Aspects of the disclosure relate to a vehicle having an autonomous driving mode and a manual driving mode. The vehicle may include a steering system having one or more processors configured to control the orientation of the one or more wheels based on control commands. The vehicle may also include an autonomous driving control system configured to control the vehicle in an autonomous driving mode by generating the control commands and to send the control commands to the steering system. In addition, the steering system may thermally derate the steering system based on first temperature information for the steering system when the vehicle is operating in a manual drive mode, and the autonomous driving control system may thermally derate the steering system based on second temperature information for the steering system when the vehicle is operating in the autonomous driving mode.

This patent application discloses methods and systems for alerting computerized motor-vehicles about predicted accidents. In an example method, a motor vehicle alerts another motor vehicle about a predicted accident, even though that accident is between the alerting car and a third motor vehicle—for example, the alert is transmitted by non-visual electromagnetic (EM) radiation. When an adjacent motor vehicle receives such accident alert and determines it might itself be hit, it will react so as to minimize its chances of being hit or at least to minimize the damage if it is being hit. Optionally, one or more of the motor vehicles has an onboard device for measuring a blood-alcohol level of a human driver thereof. The measured blood-alcohol level may be used to compute a probability of an occurrence of an accident and/or may be included in one or more of the transmitted accident alerts.

In a vehicle control system, a running controller (120) that executes running control of a vehicle without depending on a driving operation of a vehicle occupant and a running device (44) that is a control target of the running controller and outputs a predetermined signal to the running controller are included, and the running controller stops the running control of the vehicle in a case in which the predetermined signal has been blocked from the running device.

An object detection system for a saddle-type vehicle is provided. The system comprises an object detection unit configured to detect an object, wherein the object detection unit is provided on a handlebar which is rotatable to a body of the vehicle; an inclination detection unit configured to detect an inclination of a saddle-type vehicle; a steering angle detection unit configured to detect a steering angle of the handlebar to the body; and a position specification unit configure to specify a position of the object detected by the object detection unit, and correcting the position so that the inclination detected by the inclination detection unit is upright and the steering angle of the handlebar detected by the steering angle detection unit is directed straight.

A vehicle control system includes the following components. An automated driving control unit carries out a first driving mode in which at least one of acceleration/deceleration and steering of a vehicle is automatically controlled. An operation device receives an operation performed by an occupant of the vehicle. A handover control unit instructs shifting to a second driving mode, in which the degree of automated driving is lower than in the first driving mode, when the occupant of the vehicle operates the operation device to instruct one of or both of acceleration/deceleration and steering of the vehicle in the first driving mode. A drive control unit performs acceleration based on an acceleration operation if speed of the vehicle to be achieved as a result of acceleration based on the acceleration operation does not exceed a threshold dependent on a steering angle of the vehicle.

A device for carrying out at least one vehicle function, including: a first control unit having a first main unit and a first redundant unit, the first control unit being for controlling a first vehicle function; a second control unit having a second main unit and a second redundant unit, the second control unit being for controlling a second vehicle function; and a first electrical system to connect the first main unit to the second redundant unit and a second electrical system separated from the first electrical system, which for connecting the second main unit to the first redundant unit, the second main unit being for controlling the first redundant unit if the first electrical system fails and/or the first main unit being for controlling the second redundant unit if the second electrical system fails. Also described are a related method, control apparatus, and computer readable medium.

The invention relates to a state control system and method for a vehicle with a battery to be swapped. The system includes: a central gateway, a vehicle state control module, and a vehicle state monitoring module that are communicatively connected, where after receiving a state-to-be-adjusted signal, the central gateway sends a control instruction to the vehicle state control module and/or the vehicle state monitoring module; the vehicle state control module and/or the vehicle state monitoring module adjust/adjusts, according to the control instruction, a state of the vehicle with a battery to be swapped; and the vehicle state monitoring module obtains an adjusted vehicle state of the vehicle with a battery to be swapped, and determines whether the vehicle state is a preset vehicle state required for a battery swap process of the vehicle with a battery to be swapped. In the invention, various control modules in the vehicle with a battery to be swapped are communicatively connected, to implement automatic adjustment of a state of the vehicle, so that the state of the vehicle with a battery to be swapped can be quickly and accurately adjusted to a state required for a battery swap process.

Systems, methods and apparatus of integrated image sensing devices. In one example, a system includes a sensor that generates data. A memory device stores the generated data, and further stores a first portion of an artificial neural network (ANN). A host interface of the system is configured to communicate with a host system that stores a second portion of the ANN. The memory device can be stacked with the sensor. The memory device includes an inference engine configured to generate inference results using the stored data as input to the first portion of the ANN. The host interface is further configured to send the inference results to the host system for processing by the host system using the second portion of the ANN.

In a driving support device, an image output unit outputs an image including a host vehicle object representing a host vehicle and a nearby vehicle object representing a nearby vehicle, to a display unit. The operation signal input unit receives an operation of a user for changing a distance between the host vehicle object and the nearby vehicle object in the image displayed on the display unit. The command output unit outputs a command for instructing one vehicle to travel following another vehicle when the distance between the host vehicle object and the nearby vehicle object is equal to or less than a predetermined distance, to an automatic driving control unit that controls automatic driving.

When the driving mode of a vehicle is switched from an automatic driving mode to a manual driving mode in response to steering of the steering wheel by a driver while the vehicle is traveling in the automatic driving mode, a control device determines whether a recognized steering angle which is the steering angle of the steering wheel recognized by the driver is near a neutral position or near a one turn position according to the grip positions on the steering wheel, and when the determined recognized steering angle differs from an actual steering angle, the control device changes a ratio between the steering angle of the steering wheel and a steered angle of a wheel such that the steered angle approaches a recognized steered angle corresponding to the recognized steering angle.