Abstract: According to an embodiment, an ADV includes a method to plan a path. The method selects a plurality of discrete points of a path to determine the obstacle cost for the path. For the discrete points that do not overlap with an obstacle, the method accumulates an obstacle cost of the path using a first cost function starting from the initial discrete point through the discrete points that are successively further away from the initial point until a first discrete point is determined to overlap with an obstacle. The method calculates an overlapping obstacle cost for the first discrete point using a second cost function. The second cost function is based on a distance of the first discrete point from the initial point of the path. The method accumulates the overlapping obstacle cost to the obstacle cost to determine the obstacle cost for the path that overlaps with an obstacle.

Abstract: A driver authentication and safety system and method for monitoring and controlling vehicle usage by high-risk drivers. A centralized database comprising a software application can be accessed by an authorized user via a data communications network utilizing a remote computer in order to configure a desired operating profile that matches requirements of the high-risk driver. The operating profile can be loaded to a driver identification and data logging module in conjunction with the remote computer. A master control unit receives a unique identification code from the data logging device to authenticate the high-risk driver and to operate the vehicle within the desired operating profile. A slave control unit receives commands from the master control unit and generates a real time alarm signal if the driver violates the preprogrammed operating profile unique to the driver.

Abstract: The present invention relates to a traffic collision warning device comprising: a main circuit board (11); a central processing unit (12) being mounted on the main circuit board (11) and controlling the operation of the device; a memory (111); a warning signal generator (18); sensors (c1, c2, c3, c4, c1?, c2?, c3?, c4?) being arranged along the road near a collision-prone area; a vehicle identification module; timers (tm, tm?); vehicle counters (n, n?); and a movement direction comparison module. Wherein, the direction of movement of a vehicle is identified based on the order in which it passes through the sensors, the vehicle velocity is calculated by dividing the distance between the two sensors by the period of time it takes the vehicle to pass through the two sensors; the vehicle length is calculated by multiply the vehicle velocity and the period of time it takes the vehicle to pass through a sensor.

Abstract: A computer-implemented method, computer program product and computing system for receiving a current operating value concerning an operating condition of an aircraft; rendering the current operating value within a magnified operating window of a glass cockpit of the aircraft; and locating the magnified operating window along a fixed range of operating values for the aircraft based, at least in part, upon the current operating value.

Abstract: Systems and methods are disclosed for determining a navigation route based on the location of a vehicle and generating a recommendation for a vehicle maneuver. The method may comprise determining, based on sensor data received from a location sensor of a mobile device or a vehicle, a location of the vehicle. A computing device may determine a navigation route for navigating the vehicle from the location to a destination, and the navigation route may comprise a plurality of intersections. The computing device may determine a plurality of potential maneuvers at a first intersection of the plurality of intersections. The computing device may also determine, based on one or more factors, a navigation score for each of the plurality of potential maneuvers at the first intersection. Based on the navigation score for each of the plurality of potential maneuvers, the computing device may select a maneuver from the plurality of potential maneuvers to recommend for the vehicle.

Abstract: An apparatus for controlling a behavior of an autonomous vehicle includes: a joystick that inputs an adjustment value corresponding to an amount of manipulation by a user, and a controller to control the behavior of the autonomous vehicle based on the adjustment value corresponding to the amount of manipulation being input from the joystick.

Abstract: An apparatus for controlling a lane change of a vehicle includes: a sensor to sense an external vehicle, an input device to receive a lane change command from a driver of the vehicle, and a control circuit to be electrically connected with the sensor and the input device. The control circuit may receive the lane change command using the input device, calculate a minimum operation speed for lane change control, and determine whether to accelerate the vehicle based on a distance between a preceding vehicle which is traveling on the same lane as the vehicle and the vehicle, when a driving speed of the vehicle is lower than the minimum operation speed when receiving the lane change command.

Abstract: A computer in a vehicle that includes a processor and memory storing instructions executable by the processor. The instruction may include: receive an indication that the vehicle door is ajar; receive sensor data from a rotational-rate sensor in a vehicle; and based on the indication and sensor data, determine a traversal event.

Abstract: A method includes obtaining map data associated with a map of a geographic location including one or more roadways, the map including a first submap represented by a first local Euclidean space and a second submap represented by a second local Euclidean space. A route that includes a first roadway in the first submap and a second roadway in the second submap is determined using a first projection between a global coordinate system and the first local Euclidean space and a second projection between the global coordinate system and the second local Euclidean space. The route is provided to an autonomous vehicle (AV) for driving on the first roadway and the second roadway.

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: Provided is a wheeled device, including: a chassis; a set of wheels coupled to the chassis; one or more electric motors to rotate the set of wheels; a network card for wireless connection to the internet; a plurality of sensors; a processor electronically coupled to the plurality of sensors; and a tangible, non-transitory, machine readable medium storing instructions that when executed by the processor effectuates operations including: capturing, with at least one exteroceptive sensor, measurement readings of the environment; and estimating, with the processor using a statistical ensemble of simulated positions of the wheeled device and the measurement readings, a corrected position of the wheeled device to replace a last known position of the wheeled device.

