Abstract: A parking control system for an autonomous vehicle is provided. The parking control system includes a parking control device configured to monitor a location and movement of an autonomous vehicle which enters a parking lot, based on a 3D electronic map, calculate a driving trajectory to a parking space selected by a driver of the autonomous vehicle based on sensor data collected from various sensor in the parking lot and vehicle information received from the autonomous vehicle, and provide information about the calculated driving trajectory to the autonomous vehicle. The autonomous vehicle travels to the parking space based on the driving trajectory received from the parking control device and parks in the parking space.

Abstract: An automated parking system and a method enables a vehicle to autonomously travel to and parks in a vacant parking slot based on communication with a parking infrastructure. In addition, the automated parking system and method for a driverless vehicle is capable of autonomously traveling from a parking slot to a pickup area via communication with the parking infrastructure.

Abstract: Method and apparatus are disclosed for mobile device tethering for a remote parking assist system of a vehicle. An example vehicle includes first and second wireless modules and a processor. The processor estimates a region of probability representative of possible locations of a mobile device based on a first signal strength indicator. When the region of probability overlaps a virtual boundary, the processor polls a key fob, estimates a distance of the key fob from the vehicle based on a second signal strength indicator, and when the key fob is within the virtual boundary, enable autonomous parking.

Abstract: A parking assist device according to the present invention includes a backward-direction-path calculation unit that calculates a backward-direction path for taking an own vehicle out from a target parking position B based on constraint conditions of a parking space and an own-vehicle behavior, a connection-candidate-position storage unit that sets a plurality of connection candidate positions D on the backward-direction path, a forward-direction-path calculation unit that calculates a forward-direction path leadable to one of the connection candidate positions D from a current position A of the own vehicle, and a parking-path setting unit that sets a parking path by combining the backward-direction path and the forward-direction path.

Abstract: A vehicle and a method for the vehicle to detect a vehicle accident are provided. The method includes accessing at least one accident profile, wherein each accident profile contains information describing, for vehicles involved in a vehicle accident, data indicating vehicle operating parameters during the accident; collecting, in real time, data from the vehicle and at least one nearby vehicle, the data describing current vehicle operating parameters for the vehicles; comparing the data collected in real time with the at least one accident profile to determine a probability of a vehicle crash; and implementing preventive action responsive to the probability of a vehicle crash exceeds a probability threshold.

Abstract: A secondary system operates on a vehicle to avoid a collision when a problem occurs with a primary system. For example, the secondary system may operate independently from the primary system to take over control of the vehicle from the primary system when the secondary system detects a potential collision, when an error occurs with the primary system, and so on. In examples, the primary system may implement first techniques, such as Artificial Intelligence (AI) techniques, to understand an environment around the vehicle and/or instruct the vehicle to move within the environment. In examples, the secondary system may implement second techniques that are based on positioning, velocity, acceleration, etc. of the vehicle and/or objects around the vehicle.

Abstract: A method for selecting and executing at least one reactive action of a vehicle includes a control unit receiving sensor data from a vehicle sensor system; detecting an emergency situation based on the sensor data; performing an evaluation; and selecting and implementing a reactive action for minimizing an accident risk of the vehicle based on the evaluation, where, in the evaluation, sensors that are uninvolved in the detection of the emergency situation are not taken into account or are taken into account at a lower weighting, are operated at a reduced performance, and/or are operated with a reduced scanning range. In addition, a control unit, computer program, and machine-readable memory medium can be provided for implementing the method.

Abstract: An in-vehicle monitoring camera device 100 includes: an obstacle detection unit 3 that detects, as first obstacles, obstacles detected by a millimeter-wave radar 11 which might collide with the host vehicle; a collision risk determination unit 4 that detects the time before the respective first obstacles and the vehicle come into contact with each other; a distortion correction unit 2 that generates image 2 by correcting distortion in image 1 captured using a wide-angle lens; and a camera-viewpoint display control unit 5 that generates image 3 by cutting out, from image 2, an image of the first obstacle having the shortest time to collision. Therein, a radar chart 31 indicating the visual field range or the center direction of the visual field of image 3 is superimposed on image 3.

