Control system for hybrid vehicles with high degree of hybridization

What is claimed is: 1. A hybrid vehicle, comprising: a fuel consuming engine configured to supply power to drive the hybrid vehicle; an energy storage device disposed within the hybrid vehicle, the energy storage device configured to supply power to drive the hybrid vehicle; a charging system coupled to the energy storage device and configured to charge the energy storage device; a movement system configured to provide for movement of the hybrid vehicle; a drive train coupled between the movement system and one or both of the fuel consuming engine and the energy storage device; a prediction processor configured to predict power demand to drive the hybrid vehicle based on changing conditions during operation of the hybrid vehicle, the prediction processor configured to: use a degradation model to predict degradation of one or more hybrid vehicle components of the fuel consuming engine, the drive train, the movement system, and/or the charging system of the hybrid vehicle; and revise the degradation model based on sensed changes in a condition of the one or more hybrid vehicle components; a power flow controller configured to automatically control power flow between at least one of: the fuel consuming engine and the drive train, the energy storage device and the drive train, and the fuel consuming engine and the energy storage device, so as to provide the power to drive the hybrid vehicle based at least in part on the predicted power demand and on the degradation model, wherein the power demand to drive the hybrid vehicle is greater than a maximum power available from the engine at a point in time during operation of the hybrid vehicle. 2. The hybrid vehicle of claim 1 , wherein the energy storage device comprises at least one of: a flywheel; a battery; and a capacitor. 3. The hybrid vehicle of claim 1 , wherein the changing conditions include one or more of: sensed conditions external to the hybrid vehicle; sensed conditions of the hybrid vehicle; predicted changes in one or more vehicle components; predicted conditions external to the vehicle; driver-specified conditions; energy usage from the energy storage device; energy usage by the fuel consuming engine; historical data; predicted destination; and predicted route. 4. The hybrid vehicle of claim 1 , further comprising one or more sensors coupled to the prediction processor, wherein the one or more sensors are configured to sense one or more of the changing conditions and the prediction processor is configured to predict the power demand to drive the vehicle based on the changing conditions. 5. The hybrid vehicle of claim 1 , wherein the degradation model comprises a degradation equation. 6. The hybrid vehicle of claim 1 , wherein the degradation model comprises a look up table. 7. The hybrid vehicle of claim 1 , wherein the degradation model includes multiple models, each of the multiple models associated with a component of the hybrid vehicle. 8. The hybrid vehicle of claim 1 , wherein the prediction processor is configured to revise the degradation model based on predicted changes to the one or more hybrid vehicle components. 9. The hybrid vehicle of claim 1 , further comprising a driver interface configured to: enable a driver to enter a selection between a first route that would cause a time delay in reaching the destination and a second route that would cause at least one of an increase in fuel consumption compared to the first route and an increase in vehicle emissions compared to the first route; and wherein the prediction processor is configured to use the selection to predict the power demand. 10. A hybrid vehicle control system, comprising: a prediction processor configured to predict power demand to drive a hybrid vehicle based on changing conditions during operation of the hybrid vehicle, the hybrid vehicle comprising a fuel consuming engine, an energy storage device, a charging system for the energy storage device, a movement system, and a drive train coupled between the movement system and one or both of the fuel consuming engine and the energy storage device, the prediction processor configured to: use a degradation model to predict degradation of one or more hybrid vehicle components of the fuel consuming engine, drive train, movement system, and/or charging system of the hybrid vehicle; and revise the degradation model based on sensed changes in a condition of the one or more hybrid vehicle components; and a power flow controller configured to automatically control power flow between at least one of: the engine and the drive train, the energy storage device and the drive train, and the engine and the energy storage device, so as to provide the power to drive the hybrid vehicle based at least in part on the predicted power demand and on the degradation model, wherein the power demand to drive the hybrid vehicle is greater than a maximum power available from the engine at a point in time during operation of the hybrid vehicle. 11. The hybrid vehicle control system of claim 10 , wherein the controller is further configured to control regenerative power flow to the energy storage device. 12. The hybrid vehicle control system of claim 10 , wherein: the prediction processor is configured to predict one or more conditions external to the hybrid vehicle, the one or more external conditions including traffic, weather, road conditions and traffic accidents; and the controller is configured to control power flow from the engine and the energy storage device based on predictions of the one or more external conditions. 13. The hybrid vehicle control system of claim 10 , wherein the prediction processor is configured to: collect at least one of vehicle-specific and driver-specific historical data; predict a route based on the historical data; and determine at least one drive parameter based on the predicted route, wherein the at least one drive parameter is predicted based on the predicted power demand and predicted available power associated with the predicted route, and the at least one drive parameter includes time to destination, emissions to destination, and fuel consumption to destination associated with the predicted route. 14. The hybrid vehicle control system of claim 10 , wherein the prediction processor is configured to predict a route-specific vehicle power demand associated with each of multiple potential routes, wherein the route-specific vehicle power demand is based on one or more of weather, component degradation, predicted traffic conditions, driver specified constraints on vehicle emissions, driver-specified vehicle behavior, driver-specified constraints on arrival time at the destination, driver-specified constraints on fuel consumption. 15. The hybrid vehicle control system of claim 10 , wherein the prediction processor is configured to predict the vehicle power demand using one or more of: a Monte Carlo algorithm in a model-predictive control framework; stochastic programming; an adaptive optimization control algorithm, one or more parameters of the adaptive optimization control algorithm revised based on real-time data; and an autoregressive model configured to account for differences in predicted and actual time evolution of traffic. 16. The hybrid vehicle control system of claim 10 , further comprising one or more sensors coupled to the prediction processor, wherein the one or more sensors are configured to sense at least one of a condition of the hybrid vehicle and a condition external to the hybrid vehicle. 17. A computer implemen