Smart trailer classification system

The invention claimed is: 1. A method, comprising: during vehicle driving, over a road segment, inferring characteristics of a trailer attached to a vehicle based on a real-time road gradient relative to an expected road gradient for the road segment; and adjusting vehicle operations based on the inferred characteristics. 2. The method of claim 1 , wherein the real-time road gradient is estimated based on a vehicle speed profile during travel over the road segment and further based on wheel contact forces of the vehicle as estimated by a powertrain controller, and wherein the inferred characteristics include a frontal area of the trailer. 3. The method of claim 2 , wherein the inferred characteristics include one or more of a weight, a size, and a frontal area of the trailer. 4. The method of claim 2 , wherein the inferring includes inferring a size of the trailer based on a difference between the real-time road gradient and the expected road gradient during vehicle travel at a steady state speed over the road segment, the inferred size increased as the real-time road gradient exceeds the expected road gradient. 5. The method of claim 2 , wherein the inferring includes inferring a weight of the trailer based on a difference between the real-time road gradient and the expected road gradient during vehicle acceleration over the road segment, the inferred weight increased as the real-time road gradient exceeds the expected road gradient. 6. The method of claim 2 , wherein the inferring includes inferring a frontal area of the trailer based on a first change in the real-time road gradient relative to a second change in the expected road gradient during vehicle deceleration over the road segment, the inferred frontal area increased as the first change exceeds the second change. 7. The method of claim 2 , wherein the inferring includes inferring the frontal area of the trailer based on a first difference between the real-time road gradient and the expected road gradient during vehicle travel at a higher steady state speed relative to a second difference between the real-time road gradient and the expected road gradient during vehicle travel at a lower steady state speed, the frontal area increased as the first difference exceeds the second difference. 8. The method of claim 2 , further comprising, estimating a first vehicle mass based on the real-time road gradient and a second vehicle mass based on the expected road gradient, wherein the inferring includes inferring a weight of the trailer based on the first mass relative to the second mass, the inferred weight increased as the first mass exceeds the second mass. 9. The method of claim 1 , wherein the expected road gradient is received from a navigation system located on-board the vehicle, the navigation system communicatively coupled to a control system of the vehicle. 10. The method of claim 9 , wherein the navigation system is further communicatively coupled to an off-board server and wherein the expected road gradient is received at the vehicle from the off-board server via the navigation system. 11. The method of claim 10 , further comprising, uploading the real-time road gradient to the off-board server and updating the expected road gradient based on the real-time road gradient. 12. The method of claim 1 , wherein adjusting vehicle operations includes adjusting one or more of a transmission gear shift schedule, engine fuel usage, and vehicle stability and sway control. 13. A method, comprising: generating an average road gradient estimate for a road segment on-board a vehicle based on wheel contact forces during vehicle travel, a confidence factor for the average road gradient estimate increased as a number of trips over the road segment increases; responsive to the confidence factor higher than a threshold, determining characteristics of a trailer attached to the vehicle based on the average road gradient estimate; and adjusting vehicle operation responsive to the trailer characteristics. 14. The method of claim 13 , wherein generating the average road gradient estimate includes determining a real-time road gradient estimate on each trip of the number of trips over the road segment, and calculating a statistical average of each real-time road gradient estimate. 15. The method of claim 14 , further comprising, responsive to the confidence factor lower than the threshold, receiving an expected road gradient estimate from an off-board server, and on a given trip, determining the trailer characteristics based on the average road gradient estimate relative to the real-time road gradient estimate. 16. The method of claim 15 , wherein determining the trailer characteristics includes: during steady-state vehicle travel, determining a size of the trailer based on a difference between the real-time road gradient estimate and the expected road gradient estimate, the size increased as the real-time road gradient estimate exceeds the expected road gradient estimate; during vehicle acceleration, determining a weight of the trailer based on the difference between the real-time road gradient estimate and the expected road gradient estimate, the weight increased as the real-time road gradient estimate exceeds the expected road gradient estimate; and during vehicle deceleration, determining a frontal area of the trailer based on a first change in the real-time road gradient estimate relative to a second change in the expected road gradient estimate, the frontal area increased as the first change exceeds the second change. 17. The method of claim 16 , wherein the adjusting includes: retarding a transmission gearshift when the trailer size is large; retarding the transmission gearshift when the trailer weight is higher than a threshold weight; and retarding the transmission gearshift when the frontal area of the trailer is larger than a threshold size. 18. A vehicle system, comprising: a vehicle with an engine; a transmission with a plurality of gearsets, the transmission coupling the engine to vehicle wheels; a trailer attached to the vehicle; a navigation system communicatively coupled to each of the vehicle and an off-board server; and a controller with computer readable instructions stored on non-transitory memory for: during vehicle travel over a road segment, estimating a real-time road gradient based on one or more of an engine torque, a powertrain torque, and a gear ratio; comparing the real-time road gradient with an expected road gradient retrieved via the navigation system; inferring one or more characteristics of the trailer based on the comparing; and adjusting a shift schedule of the transmission based on the inferred characteristics. 19. The system of claim 18 , wherein the inferring includes estimating a first vehicle mass based on the real-time road gradient, estimating a second vehicle mass based on the expected road gradient, and inferring the one or more characteristics of the trailer based on the first vehicle mass relative to the second vehicle mass, the one or more characteristics including a trailer size, a trailer weight, and a trailer frontal area. 20. The system of claim 18 , wherein the expected road gradient is a first off-board expected road gradient estimate, wherein the controller includes further instructions for: updating an on-board expected road gradient estimate based on the real-time road gradient; and updating a confidence factor of the on-board expected road gradient estimate based on a number of completed trips over the r