Abstract: A method includes receiving an equipment configuration code file for configuration and control of a work vehicle, for configuration and control of an attachment to be carried or towed by the work vehicle, or for combined configuration and control of both the work vehicle and the implement in combination, altering the equipment configuration code file for use of the work vehicle, the implement, or both in an actual work setting, and storing the altered equipment configuration code file in an electronic storage medium for later access for use of the work vehicle, the implement, or both.

Abstract: Methods and systems for depicting a wind force exerted on an airborne vehicle are provided herein. The method includes receiving, by a processor, wind data measured by one or more airborne vehicles and position data associated with the one or more airborne vehicles. The method also includes generating, by the processor, a map display depicting a position of each of the one or more airborne vehicles based on the received position data. The method further includes generating a vehicle symbol on the map display for each of the one or more airborne vehicles. The vehicle symbol includes a vehicle indicator and a wind indicator. The wind indicator includes a symbol indicating a speed and a direction of wind exerted on the vehicle.

Abstract: A method for operating a vehicle, comprising receiving one or more dimensions of a parking position via a communication network, and autonomously maneuvering the vehicle into the parking position based on the one or more dimensions. An apparatus for operating a vehicle, and a method and an apparatus for assisting a vehicle upon maneuvering into a parking position are also described. A vehicle, a parking system for vehicles, and a computer program are also described.

Abstract: There is provided a map production method to be performed by a mobile robot which moves in a first region and includes a first sensor and a second sensor. The map production method includes acquiring first information from the first sensor, acquiring second information from the second sensor, acquiring third information from a third sensor provided in the first region, acquiring fourth information indicating a detection region of the second sensor calculated from the first information and the second information, acquiring fifth information indicating a detection region of the third sensor calculated from the third information, and updating map information of the first region for a third region, including a first object, if a the second region overlaps with the third region is judged to be present from the fourth information and the fifth information.

Abstract: A framework comprises a laser distance meter (LDM), first and second laser reflectors at respective nodes, and an excavator including a chassis, a linkage assembly (LA) including a boom and stick, an implement including the nodes and tilting about axis TA, an implement sensor generating signal ?tilt, and architecture. The LDM generates LDM distance signals DLDM and LDM angle of inclination signals ?INC between the LDM and the laser reflectors. The architecture comprises LA actuators and a controller programmed to determine the TA relative to horizontal based on ?tilt and execute an iterative process to curl the excavating implement and create bucket angles, align the LDM and the first node to determine a set of rotated IDV, align the LDM and the second node to determine a set of rotated IPV, and determine implement dimensions between the nodes based on the set of rotated IDV and IPV.

Abstract: Aspects of the disclosure relate to a method of controlling an HMI-apparatus for providing information to a driver of a vehicle for aiding driver control of a vehicle when the vehicle is wading in a body of water. The method includes determining a measured depth of water about the actual vehicle and determining a display depth, dependent upon the measured depth of water. The method also includes measuring a lateral and/or longitudinal gradient of the actual vehicle and selecting a display vehicle position from a limited number of available options of display vehicle positions based upon the measured lateral and/or longitudinal gradient of the actual vehicle. In this way the HMI-apparatus can output a simplified picture of the actual vehicle scenario which may be easier for the driver to assimilate.

Abstract: The guiding method such as described correctly guides an aircraft on a platform of an airport, even in complex taxiing areas.

Abstract: A vehicle behavior detection device mounted on an own vehicle detects own vehicle's behavior, in particular driver's right or left turn behavior at an intersection on a roadway. The vehicle behavior detection device is a microcomputer system having a CPU capable of providing an intended direction acquiring section, a turn direction acquiring section, a coincidence judgment section and an information output section. The intended direction acquiring section obtains an intended direction toward which the own vehicle is turning. The turn direction acquiring section acquires a direction to which the own vehicle turns. The coincidence judgment section detects whether or not the intended direction coincides with the turn direction of the own vehicle. The information output section provides warning regarding wide right or left turn of the own vehicle when the judgment result indicates that the intended direction does not coincide with the turn direction of the own vehicle.

Abstract: The present disclosure relates to a forklift and a forklift control method. The forklift and the forklift control method according to the present disclosure may adjust a fork/mast inclination with reference to the coefficient of friction, and precedently and appropriately adjust a fork/mast inclination right before the forklift enters or exits from a slope by referring to geological information. Further, when a degree of danger is not decreased even when a fork/mast inclination is tilted backward to the largest extend, the forklift and the forklift control method according to the present disclosure may decrease a travelling speed of a vehicle by decreasing an output of the forklift or operating a brake, thereby remarkably decreasing the danger of the load falling.

Abstract: A distance detecting device is mounted on a user's vehicle to detect a distance between the user's vehicle and a leading vehicle moving in front of the user's vehicle. The distance detecting device communicates with a processing device, which applies race based distance rules to determine whether the user's vehicle is close to or incurring a penalty based at least on the distance between the user's vehicle and the leading vehicle. An indication can be given to the user regarding an impending penalty and/or when a penalty is incurred. Similarly, the device can be read to apply a penalty. Various modifications can be made to allow for recording, display, and transmission of racing and penalty statistics, enabling and disabling recordation of penalty occurrences, tailoring the penalty determinations to a given race, and mounting the distance detecting device to a vehicle.

Abstract: In aspects herein, if GPS signals used as inputs into a GPS landing system become unreliable, an aircraft instead uses signals derived from radar data to operate the GPS landing system. Generally, GPS signals are unreliable if they cannot be received or if the signals are corrupted. Instead of using GPS signals, the landing system uses radar derived location data as inputs. In one example, the radar derived location data is generated using a radar system located at the intended landing site—e.g., an airport or aircraft carrier. The landing site transmits this data to the aircraft which processes the data using its GPS landing system that outputs control signals for landing the aircraft. Thus, even when GPS signals are unreliable, the aircraft can use the GPS landing system to land.

