A method for operating a recuperation brake of a motor vehicle is disclosed. First, a future operating intensity of the recuperation brake is estimated for a section of route to be travelled on by the motor vehicle based on an input which characterizes the driving style of the section of route to be travelled on. In addition, a maximum slip-free vehicle braking power for the section of route is estimated as a function of the input. In addition, the braking power of the recuperation brake is set to a setpoint braking power which is not greater than the maximum vehicle braking power for the section of route, and finally the recuperation brake is activated on the section of route to be travelled on with the setpoint braking power. In addition, a recuperation brake for carrying out the method is described.

The present disclosure provides an apparatus and method for guiding a driver in coasting of an eco-friendly vehicle at an appropriate timing in a situation where deceleration is needed, which can enable economic driving through energy savings and improve the mileage and fuel efficiency of the vehicle.

The invention relates to a method for operating an environment-monitoring system for a motor vehicle, by means of which the positions of objects in the environment laterally adjacent to, in front of, and behind the vehicle are determined. According to the invention, in order to improve the accuracy of the environment-monitoring system, the motion path is determined for a stationary object which the vehicle passes, and said motion path is used to determine the angular deviation with which the motion path determined for the stationary object deviates from the motion path of the vehicle.

A driving assistance apparatus, which executes a regeneration increasing control, includes a stop position specifying unit specifying a stop position, a calculation unit calculating a predetermined position at which a speed of the vehicle reduces to a predetermined speed, a determination unit determining a start point of a deceleration distance as a notification position when a distance between an end point of the deceleration distance and the predetermined position satisfies a predetermined condition, a notification unit notifying the driver to turn off the accelerator, and a regeneration control unit starting the regeneration increasing control when the vehicle has travelled the distance that satisfies the predetermined condition from the notification position.

An approach is provided for detecting a slippery road condition based on a friction measurement. The approach, for example, involves receiving a traction loss of a vehicle traveling on the road link. The traction loss is detected using a first sensor. The approach also involves receiving a coefficient of friction between the vehicle and a road surface of the road link. The coefficient of friction is measured using a second sensor. The approach further involves fusing the traction loss with the coefficient of friction to detect the slippery road condition on the road link. The approach further involves providing the detected slippery road condition as an output.

A driver assessment system includes at least one vehicle sensor on a vehicle gathering vehicle dynamics information. At least one occupant sensor gathers driver information. The at least one occupant sensor may be a wearable device or subdermal device on the driver. At least one computer receives the vehicle dynamics information and the driver information to determine a driver readiness.

A travel control apparatus includes: a transformation unit configured to project the lane and object on a lane coordinate system in which a center line of the lane is a first coordinate axis and an axis orthogonal to the first coordinate axis is a second coordinate axis by performing a coordinate transformation based on the shape of the lane and the position of the object in a plane coordinate system; an area calculation unit configured to calculate a travelable area in which the vehicle can travel in the lane coordinate system; a travel trajectory generation unit configured to perform an inverse transformation of the coordinate transformation by the transformation unit based on the travelable area, and to generate a travel trajectory of the vehicle in the plane coordinate system; and a control unit configured to perform a steering control on the vehicle.

A method is for calculating a management setpoint for the consumption of fuel and of electric current by a hybrid motor vehicle including at least one electric motor that is supplied with electric current by a traction battery and an internal combustion engine that runs on fuel. The method includes: dividing a journey into segments; acquiring attributes for each segment; for each segment, acquiring a relationship between the fuel and electrical consumption; determining an optimal consumption point in each acquired relationship to maximize discharging the traction battery over the segments for which use of the internal combustion engine is not authorized, minimize the fuel consumption of the hybrid motor vehicle over the entire journey, and maximize the discharging of the traction battery upon completion of the journey; and developing a setpoint for power management over the entire journey, according to the coordinates of the optimal points.

An electronic system for controlling vibrations and/or inertial forces occurring at a plurality of areas of interest within an operating vehicle, the electronic device comprising circuitry configured to: receive input data comprising sensor data from one or more environment sensors (12) and/or one or more internal sensors (14); convert, by means of a machine learning system (18), the input data into actuator settings; and transmit the actuator settings to one or more actuators (20) to control vibrations and/or inertial forces occurring at each of the plurality of areas of interest within the vehicle.

A bicycle configurable for operating using a speed based control system and scheme or a torque based control system and scheme. A speed sensor or a torque sensor may detect an operating characteristic of the bicycle and a controller may determine whether to operate using a speed based control system and scheme or a torque based control system and scheme based on the operating characteristic. A signal from a speed sensor or a torque sensor may be used for determining the mechanical limits of a CVT range and when to incorporate an electric motor.