A control apparatus of a vehicle for causing an own vehicle to travel following a preceding vehicle calculates a requested acceleration of the own vehicle on the basis of a feedback requested acceleration to maintain an inter-vehicle distance at a target distance and a feedforward requested acceleration to cause the own vehicle to travel following the preceding vehicle. The apparatus calculates the feedforward requested acceleration on the basis of information on an acceleration of the preceding vehicle sent from the preceding vehicle through a wireless communication. The apparatus sets the feedforward requested acceleration to zero when a vehicle travel stabilization control is executed in the preceding vehicle to control a friction braking force applied to at least one of vehicle wheels of the preceding vehicle to stabilize a travel of the preceding vehicle, and the feedforward requested acceleration is larger than zero.

A damping control device for an electric vehicle is having a continuously variable transmission between a motor and left and right front wheels. The damping control device drive system includes a feedback control unit, which suppresses a vibration accompanying a disturbance in the rotational speed of the motor, and an operation determination unit, which determines whether or not an absolute value of a second-order differential of the transmission ratio is equal to, or greater than, a predetermined value, wherein when the absolute value of the second-order differential of the transmission ratio is equal to, or greater than, the predetermined value. The feedback control unit performs control of the output torque of the motor whereby a compensation torque component for suppressing a vibration accompanying a gear shift is subtracted from a compensation torque.

A damping control device for a hybrid vehicle is provided that make it possible to suppress behavior that differs from a request of a driver. The damping control device includes a controller that calculates an amount of change in a target driving torque, and calculates an amount of change in a target motor torque. The damping control device also includes a damping rate variation unit that sets the damping of a feed forward control unit to a first damping rate when the target driving torque change amount and the target motor torque change amount both are positive or negative, and to a second damping rate, which is smaller than the first damping rate, when the target driving torque change amount and the target motor torque change amount have opposite positivity or negativity.

A safety stoppage device and method for safety stoppage of an autonomous vehicle including control networks and sensors for monitoring the autonomous vehicle surroundings and motion includes a brake-control unit for a brake system including wheel brakes of the autonomous vehicle, and a signaling processing system for processing sensor signals enabling an autonomous drive mode thereof. Where a drivable space exists is predicted based on data from the sensors and sensor fusion, and a safe trajectory to a stop within the drivable space is calculated and sent to the brake-control unit and stored therein. The brake-control unit is shielded against electromagnetic compatibility problems and configured to monitor if the control networks are operational and, if determined incapacitated, control the autonomous vehicle to follow the most recently calculated safe trajectory to a stop within the drivable space using differential braking of the wheel brakes thereof in order to effectuate steering.

A method according to an exemplary aspect of the present disclosure includes, among other things, controlling a torque output of an electric machine of an electrified vehicle during a vehicle creep condition, the torque output calculated based at least on a road grade estimate and a vehicle mass estimate.

Methods, systems, and apparatuses are provided for controlling longitudinal and/or lateral guidance of a vehicle. A trajectory planner is configured to ascertain setpoint trajectory variables for a trajectory of the vehicle. The setpoint trajectory variables include a first trajectory state and a second trajectory state. The second trajectory state corresponds to a change in the first trajectory state over time. A feed-forward controller is configured to calculate a feed-forward control variable from the setpoint trajectory variables and from a model of dynamic behavior of the vehicle. The feed-forward control variable and the first trajectory state are variables of the same type. The device is configured to use the feed-forward control variable as a basis for determining a manipulated variable for a controlled system within the scope of the longitudinal and/or lateral guidance. The manipulated variable and the feed-forward control variable are variables of the same type.

A vehicular driving assistance system includes a camera viewing exterior of a vehicle and capturing image data. The system, via processing captured image data as the vehicle travels along a current traffic lane, determines a current lateral position of the vehicle within the current traffic lane and determines a target lateral position of the vehicle within the current traffic lane. The system determines a steering command to guide the vehicle from the current lateral position to the target lateral position and determines a steering angle offset required to maintain the target lateral position within the current traffic lane and stores the determined steering angle offset in nonvolatile memory. After storing the determined steering angle offset and when the vehicle is traveling during a subsequent trip, the system determines a second target lateral position of the vehicle within the current traffic lane and applies the stored steering angle offset.

A system for operating a hybrid electric vehicle includes a hybrid starter generator generating a counter-electromotive force while rotating with an engine when conditions are satisfied, including where starting of the engine is secured, a main relay is turned off, and an engine clutch is opened according to a request for reverse traveling, in a state where a component of a high-voltage system is failed, a motor reversely rotating using the counter-electromotive force of the hybrid starter generator, an electronic load component operated using the counter-electromotive force of the hybrid starter generator, and a controller determining an engine speed required by load output values according to operations of the motor and the electronic load component, and restricting the operation of the motor or the electronic load component according to a determined engine speed.

In various example embodiments, a system and method for determining a total weight of a vehicle, transmitting the total weight measured to the vehicle's autonomous control system, and controlling the vehicle according to the total weight of the vehicle. The system and method further transmits information between separate vehicles with similar autonomous control systems. A method includes: providing predetermined calibration settings relating drive force to motor speed for a vehicle travelling at various speeds, determining that one or more vehicle performance parameters fall within a threshold range, determining the vehicle's longitudinal acceleration and drive force, determining a total weight comprising a weight of the vehicle and a weight being hauled by the vehicle; transmitting the total weight to the autonomous control system, and controlling the vehicle according to total weight of the vehicle.

A hybrid powertrain includes an engine having a crankshaft, and an electric motor having a rotor selectively coupled to the crankshaft via a disconnect clutch and configured to operate in torque control and in speed control. The powertrain further includes a transmission having a torque converter with an impeller fixed to the rotor, a turbine disposed on an input shaft of the transmission, and a bypass clutch configured to selectively transmit torque from the impeller to the turbine. A controller is configured to, in response to the motor switching from torque control to speed control, generate a torque command for the motor that defines a magnitude derived from an error between measured and estimated speeds of the impeller obtained during torque control to prevent a spike in motor speed when the motor switches from torque control to speed control.