A cruise control arrangement is provided with a cruise control speed function and where the cruise control arrangement is provided with a set cruise speed value and a set brake cruise speed value, and where the cruise control brake function is active when the vehicle travels downhill, where the cruise control arrangement is adapted to activate at least one auxiliary brake when the vehicle speed reaches the set brake cruise speed, to apply a service brake of the vehicle in order to reduce the speed of the Vehicle to a predefined first speed if the vehicle speed exceeds the set brake cruise speed when the least one auxiliary brake is delivering full brake power, where the predefined first speed is lower than the set brake cruise speed. Undesired acceleration during downhill travel can be avoided when the brake power of the auxiliary brake is not sufficient. Further, a required downshift can be delayed, which will improve the fuel consumption of the vehicle.

A method for selecting a gear ratio for a driveline of vehicle is provided. The method comprises gathering information relating to one or more parameters associated with the vehicle and anticipating, based on the gathered information, an occurrence of an event relating to the vehicle for which a change in driveline gear ratio is needed. The method further comprises identifying a suitable driveline gear ratio for the anticipated event, generating a command signal representative of a request to change the gear ratio of the driveline to the identified gear ratio, and communicating the command signal to a driveline subsystem of the vehicle. A system comprising an electronic control unit configured to perform the method is also provided.

A cruise control arrangement for a vehicle is provided with a cruise control brake function that is set to a brake cruise speed. The cruise control arrangement is adapted to activate at least one auxiliary brake when the vehicle speed reaches the set brake cruise speed, and at the same time to apply a service brake of the vehicle to keep the speed of the vehicle at the set brake cruise speed, and is further adapted to decrease the brake power of the service brake at the same time as the brake power of the at least one auxiliary brake increases, such that the speed of the vehicle is kept at the set brake cruise speed. The speed of the vehicle can be held at the set cruise speed when an auxiliary brake is activated, regardless of the activation time of the auxiliary brake. In this way, an overshoot in speed can be avoided during the activation time of the auxiliary brake.

A speed control system for a vehicle includes an electronic controller configured to automatically cause a vehicle to operate in accordance with a target speed value. The electronic controller is further configured to receive information relating to movement of at least a portion of a vehicle body or at least a portion of a body of an occupant relative to a vehicle, and to automatically adjust the value of the target speed value in dependence on the received information.

A method for operating a speed control system of a vehicle is provided. The method comprises detecting an external force acting on the vehicle wherein the external force has an accelerating or decelerating effect on the vehicle. The method further comprises automatically adjusting a rate of change of at least one component of a net torque being applied to one or more wheels of the vehicle to compensate for the accelerating or decelerating effect of the external force on the vehicle. A system for controlling the speed of a vehicle comprising an electronic control unit configured to perform the above-described methodology is also provided.

A brake temperature detection device: acquires a kinetic-energy based temperature rise, which is an increase in an amount of brake heat that occurs when kinetic energy generated in a running vehicle is converted into thermal energy by braking; acquires a braking-energy based temperature rise, which is an increase in an amount of brake heat that is calculated from an amount of work done when a brake's friction material is pressed against a friction target material; determines state of slope of a road surface on which the vehicle is running; and detects a brake temperature in accordance with an increase in an amount of brake heat generated in braking. The brake temperature detection device selects, based on the state of slope, either the kinetic-energy based temperature rise or the braking-energy based temperature rise as the increase in the amount of brake heat generated in braking and achieves brake temperature detection.

A regenerative braking system and method are disclosed. According to certain embodiments, the regenerative braking system is engaged and adjusted when the navigation system recognizes that the vehicle is descending down a long grade. This can be pre-stored information, or information derived from prior experience or from the shared experiences of other drivers. The regenerative braking system does not engage to the full stop of the vehicle, but instead can release at approximately three mph and allows friction braking to handle the rest of the stop. The navigation system in this embodiment recognizes that a stop sign or other full-stop situation is present.

A control device of a vehicle has a hill ascent angle update determiner, a slope estimator, a deceleration determiner, and a hill ascent angle estimator. The deceleration determiner determines that a vehicle is in a deceleration state when the throttle opening is equal to or lower than a threshold. The hill ascent angle update determiner prohibits update processing of an estimated hill ascent angle in the increase direction by the hill ascent angle estimator if the slope estimator estimates that a road surface has an upward slope and the deceleration determiner determines that the vehicle is in the deceleration state.

A method for vehicle control comprises determining a braking capability of a braking system of a vehicle, and modifying application of at least one control parameter by a control system of the vehicle based on the determined braking capability. Braking capability may be determined by activating the braking system of the vehicle to apply a braking force on the vehicle, and concurrently, applying a level of tractive effort of the vehicle that is sufficient to overcome the braking force. The braking capability is determined based on the level of tractive effort.

In consideration of an amplification effect of a braking force at the time of brake operation, upper-limits (, ) of a brake operation force (Brk) with which the execution of free-run coasting and neutral coasting is started may be different, on the basis of whether or not a brake booster can be filled with a negative pressure. Therefore, while the braking force at the time of brake operation is secured, the range of the brake operation force (Brk) with which coasting is executed can be enlarged, and an improvement in fuel economy can be made.