Abstract: Aspects of the disclosure relate to controlling a first vehicle in an autonomous driving mode. While doing so, a second vehicle may be identified. This vehicle may be determined to be a tailgating vehicle. An initial allowable discomfort value representing expected discomfort of an occupant of the first vehicle and expected discomfort of an occupant of the second vehicle may be identified. Determining a speed profile for a future trajectory of the first vehicle that meets the value may be attempted based on a set of factors corresponding to a reaction of the tailgating vehicle. When a speed profile that meets the value cannot be determined, the value may be adjusted until a speed profile that meets the value is determined. The speed profile that meets an adjusted value is used to control the first vehicle in the autonomous driving mode.

Abstract: A traveling control apparatus is configured to control automated driving traveling of a vehicle based on a set automated driving level. The traveling control apparatus comprises: an acquisition unit configured to acquire traveling scene information that specifies a traveling scene of the vehicle; and a control unit configured to perform offset control to offset a traveling position of the vehicle in a vehicle width direction to increase a distance to another vehicle traveling side by side with the vehicle. The control unit performs the offset control by setting one of a first mode and a second mode based on at least one of the traveling scene information and the automated driving level.

Abstract: This work vehicle (tractor), which is provided with an engine and an accelerator pedal capable of changing the operational state of the engine, and is configured to be free to travel by means of an operation of the accelerator pedal by an operator, is equipped with a display near an operator's seat, said display being configured to be capable of displaying a screen (travel customization screen) for selecting whether or not to allow travel in conjunction with the accelerator.

Abstract: When controlling a driving source torque in order to accelerate a driving wheel, a driving source torque controller performs shock suppression control of controlling the driving source torque based on an acquired driving source torque so that at least one of (i) an absolute value of relative speed between power transmission members on a power transmission path decreases when backlash between the power transmission members decreases or (ii) a transmission torque which is transmitted between the power transmission members on the power transmission path decreases when the backlash between the power transmission members is eliminated.

Abstract: A vehicle includes a motor; a transmission; a battery; a mode input device for receiving a driving mode; a control information input device for receiving regenerative braking control information or gearshift level control information; and a controller configured to control at least one of braking torque of the motor and gearshift level of the transmission to control an amount of regenerative braking during regenerative braking by recognizing a signal received from the control information input device as a signal corresponding to the regenerative braking control information when the driving mode input to the mode input device is a first mode, and control the transmission to control the gearshift level of the transmission by recognizing a signal received from the control information input device as a signal corresponding to the gearshift level control information when the driving mode input to the mode input device is a second mode.

Abstract: A method and an apparatus for temporarily deactivating a function of maintaining constant speed for a two-wheeled motor vehicle, independently of a driver, where a speed to be maintained is specified by the driver, the occurrence of cornering is detected, and, in response to the occurrence of cornering, the specified speed is reduced independently of the driver.

Abstract: A host vehicle includes an internal combustion engine, a turbocharger in fluid communication with the internal combustion engine, a communication system configured to transmit and receive a traffic-related message, and a controller in communication with the turbocharger and the communication system. The controller is programmed to: receive the traffic-related message via the communication system; and command the internal combustion engine to increase a power output to spool up the turbocharger in response to receiving the traffic-related message. The controller is programmed to determine a number of relevant vehicles. The number of relevant vehicles is a number of vehicles that are in front of the host vehicle and behind a traffic light and affect a movement of the host vehicle toward the traffic light. The traffic-related message is a one of a vehicle message from another vehicle and/or a traffic-light message from the traffic light.

Abstract: The invention relates to a vehicle control device adapted to be mounted in a host vehicle (H), the vehicle control device comprising an environment monitoring unit adapted and configured to monitor the environment of the host vehicle (H) and to provide corresponding environment monitoring data, and a lane change request generating unit adapted and configured to determine based upon the environment monitoring data whether the generation of a request for a lane change of the host vehicle (H) from a current lane (CL) to a lower-ranking lane (RL) is to be initiated (arrow A6a) or is to be suppressed (arrow A6b), if the environment monitoring data indicate that at least one succeeding vehicle (S) driving in the same lane as the host vehicle (H) approaches the host vehicle from behind at a speed higher than the speed of the host vehicle (H).

