Method of estimating brake pad wear and vehicle having a controller that implements the method

The invention claimed is: 1. A method of estimating brake pad wear on a vehicle, the method comprising: determining, via an electronic controller, required braking energy to be dissipated by a braking system of the vehicle as a fraction of total kinetic energy of the vehicle according to an energy partitioning model; determining, via the electronic controller, a distribution of the required braking energy to multiple vehicle braking mechanisms on the vehicle according to a vehicle dynamics model; wherein the vehicle dynamics model: determines whether the square root of the sum of the square of lateral acceleration of the vehicle and the square of longitudinal acceleration of the vehicle is greater than a predetermined traction threshold, and distributes braking energy according to available vertical force at each wheel of the vehicle if the square root of the sum of the square of lateral acceleration of the vehicle and the square of longitudinal acceleration of the vehicle is greater than the predetermined traction threshold; wherein each of the multiple vehicle braking mechanisms has a brake rotor and a brake pad; determining, via the electronic controller, rotor temperature of each brake rotor according to a rotor temperature model that utilizes the required braking energy and the distribution of the required braking energy; determining, via the electronic controller, brake pad wear of each brake pad according to a brake pad wear model; indicating the brake pad wear via a brake pad wear indicator output device; and wherein the energy partitioning model, the vehicle dynamics model, the rotor temperature model, and the brake pad wear model are representative of vehicle conditions when the rotor temperature is greater than a predetermined minimum rotor temperature, braking speed is greater than a predetermined minimum braking speed, and the required braking energy is greater than a predetermined minimum braking energy; wherein the energy partitioning model, the vehicle dynamics model, the rotor temperature model and the brake pad model are utilized for said determining the required braking energy to be dissipated, determining the distribution of the required braking energy, determining the rotor temperature, and determining the brake pad wear, respectively, only when the predetermined minimum rotor temperature and the predetermined minimum braking speed are exceeded a predetermined number of times within a predetermined time period, or the braking energy exceeds the predetermined minimum braking energy for a predetermined minimum period of time; and wherein an alternative brake pad wear model is utilized when the predetermined minimum rotor temperature and the predetermined minimum braking speed are not exceeded the predetermined number of times within the predetermined time period, and the braking energy does not exceed the predetermined minimum braking energy for the predetermined minimum period of time. 2. The method of claim 1 , wherein the energy partitioning model, the vehicle dynamics model, the rotor temperature model and the brake pad model are utilized for said determining the required braking energy to be dissipated, determining the distribution of the required braking energy, determining the rotor temperature, and determining the brake pad wear, respectively in response to operator selection even if the predetermined minimum rotor temperature and the predetermined minimum braking speed are not exceeded the predetermined number of times within the predetermined time period, and even if the braking energy does not exceed the predetermined minimum braking energy for the predetermined minimum period of time. 3. The method of claim 1 , wherein the predetermined minimum rotor temperature is representative of vehicle operation in a first driving mode; wherein the rotor temperature model is representative of vehicle operation in a second driving mode; and wherein braking speeds and braking energy in the second driving mode are greater than braking speeds and braking energy in the first driving mode. 4. The method of claim 3 , wherein the rotor temperature model used in the second driving mode includes a lumped capacitance model of rotor specific heat capacity with cooling coefficients less than cooling coefficients used in the first driving mode. 5. The method of claim 1 , wherein the brake pad wear model determines an amount of linear wear of each brake pad per a predetermined amount of time by reference to stored linear wear data or by reference to a fitted linear wear equation. 6. The method of claim 1 , wherein the energy partitioning model is based at least partially on gear ratio, vehicle speed, and braking energy. 7. The method of claim 1 , further comprising: receiving a sensor signal indicative of a predetermined amount of actual brake pad wear; comparing brake pad wear determined according to the brake pad wear model to the predetermined amount of actual brake pad wear; and revising the brake pad wear model wear based on the comparison to the predetermined amount of actual brake pad wear. 8. A method of estimating brake pad wear on a vehicle, the method comprising: determining, via an electronic controller, brake pad wear according to a first brake pad wear model when an estimated brake rotor temperature is less than or equal to a predetermined minimum rotor temperature; and determining, via the electronic controller, brake pad wear according to a second brake pad wear model different than the first brake pad wear model, when the estimated brake rotor temperature is greater than the predetermined minimum rotor temperature; wherein said determining, via the electronic controller, brake pad wear according to the second brake pad wear model includes: determining, via the electronic controller, required braking energy to be dissipated by a braking system of the vehicle as a fraction of total kinetic energy of the vehicle according to an energy partitioning model; and determining, via the electronic controller, a distribution of the required braking energy to multiple vehicle braking mechanisms on the vehicle according to a vehicle dynamics model; wherein the vehicle dynamics model determines whether the square root of the sum of the square of lateral acceleration of the vehicle and the square of longitudinal acceleration of the vehicle is greater than a predetermined traction threshold and, distributes braking energy according to available vertical force at each wheel of the vehicle if the square root of the sum of the square of lateral acceleration of the vehicle and the square of longitudinal acceleration of the vehicle is greater than the predetermined traction threshold; wherein each of the multiple vehicle braking systems has a brake rotor and a brake pad; wherein the second rotor temperature model utilizes the required braking energy and the distribution of the required braking energy; wherein the second rotor temperature model and the second brake pad wear model are representative of vehicle conditions when the rotor temperature is greater than a predetermined minimum rotor temperature, braking speed is greater than a predetermined minimum braking speed, and the required braking energy is greater than a predetermined minimum braking energy; and indicating the brake pad wear via a brake pad wear indicator output device. 9. The method of claim 8 , wherein said determining brake pad wear according to the first brake pad wear model is only when braking speed is less than or equal to the predetermined minimum braking speed, and the required braking energy is less than or equal to the predetermined minimum braking energy; and wherein said determining brake pad wear according to the second brake pad wear model