Abstract: A method of operating a powertrain system during coasting operation, wherein the powertrain system includes a driveline component (e.g., a transmission, drive shaft, differential, axle or wheel) having an output torque profile. The method includes: (i) determining a desired output torque transition profile for the driveline component between a first transition point before an end of a first state, and a second transition point after a beginning of a second state; and (ii) in response to a braking torque request, generating a friction braking torque command to operate a friction braking system, and adjusting the friction braking torque command during a transitional state between the first and second transition points by an amount corresponding to a difference between a magnitude of the output torque profile and a magnitude of the desired output torque transition profile.

Abstract: A system is disclosed including but not limited to a processor; a hybrid power source for servicing a system load, the hybrid power source comprising a natural gas engine, a diesel engine and a battery; a linear computer program comprising, instructions determining a current system load serviced by power provided from the hybrid power source; instructions to determine a current operating state for the natural gas engine, the diesel engine and the battery; instructions to use linear programming to determine a new operating state for the natural gas engine, the diesel engine and the battery to reduce power consumption servicing the current system load the natural gas engine, the diesel engine and the battery; and instructions to replace the current operating state for the natural gas engine, the diesel engine and the battery to the new operating state for the natural gas engine, the diesel engine and the battery.

Abstract: A slip angle estimation device for a vehicle comprises an imaging device for capturing an image of at least one of the front and the rear of the vehicle and a control unit. The imaging device is a CCD camera including a lens and an imaging sensor. The control unit is configured to determine a plurality of tracking points for a plurality of captured objects, determine an optical flow for the plurality of tracking points based on two images captured at predetermined elapsed time intervals, determine a vanishing point based on intersections of the plurality of optical flows, and calculate a slip angle of the vehicle based on a ratio of a horizontal distance between an image center and the vanishing point to a distance between a lens center of the CCD camera and an imaging sensor.

Abstract: A system and a method of controlling an operation of an autonomous vehicle are provided. The method includes receiving, by the autonomous vehicle, information about neighboring vehicles and estimating a lane change intention of a first vehicle of the neighboring vehicles in a next lane in a front direction of the autonomous vehicle through the input information. Whether to allow the first vehicle to change a lane in consideration of acceleration/deceleration of the autonomous vehicle and whether a safe distance between the autonomous vehicle and the neighboring vehicles is secured is determined. An acceleration/deceleration control signal is generated for adjusting a traveling speed of the traveling vehicle and regenerative braking force and friction braking force of the autonomous vehicle is distributed according to the acceleration/deceleration control signal to perform braking.

Abstract: A vehicle control system includes: a plurality of terminals configured to be carried by users; and a control device configured to execute remote parking processing to move a vehicle from a current position to a parking position and to park the vehicle at the parking position in response to an instruction from any of the terminals. The control device is configured to execute starting processing to start operation of the vehicle in response to the instruction from any of the terminals. Once the control device executes the starting processing in response to an instruction from one of the terminals, the control device prohibits the remote parking processing in response to an instruction from any other of the terminals as long as the vehicle is in operation.

Abstract: This vehicle control device comprises: action amount determination units that determine evasive action amounts indicating the degree of evasive action relative to a recognized obstacle; and a travel control unit that performs travel control whereby a vehicle is caused to take evasive action corresponding to the determined evasive action amount. The action amount determination units determine the amount of evasive action, according to user preferences for the vehicle.

Abstract: An in-vehicle driving assistance apparatus that can execute driving assistance on the basis of any one of a plurality of control modes having mutually-different degrees of driving assistance, the apparatus comprising a receiving unit configured to receive a transition instruction of the control mode, a setting unit configured to set the control mode based on the transition instruction, a determining unit configured to determine whether or not a transition scheme for the control mode indicated by the transition instruction has a pre-registered detail, and a suppressing unit configured to suppress the setting of the control mode by the setting unit when the transition scheme for the control mode indicated by the transition instruction does not have the pre-registered detail.

Abstract: A vehicle control system includes: a driving operation device provided in a vehicle and configured to accept a driving operation by a user; an operation terminal configured to be carried by the user and including an input/output unit configured to accept an input by the user and to output a signal; and a control device configured to control traveling of the vehicle based on a signal from the driving operation device and to execute remote parking processing to move the vehicle to a parking position based on a signal from the operation terminal. When the control device detects the driving operation based on a signal from the driving operation device during the remote parking processing, the control device executes suspension processing to stop the vehicle and to make the input/output unit notify that the driving operation device has been operated.

Abstract: Apparatuses, systems, and methods relate to technology to control one or more systems to mitigate an oversteer condition of a vehicle or allow the oversteer condition, identify a curve in a roadway based on sensor data associated with the vehicle, based on the curve in the roadway, conduct an identification that the oversteer condition is to be allowed for at least a portion of the curve, and in response to the identification that the oversteer condition is to be allowed, controlling the one or more systems to allow the oversteer condition for the at least the portion of the curve.