Abstract: A vehicle control device including a first driving force controller and a second driving force controller. The first driving force controller executes the first driving force control or the second driving force controller executes the second driving force control, on the basis of the speed of the vehicle, the first vehicle speed limit, and the second vehicle speed limit. The first vehicle speed limit and the second vehicle speed limit change independently of each other.

Abstract: Vehicle alert and control systems and methods taking into account a detected road friction at a following vehicle and a predicted road friction by the following vehicle. The detected road friction between the following vehicle tires and the road surface may be assessed using a variety of methodologies and is used to compute a critical safety distance between the following vehicle and the preceding vehicle and a critical safety speed of the following vehicle. The predicted road friction ahead of the following vehicle may also be assessed using a variety of methodologies (lidar, camera, and cloud-based examples are provided) and is used to compute a warning safety distance between the following vehicle and the preceding vehicle and a warning safety speed of the following vehicle. These functionalities may be applied to vehicle/stationary object warning and response scenarios as well.

Abstract: A travel control apparatus is provided. The travel control apparatus acquires driver abnormality information indicative of an abnormality of a driver of a vehicle, makes a determination that the driver is in a driving difficulty state based at least on the driver abnormality information, and activates a lane departure prevention function and a cruise control function of the vehicle at substantially the same time during a time period between when the driver abnormality information is acquired and when the driving difficulty state is determined. Together with activating the lane departure prevention function and the cruise control function, the travel control apparatus outputs notification request information to a human machine interface controller controlling a notification device which issues a notification to a passenger of the vehicle. The notification request information causes the notification indicative of activation of the lane departure prevention function and the cruise control function to be issued.

Abstract: Methods and systems for generating a predicted occupancy grid map (OGM) over at least one future time step are described. The system include a first encoder for extracting OGM features from an input OGM in a current time step. The system also includes a recurrent neural network for generating a corrective term from at least the OGM features, wherein the corrective term represents predicted change to the input OGM, and wherein the corrective term is applied to the input OGM to generate a corrected OGM. The corrected OGM represents features corresponding to occupancy of the environment in a first future time step. The system also includes a classifier for converting the corrected OGM to the predicted OGM for the first future time step. The predicted OGM is fed back as input for performing generating a predicted OGM for a second future time step.

Abstract: A fuel economy and comfort control apparatus is provided for a motor vehicle. That apparatus includes a plurality of sensors and a controller. The controller is configured to determine and advise an operator of the motor vehicle of the most fuel efficient mode of operating a climate control system of the motor vehicle to maintain occupant comfort while optimizing fuel efficient operation of the motor vehicle. A related method is also disclosed.

Abstract: A vehicle configured for determining an emotion state of a user, and adjusting a speed change of the vehicle that exerts an influence on the drive ability on the basis of the determined emotion state, and a method of controlling the same, may include a sensing unit configured to measure an acceleration of a vehicle and a bio-signal of a user; and a control unit connected to the sensing unit and configured to determine emotion state information indicating an emotion state of the user on the basis of the measured bio-signal when the measured acceleration is greater than or equal to a threshold acceleration, and on the basis of the emotion state information and correlation information indicating a relationship between the emotion state information and a drive ability factor related to a drive ability according to a speed change of the vehicle, update a setting value of the drive ability factor.

Abstract: A method, computer program product, and computing system for operating an autonomous vehicle; monitoring the operation of a plurality of computing devices within the autonomous vehicle; and in response to detecting the failure of one or more of the plurality of computing devices, switching the autonomous vehicle from a nominal autonomous operational mode to a degraded autonomous operational mode.

Abstract: A method and system for enabling a vehicular accessory control improvement is provided. The method includes continuously monitoring user attributes associated with user actions occurring exterior to a vehicle. Vehicle control actions associated with controlling devices of the vehicle are determined in response to the user actions and activities occurring within the vehicle are monitored. The vehicle control actions are executed and self-learning software code associated with future instances of executing the vehicle control actions with respect to detecting future instances of user actions is generated.

