A method and a device for operating an automated vehicle are provided. The method includes a step of receiving a first position of the automated vehicle, a step of receiving environment data values, the environment data values representing an environment of the automated vehicle, a step of detecting at least one further vehicle in the environment of the automated vehicle, and a step of generating a digital environment model, starting from a digital map, based on the environment data values and as a function of the first position of the automated vehicle. The environment model comprises the automated vehicle, the at least one further vehicle, and at least one simulated object in the environment of the automated vehicle. The method also includes a step of operating the automated vehicle as a function of the digital environment model.

Techniques associated with generating simulation scenarios for simulating a vehicle controller are discussed herein. Log data may include sensor data captured by sensors of a vehicle. The log data may represent objects in an environment. Objects may be associated with a region of a discretized representation of the environment relative to the vehicle. Specific states of objects (relative position in a region type, velocity, classification, size, etc.) may represent an instance of an occupation. Log data can be aggregated based on similar region type and/or object state. A statistical model over object states can be determined for each region type and can later be sampled to determine simulation parameters. A simulation scenario can be generated based on the simulation parameters, and a vehicle controller can be evaluated based on the simulation scenario.

An object is to reduce a current detection error of a current sensor while suppressing upsizing of a power conversion device equipped with the current sensor. A power conversion device includes a power conversion circuit; a conductor to transmit current to the circuit; and a coreless current sensor to detect the current. The coreless current sensor includes: a magnetic field detection portion; and a shield portion facing the magnetic field detection portion. The conductor includes: a first conductor portion that passes through a space between the magnetic field detection portion and shield portion; and a second conductor portion connected to the first conductor portion via a first bent portion, and the first bent portion is formed such that the space between the magnetic field detection portion and shield portion is not disposed in a direction perpendicular to a face of the second conductor portion closest to the shield portion.

High-performance road vehicle having: a plurality of replaceable or removable components; a control unit, which controls the operation of the road vehicle; at least one electronic identification device, which is fitted on a corresponding component, has a memory designed to contain at least one unique identifying code of the component and has a first transmission organ designed to send the data contained in the memory; and a second transmission organ, designed to communicate with the first transmission organ and connected to the control unit to allow the control unit to read the univocal identifying code of the component.

A vehicle control system for use with a host vehicle configured for travel along a path is described. The vehicle control system includes a processor configured to access a host location and host speed of the host vehicle. The processor is also configured to detect a follower location and follower speed of a following vehicle behind the host vehicle on the path. A tailgating distance is calculated between the host vehicle and the following vehicle. The following vehicle is identified as a tailgating vehicle when the tailgating distance is less than or equal to a first warning distance or when the follower speed is greater than the host vehicle within a second warning distance. A tailgating protocol of the host vehicle is initiated for the tailgating vehicle based on a differential speed between the host speed and the follower speed.

Disclosed are a method of controlling a mode transition in order to predict a driver's required torque to reduce non-driving fuel loss, and a hybrid vehicle for performing the method in particular, the method of controlling a mode transition of a hybrid vehicle may include: determining whether to change a first mode to a second mode based on a first torque; determining a second torque expected to be generated at a near-future time after a current time; determining whether or not an engine clutch engagement is possible at the near-future time based on the second torque or a predicted acceleration; and performing the change from the first mode to the second mode when the mode change from the first mode to the second mode is determined and the engine clutch engagement is possible.

A vehicular control system includes a camera disposed at a vehicle and having a field of view forward of the vehicle, and includes a radar sensor disposed at the vehicle and sensing forward of the vehicle. Data is wirelessly transmitted from the vehicle to a data cloud. Data is wirelessly received at the vehicle from the data cloud concerning a potential hazard existing forward of the vehicle that has not yet been detected via processing by at a processor of image data captured by the camera and/or radar data captured by the radar sensor. Responsive at least in part to the vehicular control system detecting the potential hazard via processing at the processor of image data captured by the camera and/or radar data captured by the radar sensor, the vehicular control system controls at least one vehicle function of the vehicle to mitigate collision with the potential hazard.

Aspects of the present disclosure relate switching between autonomous and manual driving modes. In order to do so, the vehicle’s computer may conduct a series of environmental, system, and driver checks to identify certain conditions. The computer may correct some of these conditions and also provide a driver with a checklist of tasks for completion. Once the tasks have been completed and the conditions are changed, the computer may allow the driver to switch from the manual to the autonomous driving mode. The computer may also make a determination, under certain conditions, that it would be detrimental to the driver’s safety or comfort to make a switch from the autonomous driving mode to the manual driving mode.

A system and method for navigating a vehicle automatically from a current location to a destination location without a human operator is disclosed. The method includes identifying a vehicle location using global positioning system (GPS) data regarding the vehicle. Also included is identifying that the vehicle location is near or at a parking location. Then, using mapping data defined for the parking location. The mapping data at least in part is used to find a path at the parking location to avoid a collision of the vehicle with at least one physical structure when the vehicle is automatically moved at the parking location. The method includes instructing the electronics of the vehicle to proceed with controlling the vehicle to automatically move from the current location to the destination location at the parking location. The electronics use as input at least part of the mapping data and sensor data collected from around the vehicle by at least two vehicle sensors. The path is configured to be updatable dynamically based on changes in the destination location or changes along the path. The destination location is a parking spot for the vehicle at the parking location.

A server determines at least two component groups in a vehicle, where each component group includes one upgrade control component configured to control a component in the component group to perform an over the air (OTA) upgrade; the server generates a first upgrade package for a first component group in the at least two component groups, where an upgrade control component in the first component group is a first upgrade control component; and the server sends the first upgrade package to the first upgrade control component, where the first upgrade package is used to upgrade a component in the first component group.