Systems and methods to improve fuel economy using adaptive cruise in a hybrid electric vehicle when approaching traffic lights

What is claimed is: 1 . A method for controlling a vehicle, comprising: in response to an anticipated stop at a traffic signal, automatically controlling vehicle brakes to decelerate the vehicle at a braking deceleration rate; and in response to the vehicle decelerating to an intermediate speed, releasing the vehicle brakes, wherein at the intermediate speed a coasting distance to a full stop is approximately equal to a distance to the traffic signal. 2 . The method of claim 1 , wherein at the intermediate speed the coasting distance to a full stop is equal to a sum of the distance to the traffic signal and a calibratable distance threshold. 3 . The method of claim 1 , wherein the braking deceleration rate is the least of a calculated comfortable deceleration rate limit, a calculated permissible deceleration rate limit, and a regenerative braking deceleration rate associated with a regenerative braking limit. 4 . The method of claim 1 , further comprising in response to the traffic signal being a traffic light and the traffic light turning green while the vehicle brakes are automatically controlled, releasing the vehicle brakes. 5 . A vehicle comprising: traction wheels; a regenerative braking system; and a controller configured to, in response to an anticipated stop, control the regenerative braking system to decelerate the wheels at a first deceleration rate, and in response to the wheels being decelerated to an intermediate speed at the first deceleration rate, control the regenerative braking system to decelerate the wheels at a second deceleration rate less than the first deceleration rate. 6 . The vehicle of claim 5 , wherein at the intermediate speed a coasting distance to a full stop is equal to or less than a sum of a distance to the anticipated stop and a calibratable distance threshold. 7 . The vehicle of claim 5 , wherein the first deceleration rate is the least of a calculated comfortable deceleration rate limit, a calculated permissible deceleration rate limit, and a regenerative braking deceleration rate associated with a limit of the regenerative braking system. 8 . The vehicle of claim 5 , wherein the second deceleration rate is a coasting deceleration rate. 9 . The vehicle of claim 5 , wherein the anticipated stop is based on a detected traffic signal. 10 . The vehicle of claim 9 , wherein the controller is further configured to, in response to the detected traffic signal being a traffic light and the traffic light turning green while the controller is controlling the regenerative braking system to decelerate the wheels, deactivate the regenerative braking system. 11 . A method of controlling a vehicle, comprising: in response to an anticipated stop at a traffic signal and an adaptive cruise control system being active, automatically controlling regenerative brakes to decelerate the vehicle at a braking deceleration rate; and in response to a coasting distance at a current vehicle speed being approximately equal to a distance to the traffic signal, automatically controlling the regenerative brakes to decelerate the vehicle at a coasting deceleration rate. 12 . The method of claim 11 , wherein the braking deceleration rate is the least of a calculated comfortable deceleration rate limit, a calculated permissible deceleration rate limit, and a regenerative braking deceleration rate associated with a limit of the regenerative brakes. 13 . The method of claim 11 , further comprising in response to the traffic signal being a traffic light and the traffic light turning green while the regenerative brakes are automatically controlled, automatically deactivating the regenerative brakes. 14 . The method of claim 11 , wherein a magnitude of the braking deceleration rate is greater than a magnitude of the coasting deceleration rate.