Abstract: The present disclosure relates to a driver distraction warning control apparatus and a driver distraction warning control method. The driver distraction warning control apparatus includes a sensor device that detects gaze of a driver, a setting device configured to divide a virtual area on front of the driver into a plurality of gaze areas, and sets a threshold for each of the gaze areas, a determining device that determines a viewing area corresponding to the driver's gaze direction from among the gaze areas, and a controller that performs driver distraction warning control based on the threshold set for the determined viewing area.

Abstract: A travel-lane determination unit determines whether a vehicle is going to enter a traffic lane on which a toll booth is provided. After it is determined that the vehicle is going to enter the traffic lane, a travel control unit stops the vehicle at a position before the toll booth in a travel direction of the vehicle.

Abstract: A driving support device includes a support unit configured to support driving by setting a target location for guiding a vehicle and a set route to the target location, a setting unit configured to set a transmissivity in accordance with a state of the vehicle with respect to the target location or the set route, and a generating unit configured to generate a display image including an indicator for supporting driving with the transmissivity.

Abstract: A vehicle control device controlling a vehicle capable of switching between an automatic driving mode and a driver involvement mode in which a driver is involved includes a blind spot boundary specifying unit configured to specify a boundary of a region becoming a blind spot of the vehicle, a traveling plan generation unit configured to generate a traveling plan in which the vehicle does not collide with a moving body assumed to be positioned on the blind spot boundary specified by the blind spot boundary specifying unit, a determination unit configured to determine whether or not the traveling plan generated by the traveling plan generation unit satisfies a predetermined condition, and a switching unit configured to switch the vehicle from the automatic driving mode to the driver involvement mode when the determination unit determines that the traveling plan satisfies the predetermined condition.

Abstract: Disclosed herein are a driver assistance apparatus for predicting a situation falling out of a system limit in advance to induce a driver to hold a steering wheel, thereby securing safety, a method of controlling the driver assistance apparatus, and a driver assistance system. The driver assistance apparatus according to an embodiment may include: a camera configured to acquire lane information of a road on which a vehicle travels, over a predetermined range; and a controller configured to receive state information of the vehicle from at least one sensor provided in the vehicle, to determine whether autonomous steering control of the vehicle is possible based on the lane information and the state information, and to control an output device provided in the vehicle to output a warning message.

Abstract: An apparatus (100) for determining an attention requirement level of a driver of a vehicle is provided, which comprises a first signal processing unit (101), a second signal processing unit (104), a third signal processing unit (107), a fourth signal processing unit (110), and an attention requirement determination unit (113), connected to the first, second, third and fourth signal processing unit (101, 104, 107, 110) and configured to determine an attention requirement level (114) as a function of current values of the first, second, third and fourth attention requirement parameters (103, 106, 109, 112). In addition, a vehicle (200) having such an apparatus (100) and an operating method (300) for the apparatus (100) are provided.

Abstract: Disclosed herein are a driver assistance apparatus for predicting a situation falling out of a system limit in advance to induce a driver to hold a steering wheel, thereby securing safety, a method of controlling the driver assistance apparatus, and a driver assistance system. The driver assistance apparatus according to an embodiment may include: a camera configured to acquire lane information of a road on which a vehicle travels, over a predetermined range; and a controller configured to receive state information of the vehicle from at least one sensor provided in the vehicle, to determine whether autonomous steering control of the vehicle is possible based on the lane information and the state information, and to control an output device provided in the vehicle to output a warning message.

Abstract: A first acquisition unit of a control device mounted on a vehicle acquires first traveling information at least including position information on a host vehicle. A second acquisition unit acquires second traveling information at least including traveling track information on a vehicle ahead when braking occurs in the vehicle ahead. A determination unit determines a threshold value based on the second traveling information acquired by the second acquisition unit and the first traveling information acquired by the first acquisition unit. An output unit gives a notification of braking in the vehicle ahead in accordance with a relationship between a distance and the threshold value determined by the determination unit, the distance being defined between the traveling track information in the second traveling information acquired by the second acquisition unit and the position information in the first traveling information acquired by the first acquisition unit.

