military incident, weather, flood event, etc. and forwarding the current physical geographic location to a legacy 911 network, a Emergency Services IP networks (ESInet) or text-to-911 Short Message Services (SMS) networks to alert emergency responders.

Abstract: Systems and methods implemented in algorithms, software, firmware, logic, or circuitry may be configured to process data and sensory input to determine whether an object external to an autonomous vehicle (e.g., another vehicle, a pedestrian, road debris, a bicyclist, etc.) may be a potential collision threat to the autonomous vehicle. The autonomous vehicle may be configured to implement active safety measures to avoid the potential collision and/or mitigate the impact of an actual collision to passengers in the autonomous vehicle and/or to the autonomous vehicle itself. Interior safety systems, exterior safety systems, a drive system or some combination of those systems may be activated to implement active safety measures in the autonomous vehicle.

Abstract: A method and apparatus are provided for determining whether a driving environment has changed relative to previously stored information about the driving environment. The apparatus may include an autonomous driving computer system configured to detect one or more vehicles in the driving environment, and determine corresponding trajectories for those detected vehicles. The autonomous driving computer system may then compare the determined trajectories to an expected trajectory of a hypothetical vehicle in the driving environment. Based on the comparison, the autonomous driving computer system may determine whether the driving environment has changed and/or a probability that the driving environment has changed, relative to the previously stored information about the driving environment.

Abstract: Methods for providing a highly assisted driving (HAD) service include: (a) transmitting telematics sensor data from a vehicle to a remote first server; (b) transmitting at least a portion of the telematics sensor data from the remote first server to a remote second server, wherein the remote second server is configured to execute a HAD application using received telematics sensor data, and wherein the HAD application is configured to output a HAD service result; and (c) transmitting the HAD service result from the remote second server to a client. Apparatuses for providing a HAD service are described.

Abstract: Systems and methods relating to the operation of an autonomous vehicle relative to forward objects in an external environment are described. At least a forward portion of the external environment can be sensed to detect an object therein. A size adjustment factor can be determined to predict a laterally innermost point of the detected object relative to the autonomous vehicle. A driving maneuver for the autonomous vehicle can be determined based at least partially on the predicted laterally innermost point of the detected object relative to the autonomous vehicle.

Abstract: An autonomous control system for a vehicle that controls the speed and steering system of the vehicle to operate in a lane-keeping mode or a lane-changing mode. Position sensors sense the location of surrounding vehicles. A lane determining system identifies a current lane where the vehicle is located. A source of oncoming lane course data provides information as to the course of the current lane. A controller provides instructions to the steering system and speed control system to maneuver the vehicle in either the lane-keeping mode or the lane-changing mode. The driver may override the control system by providing a manual input to the steering system or the speed control system.

Abstract: In accordance with aspects of the present invention, a service robot, such as a robotic cleaner, can be configured to more effectively service an environment. The service robot can include one or more sensors that sense its location, the location of objects, or both, and can also include noise reduction elements. The service robot can determine that it is under a “furnishing” and implement a different servicing pattern.

Abstract: In a vehicle control device that is configured to be capable of switching from an automatic travel of the vehicle to manual travel by a driver, a manual driving adaptation degree of a driver during an automatic travel is calculated based on a driver state (S16), a notification timing is set such that the notification timing is earlier as the manual driving adaptation degree becomes lower (S18), and the automatic travel end notification is given to the driver at the set notification timing (S20).

Abstract: A system and method for operating a machine is disclosed. The system may include an input device configured to select from a plurality of modes of operation for the machine, the plurality of modes of operation comprising a manual mode, a remote mode, and an autonomous mode. The system may further include a controller coupled to the machine, the controller configured to place the machine in the selected mode of operation based on an input at the input device. The system may further include a transmitter configured to transmit a heartbeat signal. The system may further include a receiver configured to receive an acknowledgment signal from a remote system in response to the transmitted heartbeat signal.

Abstract: An imaging system of a vehicle is provided herein. A camera is configured to capture images of a rear vehicle scene containing a trailer attached to the vehicle. A device is configured to remove contaminants on a lens of the camera. A controller is configured to analyze the captured images and activate the device based on the image quality of the captured images and a motion of the trailer relative to the vehicle.

Abstract: Methods, systems, and apparatus, including computer programs encoded on computer storage media, for unmanned aerial vehicle authorization and geofence envelope determination. One of the methods includes determining, by an electronic system in an Unmanned Aerial Vehicle (UAV), an estimated fuel remaining in the UAV. An estimated fuel consumption of the UAV is determined. Estimated information associated with wind affecting the UAV is determined using information obtained from sensors included in the UAV. Estimated flights times remaining for a current path, and one or more alternative flight paths, are determined using the determined estimated fuel remaining, determined estimated fuel consumption, determined information associated wind, and information describing each flight path. In response to the electronic system determining that the estimated fuel remaining, after completion of the current flight path, would be below a first threshold, an alternative flight path is selected.

Abstract: A method comprising receiving map data that is associated with a location of an autonomous vehicle, determining an operational state of the autonomous vehicle, determining that the map data and the operational state satisfy a local assistance request criteria, and causing rendering of a local assistance request based, at least in part, on the determination that the map data and the operational state satisfy the local assistance request criteria is disclosed.

Abstract: A tele-presence system that includes a cart. The cart includes a robot face that has a robot monitor, a robot camera, a robot speaker, a robot microphone, and an overhead camera. The system also includes a remote station that is coupled to the robot face and the overhead camera. The remote station includes a station monitor, a station camera, a station speaker and a station microphone. The remote station can display video images captured by the robot camera and/or overhead camera. By way of example, the cart can be used in an operating room, wherein the overhead camera can be placed in a sterile field and the robot face can be used in a non-sterile field. The user at the remote station can conduct a teleconference through the robot face and also obtain a view of a medical procedure through the overhead camera.

Abstract: A method has steps for dividing a controlled roadway into virtual moving packets with characteristics of being spaced apart by a specific distance and moving at a controlled speed on the roadway, by a master computer coupled to sensors and actuators of the controlled roadway, managing vehicles traveling on the controlled roadway to enter, leave and occupy individual ones of the virtual packets, through communication by the master computer with on-board computers in individual ones of the vehicles, and adjusting virtual packet size and spacing during operation, causing vehicles occupying the spaces of the virtual packets to readjust position relative to one another according to the size and spacing adjustment of the packets by the master computer.

Abstract: A remote controller enables a user to manipulate behavior of a robot so that the robot does not stray away from a given area and also avoids contact with an object. If a route designated by the user satisfies a stable movement requirement, a first command signal is transmitted from the remote controller to the robot. By doing so, it is possible to move the robot according to the designated route. On the other hand, if the route designated by the user does not satisfy the stable movement requirement, the first command signal is not transmitted from the remote controller to the robot. Therefore, it is possible to stop the robot from moving according to the designated route, and further to avoid the situation where the robot strays away from the designated region, or comes into contact with the object.