A system and method for detecting a hands-off state of a steering wheel may include acquiring, by a controller, a steering torque, a steering angle and a steering angular speed while driving of a vehicle, determining, by the controller, a variance value of the steering angular speed through cumulation for a designated time, determining, by the controller, a difference value between a steering angular speed estimated through a steering system model determined on an assumption that the steering wheel is in the hands-off state and a measured steering angular speed through cumulation for a designated time, when the variance value of the steering angular speed is less than a first threshold value, and divisionally determining, by the controller, whether or not the steering wheel is in the hands-off state or in the hands-on state according to the difference value between the measured and estimated steering angular speeds.

A remote operating system is equipped with an automatically operated vehicle and a remote operating device. A first processor of the automatically operated vehicle calculates a target steering angle of a first steering unit on the vehicle side during the performance of automatic operation control. A first communication device transmits the target steering angle to the remote operating device. A second processor on the remote operating device side controls an electric motor in such a manner as to generate a driving torque for making a steering angle of a second steering unit coincident with the target steering angle, during the execution of a cooperative mode in which a turning actuator on the vehicle side is controlled through cooperation between remote operation control for controlling the turning actuator based on the steering angle of the second steering unit steered by an operator and the automatic operation control.

An autonomous driving control device is capable of starting an autonomous driving control without an operation of a driver and reducing a possibility that the driver can not start manual driving. An autonomous driving control is switched to manual driving when a determination section determines that the amount of operation by the driver is equal to or greater than a first threshold, before a predetermined time elapses since the autonomous driving control is automatically started. An autonomous driving control is switched to a manual driving when the determination section determines that the amount of operation by the driver is equal to or greater than a second threshold that is greater than the first threshold, after the predetermined time elapses.

A system for a vehicle, having a driver monitoring device with a sensor device and with a first camera, an environment detection device with sensors for surroundings acquisition, a control unit and a classifier. Using the environment detection device and the classifier, traffic scenarios A and B may be classified. Using the driver monitoring device, it is possible to determine whether a direction of view of the driver is directed towards a traffic situation and whether the driver has their hands on a steering wheel of the vehicle. Using the control unit, it is possible, on the basis of information from the driver monitoring device and the environment detection device, to determine whether the driver is capable of resolving the traffic scenario classified as A or B within a response time.

In a cruise assist system, a turning angle controller executes at least one of an automatic cruise control task that automatically controls a turning angle of the vehicle, and an assist control task that controls the turning angle of the vehicle in accordance with an occupant's operation of the steering wheel. A holding determiner includes an input detector detecting an occupant's physical input to a steering shaft via a steering wheel based on at least one of a first type physical quantity and second type physical quantities. Each of the first and second physical quantities depends on rotational movement of the steering shaft. The first type physical quantity contains the occupant's physical input, and a disturbance input, which is different therefrom, to the steering shaft. The second type physical quantities have a physical relationship therebetween, which is changed depending on the occupant's physical input.

A drive assist apparatus includes a surrounding situation recognition device, a surrounding situation determination processor, a steering-wheel holding state recognizer, a steering-wheel holding state determination processor, and a traveling control device. The surrounding situation recognition device recognizes a surrounding situation of a first vehicle to be applied with the apparatus. The surrounding situation determination processor determines the surrounding situation based on a recognition result of the surrounding situation recognition device. The steering-wheel holding state recognizer recognizes a steering-wheel holding state. The steering-wheel holding state determination processor determines the steering-wheel holding state on the basis of a recognition result of the steering-wheel holding state recognizer. The traveling control device executes a traveling control for emergency in a case where the surrounding situation determination processor or the steering-wheel holding state determination processor determines that the first vehicle or a driver of the first vehicle is unable to maintain normal traveling.

A turn assist device is configured to execute a turn assist process that assists turning of a vehicle in a case in which a steering operation of a steering wheel is in progress in a situation in which collision prediction time is shorter than or equal to determination prediction time. The turn assist process includes: an in-phase process that outputs a command for steering a rear wheel in the same direction as a steering direction of a front wheel, and a counter-phase process that outputs a command for steering the rear wheel in a direction opposite to the steering direction of the front wheel when a difference between an actual value of the lateral acceleration of the vehicle and a lateral acceleration target value exceeds a difference determination value during execution of the in-phase process.

A computer includes a processor and a memory storing instructions executable by the processor to determine, for a host vehicle operating in a first operation mode, a first operation mode transition location based on a time to transition the host vehicle from the first operation mode to a second operation mode, a current speed of the host vehicle, and a distance from the host vehicle to an operation mode transition boundary location, to determine a second operation mode transition location that is a specified distance from the first operation mode transition location, the specified distance based on the current host vehicle speed, to transition from the first operation mode to the second operation mode upon reaching the first operation mode transition location, and to transition from the second operation mode to the first operation mode when the second operation mode transition location is between a current location of the host vehicle and the operation mode transition boundary location.

An apparatus may include a driving information input unit for receiving driving information generated while a vehicle travels, a steering angle location control unit for receiving a command steering angle for autonomous driving and a current motor steering angle of a driving motor and outputting an autonomous driving command through location control, and a motor-driven power steering control unit for driving the driving motor based on the autonomous driving command in an autonomous driving mode, determining whether a driver intervenes in steering, based on the driving information during the autonomous driving, computing a driver command according to the driver' steering based on a result of the determination, computing a compensation output between the autonomous driving command and the driver command by applying a weighting according to a steering angular speed, and making a mode transition from the autonomous driving mode to a driver mode while driving the driving motor.

A device and method for detecting short-circuit between sub-systems in a distribution system, and a distribution system including the same are disclosed. A device for detecting short-circuit may include a first sensor, a first electronic control unit (ECU) electrically connected to the first sensor, and a first signal line connecting the first sensor and the first ECU. The first ECU may perform initialization for initial configuration setting when receiving a first sensor signal through the first signal line, and may perform, when executing a specific periodic function, a short-circuit detection with a second sub-system, which is another sub-system included in the distribution system, by comparing a difference value between a current system timer value when receiving a current sensor signal and a previous system timer value when receiving a previous sensor signal with a threshold value or range.