Abstract: A method for decelerating a vehicle, a non-transitory computer-readable medium for performing the method, and reception apparatuses. The method includes monitoring a state of a driver of the vehicle, and causing a notification to be output based on the monitored state of the driver. The method further includes determining, by circuitry of an information processing apparatus and when operating in a manual operation mode, whether to cause the vehicle to decelerate after the notification is output.

Abstract: A method for autonomous emergency braking of an ego vehicle includes capturing driving-dynamics variables of the ego vehicle, capturing distance measurement signals, determining a longitudinal distance of the ego vehicle from an object in front, detecting an emergency braking situation based on the driving-dynamics variables and the distance measurement signals. The method further includes advanced determining or projecting, in response to the detecting the emergency braking situation, of first, second, and third starting points for initiation of a warning phase, a subsequent partial braking phase, and an emergency braking brake pressure. The advanced determining or projecting of the first, second, and/or third starting points includes: setting up a minimum period criterion with at least one minimum period and projecting, in advance in accordance with the longitudinal distance from the object, a criticality function that represents a criticality of the traffic situation.

Abstract: A system for automated maneuvering of an ego vehicle includes: a recognition device configured to recognize a moving object in the surroundings of the ego vehicle and to assign the object to a specific object classification; a control device coupled to the recognition device, the control device being configured to retrieve behavior parameters for the recognized object classification from a behavior database, the behavior parameters having been determined by a method in which moving objects are classified using machine learning and are tagged on the basis of specific behavior patterns; and a maneuver planning unit coupled to the control device, the planning unit being configured to plan and execute a driving maneuver of the ego vehicle on the basis of the retrieved behavior parameter.

Abstract: A computer is programmed to receive biometric data, from a transdermal patch in a vehicle during operation of a vehicle, wherein the biometric data include a measurement of a chemical. The computer is programmed to actuate a vehicle component, upon determining from a combination of the measurement of the chemical and vehicle operating data that a risk threshold is exceeded.

Abstract: An issue reporting and detection system is discussed. A user can capture an image with a mobile device of an issue at a location in a facility. An application executing on the mobile device can receive an input associated with the image. The mobile application can transmit image and the input associated with the image to a computing system which can determine a location at which the image was taken in the facility. The computing system can transmit a command to a UAGV to navigate to the determined location of the facility where the UAGV can capture an image using an image capturing device coupled to the UAGV, of the reported issue at the location in the facility. The UAGV can transmit the image to the computing system to confirm the type of the facility issue based on the image captured by the UAGV. The computing system can transmit an appropriate alert after confirming the issue.

Abstract: A platform door system is disclosed. The platform door system has: a platform data transmitting element positioned on a platform for transmitting a platform signal; a vehicle information integrating element, positioned on a vehicle adjacent to the platform, for receiving the platform signal and a vehicle signal corresponding to a door opening or closing status of the vehicle door from the vehicle, and for transmitting a platform-vehicle integration signal; and a platform door controlling element, positioned on the platform, for receiving the platform-vehicle integration signal and for opening or closing a platform door in response to the platform-vehicle integration signal to correspond to the opening-or-closing status of the vehicle door.

Abstract: A trajectory changing zipline system has a zipline support rail, a zipline trolley, and a pair of zipline cables. The pair of zipline cables is supported by a pair of cable supports of the trolley. A pair of support carriages of the trolley traverses along the cables and interfaces with the pair of cable supports. The zipline support rail may be curved to change an initial trajectory of the zipline trolley into a final trajectory.

Abstract: A system is provided that includes a controller configured to determine one or more propulsion-generating vehicles in a group of propulsion-generating vehicles that have an increased risk for damage to an engine system based on operation at a fueling level that is less than a designated threshold fueling level for at least a designated time period. The controller is further configured to determine respective power outputs for the propulsion-generating vehicles in the group such that the one or more propulsion-generating vehicles having the increased risk for damage to the engine system do not operate below the designated threshold fueling level for longer than the designated time period.

Abstract: A bodywork structure for a body for a public transport vehicle, in particular a railway vehicle or a road transport vehicle, for example a guided road transport vehicle, including a wall extending in a longitudinal direction, the wall including at least one cavity extending in the longitudinal direction, wherein the cavity forms a passage for a fluid under pressure, for example a gas under pressure.