Abstract: A powertrain system including an internal combustion engine, a transmission and an electric machine is described, and includes the electric machine rotatably coupled to a crankshaft of the internal combustion engine. The transmission is coupled to a driveline to transfer tractive torque and braking torque thereto. A method for controlling the electric machine includes determining a short-term axle torque capacity, a long-term axle torque capacity and a maximum regenerative braking stall torque capacity, and determining an operator request for braking. A preferred regenerative braking capacity is determined based upon the short-term axle torque capacity, the long-term regenerative braking capacity, the engine stall regenerative braking capacity and the operator request for braking. Torque output from the electric machine is controlled based upon the preferred regenerative braking capacity.

Abstract: A remote computing system is described that includes at least one processor and at least one module. The at least one module is operable by the at least one processor to receive first operational data collected by a first line-replaceable-unit of a first aircraft during flight operations of the first aircraft, and receive second operational data collected by at least one second line-replaceable-unit of at least one second aircraft during flight operations of the at least one second aircraft. The at least one module is further operable by the at least one processor to predict, based at least in part on the first operational data and the second operational data, a failure condition associated with the first line-replaceable-unit of the first aircraft, and output, based on the impending failure condition, an indication of the predicted failure condition.

Abstract: Some embodiments provide a navigation application with a novel declutter navigation mode. In some embodiments, the navigation application has a declutter control that when selected, directs the navigation application to simplify a navigation presentation by removing or de-emphasizing non-essential items that are displayed in the navigation presentation. In some embodiments, the declutter control is a mode-selecting control that allows the navigation presentation to toggle between normal first navigation presentation and a simplified second navigation presentation, which below is also referred to as a decluttered navigation presentation. During normal mode operation, the navigation presentation of some embodiments provides (1) a representation of the navigated route, (2) representations of the roads along the navigated route, (3) representation of major and minor roads that intersect or are near the navigated route, and (4) representations of buildings and other objects in the navigated scene.

Abstract: This disclosure describes systems, methods, and apparatus for automating the verification of aerial vehicle sensors as part of a pre-flight, flight departure, in-transit flight, and/or delivery destination calibration verification process. At different stages, aerial vehicle sensors may obtain sensor measurements about objects within an environment, the obtained measurements may be processed to determine information about the object, as presented in the measurements, and the processed information may be compared with the actual information about the object to determine a variation or difference between the information. If the variation is within a tolerance range, the sensor may be auto adjusted and operation of the aerial vehicle may continue. If the variation exceeds a correction range, flight of the aerial vehicle may be aborted and the aerial vehicle routed for a full sensor calibration.

Abstract: A control system for a vehicle includes at least one controller. The controller is programmed to receive first sensor readings from a first group of sensors and provide a first vehicle pose based on the first sensor readings. The first vehicle pose includes a first location and a first orientation of the vehicle. The controller is also programmed to receive second sensor readings from a second group of sensors and provide a second vehicle pose based on the second sensor readings. The second vehicle pose includes a second location and a second orientation of the vehicle. The controller is further programmed to, in response to the first vehicle pose being outside a predetermined range of the second vehicle pose, generate a diagnostic signal.

Abstract: Techniques and systems for providing miniaturized unmanned aerial vehicles (UAVs) are disclosed. The techniques and systems can include significant off-board processing support for the UAVs to enable the UAVs to be smaller, lighter, and less expensive than conventional UAVs. The techniques and systems can include routines to provide enhanced support for police during routine traffic stops. The techniques and systems can also include routines to locate objects or people including, for example, locating a lost child in a crowd or a lost vehicle in a parking lot. The miniaturized UAVs can provide enhances perception for the user to enable the user to over and around objects for improved visibility and safety, among other things.

Abstract: Systems, methods and computer-storage media are provided for displaying a real-time image in a cockpit of an aircraft. Use of a synthetic vision application is provided with a gradient-type feature such that a level of synthetic enhancements applied to an image may be adjusted to a synthetic vision application value that is less than 100 percent. The synthetic vision enhancement may be overlaid with the original image, according to the synthetic vision application value, to generate a modified image. Additional information may overlay the original image with the synthetic vision application such as a three-dimensional weather representation. The synthetic vision application may be used in conjunction with a high-definition camera to generate the original image. The modified image may be updated in real-time such that an updated view is continuously modified with an updated synthetic vision enhancement to provide accurate real-time views.

Abstract: A method of controlling operation of a robotic cleaning device and a robotic cleaning device performing the method. The robotic cleaning device includes a main body, a propulsion system arranged to move the robotic cleaning device, and an obstacle detection device arranged to detect obstacles. The robotic cleaning device further includes a controller arranged to control the propulsion system to move the robotic cleaning device. The controller is further arranged to identify one or more sections to be cleaned where the robotic cleaning device is likely to move without being hindered by the detected obstacles, and to control movement of the robotic cleaning device such that cleaning of the identified one or more sections is prioritized before sections of the surface where the robotic cleaning device is more likely to be hindered by the detected obstacles.

Abstract: A steering assist system for a vehicle comprises a steering assist module configured to determine a baseline assistance force to be applied to a steering system of the vehicle, and a transient disturbance compensation module configured to determine a transient compensation force to compensate for transient conditions that urge the vehicle to deviate from a straight path. The transient compensation force is based at least partially on the determined baseline assistance force. The system also includes a steady-state disturbance compensation module configured to determine a steady-state compensation force to compensate for steady-state conditions that urge the vehicle to deviate from the straight path, the steady-state compensation force being based at least partially on the determined baseline assistance force. Methods relate to controlling steering systems.