Systems and methods for estimating tire wear

What is claimed is: 1. A method for determining a tire tread wear estimation of a tire, comprising: receiving, by a controller, sensor data from one or more vehicle sensors in communication with the controller, wherein the controller includes a memory configured to store executable instructions to be used by the controller, and a microprocessor in communication with the memory to execute the stored executable instructions; receiving, by the controller, vehicle dynamics data from one or more vehicle systems in communication with the controller; receiving, by the controller, a direct tire tread wear measurement; performing, by the controller, an indirect tire tread wear estimation using the sensor data and the vehicle dynamics data received by the controller; performing, by the controller, a data fusion of the indirect tire tread wear estimation with the direct tire tread wear measurement received by the controller, wherein the data fusion is one of the executable instructions; estimating, by the controller, a percentage tire life remaining and a mileage to end of tire life based on the data fusion performed by the controller; estimating, by the controller, a refined tire tread wear calibration coefficient for performing future indirect tire tread wear estimations; and generating, by the controller, based on an estimated error in a tire tread wear distribution, one of a first notification to an operator of the percentage tire life remaining and mileage to end of tire life and a second notification to an operator of an unavailability of the tire tread wear estimation and an instruction to the operator to perform the direct tire tread wear measurement. 2. The method of claim 1 , wherein the data fusion of the indirect tire tread wear estimation with the direct tire tread wear measurement comprises performing, by the controller, a data fusion for a distribution of the indirect tire tread wear estimation with the direct tire tread wear measurements from tire tread grooves of the tire with a minimum tread depth remaining when the direct tire tread wear measurements are indicative of uneven wear. 3. The method of claim 1 , wherein the data fusion of the indirect tire tread wear estimation with the direct tire tread wear measurement comprises performing, by the controller, a data fusion for a distribution of the indirect tire tread wear estimation with the direct tire tread wear measurements from all available direct measurements of tire tread depths when the direct tire tread wear measurements are indicative of uniform wear. 4. The method of claim 1 , wherein the indirect tire tread wear estimation uses a recursive weighted tire slip, wherein the recursive weighted tire slip includes an accumulated longitudinal and lateral tire slip and corner-based tire slip estimation normalized by a surface of the tire and based on sensor data including one or more of a vehicle velocity, a yaw rate, a steering angle, and a wheel speed. 5. The method of claim 4 , wherein the indirect tire tread wear estimation is calculated using a tire effective radius, a pressure and temperature correction factor, a tire width, a tire type correction factor, a longitudinal slippage weight factor, a lateral slippage weight factor, a calibration coefficient, a relative longitudinal velocity, and a relative lateral velocity. 6. The method of claim 5 , wherein the indirect tire tread wear estimation includes a correction factor that is a function of a tire tread depth. 7. The method of claim 5 , wherein the indirect tire tread wear estimation includes a correction factor that is a function of a wheel alignment to estimate an effect of uneven tire tread wear. 8. The method of claim 5 , wherein the indirect tire tread wear estimation is dependent on a relative longitudinal and lateral tire slip as represented by the calibration coefficient and is not directly a function of a normal load on the tire. 9. The method of claim 1 , further comprising combining, by the controller, indirect and direct measurement data from multiple vehicles with consideration to factors including one or more of geolocation, driving behavior classification, vehicle driving conditions, environment, vehicle type, tire type, and direct measurement method to further enhance an accuracy of the tire tread wear estimation. 10. A system for determining a tire tread wear estimation of a tire, comprising: at least one sensor configured to generate sensor data indicative of a vehicle velocity, a yaw rate, a steering angle, a wheel speed, a tire pressure, and a tire temperature; and a controller including a memory configured to store executable instructions, and a microprocessor, in communication with the memory, configured to execute the stored executable instructions, the controller configured to receive a direct tire tread wear measurement; perform an indirect tire tread wear estimation based on the sensor data generated; perform a data fusion of the indirect tire tread wear estimation with the direct tire tread wear measurement, wherein the data fusion is one of the executable instructions; estimate a percentage tire life remaining and a mileage to end of tire life based on the data fusion; estimate a refined tire tread wear calibration coefficient for performing future indirect tire tread wear estimations; and generate, based on an estimated error in a tire tread wear distribution, one of a first notification to an operator of the percentage tire life remaining and mileage to end of tire life and a second notification to the operator of an unavailability of the tire tread wear estimation and an instruction to the operator to perform the direct tire tread wear measurement. 11. The system of claim 10 , wherein performing the data fusion of the indirect tire tread wear estimation with the direct tire tread wear measurement comprises performing, by the controller, a data fusion for a distribution of the indirect tire tread wear estimation with the direct tire tread wear measurements from tire tread grooves of the tire with a minimum tread depth remaining when the direct tire tread wear measurements are indicative of uneven wear. 12. The system of claim 10 , wherein the data fusion of the indirect tire tread wear estimation with the direct tire tread wear measurement comprises performing, by the controller, a data fusion for a distribution of the indirect tire tread wear estimation with the direct tire tread wear measurements from all available direct measurements of tire tread depths when the direct tire tread wear measurements are indicative of uniform wear. 13. The system of claim 10 , wherein the indirect tire tread wear estimation uses a recursive weighted tire slip, wherein the recursive weighted tire slip includes an accumulated longitudinal and lateral tire slip and corner-based tire slip estimation based normalized by a surface of the tire and based on sensor data including one or more of a vehicle velocity, a yaw rate, a steering angle, and a wheel speed. 14. The system of claim 13 , wherein the indirect tire tread wear estimation is calculated using a tire effective radius, a pressure and temperature correction factor, a tire width, a tire type correction factor, a longitudinal slippage weight factor, a lateral slippage weight factor, a calibration coefficient, a relative longitudinal velocity, and a relative lateral velocity. 15. The system of claim 10 , wherein the indirect tire tread wear estimation includes a correction factor that is a function of a tire tread depth. 16. The system of claim 10 , wherein the indirect tire tread wear estimation includes a cor