Abstract: This abnormality monitoring device is equipped with: an acceleration data acquisition unit for acquiring measurement data about the acceleration of a vehicle chassis; an abnormality presence determination unit for determining whether an abnormality is present on the basis of a comparison between the acceleration and a threshold; a frequency analysis unit for analyzing the acceleration frequency when the abnormality presence determination unit determines that an abnormality is present, and an abnormality type identification unit for identifying abnormality type on the basis of the frequency pattern.

Abstract: The present invention relates to a smart vest for use by railyard personnel at a railyard. The smart vest utilizes many safety features, such as improved visibility, a real-time camera, an environmental monitor, high-accuracy location tracking, tracking the “state” of the railyard crew member, real-time communication, and mobile power. Each of these features may be incorporated with the smart vest.

Abstract: A method and system for motion control of movers in an independent cart system is disclosed. In one implementation, the independent cart system includes a plurality of track segments, each section having a respective controller. One of the controllers receives a motion command for a plurality of carts, respectively. The controller generates a force command for each of the plurality of carts and transmits the respective commands to the track segments commutating the plurality of carts.

Abstract: An independent cart system with safety functions that prevent unintended motion independently within different sections of the track while permitting motion along other sections of the track is disclosed. A safety controller receives one or more input signals corresponding to operating conditions along the track. A safety program executing in the safety controller monitors the state of the input signals to determine whether a safety function is to be executed. When a safety program is executed, the safety controller transmits an output signal to one or more segment controllers present in one section along the track. Each segment controller is responsible for regulating current flow to the coils mounted to the corresponding track segment. In response to the signal from the safety controller, each segment controller in the section controls the power output to the coils along that section of track to achieve the safe operation desired in that segment.

Abstract: The present disclosure provides a train turn-back control method, device and system. The method includes: determining first state information of a train when confirming that a turn-back instruction is received; directly resetting the first state information to obtain second state information; and performing turn-back control on the train according to the second state information. The present disclosure can realize turn-back control on the train based on a single set of vehicle on-board-device, thereby improving the turn-back success rate and turn-back efficiency of the train, and reducing the hardware consumption.

Abstract: A cart may include a door forming a bed of the cart and a pair of wheel attachment assemblies. Each wheel attachment assembly may include (a) a fender having a planar expanse configured to abut a lower major face of the door, (b) a clamping member coupled to the fender, the clamping member configured to be coupled to an upper major face of the door and abut an edge face of the door, and (c) a wheel fork coupled to the fender and configured to be coupled to an axle of a wheel. The cart may include a handle clamp configured to be coupled to an edge portion of the planar member and a handle configured to be coupled to the handle clamp.

Abstract: A carriage includes a storage, a sensor, and a computer. The storage is configured to receive a commodity to be placed in the storage. The sensor is configured to acquire a waveform of vibration of the placement unit. The computer is configured to detect that the commodity is placed in the placement unit based upon the waveform acquired by the sensor.

Abstract: A transport dolly includes a base and a tongue rotatably mounted to the base. At least one support is mounted to the base. A first cable guide is coupled to the at least one support. A lever is rotatable between a first orientation and a second orientation. A cable has a first portion attached to the tongue. The cable extends from the tongue to the first cable guide, then to the lever. The lever pulls on the cable when the lever is rotated from the first orientation to the second orientation, so as to decrease a distance between the cable first portion and the first cable guide, thereby rotating the tongue from a lowered orientation to a raised orientation. A spring mechanism exerts a force on the lever to prevent rotation of the lever from the second orientation to the first orientation when the tongue is raised.

Abstract: A shopping cart basket having a handle region located at the front or the sides of the shopping cart basket is disclosed. The forward handle region may have a plurality of openings along the front, corners, and sides to allow a customer to easily grip the shopping cart basket and guide the shopping cart. The shopping cart basket may be formed from a metallic wire portion and a non-metallic forward handle region, or in some embodiments, the shopping cart basket may be formed from a fully formed from a polymer material. The shopping cart may also include non-metallic corner inserts that form a portion of the side and front walls of the shopping cart as well as a non-metallic bottom insert that forms a portion of the bottom wall of the shopping cart.