Hybrid vehicle controller and method of controlling a hybrid vehicle

The invention claimed is: 1. A controller operable to control a hybrid electric vehicle (HEV) to assume one of a plurality of modes of operation in each of which each of a plurality of actuators of the HEV is controlled to assume a prescribed operational state, the plurality of actuators including at least one fuel burning actuator and at least one electric machine, the controller being configured to control the HEV to assume a selected one of the plurality of operational modes based on data pertaining to a route of a journey to be made by the HEV, the route comprising a plurality of route segments, the controller being configured to determine, for an end of each of said plurality of route segments, a target state of charge of an energy storage device of the HEV that is to be achieved based on the data pertaining to the route, the controller being further configured to control the HEV to achieve the target state of charge at the end of said at least one route segment, and the controller being further configured to monitor a deviation of an actual state of charge of the energy storage device at an end of a given one of the plurality of route segments from the target state of charge for the given one of the plurality of route segments, and to detect whether a fault exists with the vehicle responsive to the deviation, and to recalculate a required operational mode for at least one of the remaining ones of the plurality of route segments in response to the deviation. 2. The controller of claim 1 , configured to select the target state of charge of the energy storage device in response to data in respect of an amount of energy consumed by the plurality of actuators and a change in state of charge of the energy storage device in each operational mode as a function of vehicle speed. 3. The controller of claim 1 , operable to select the target state of the energy storage device in response to data in respect of an amount of energy consumed by the plurality of actuators and a change in state of charge of the energy storage device in each operational mode at an expected speed of a vehicle over a route segment. 4. The controller of claim 1 , operable to select the target state of charge responsive to data in respect of a type of a driver. 5. The controller of claim 4 , operable to determine the type of the driver responsive to at least one selected from amongst an identity of a device carried by the driver, an input provided by the driver and a driving style of the driver. 6. The controller of claim 1 , configured to set the target value of state of charge of the energy storage device that is to be achieved at a destination of a vehicle in response to data in respect of a particular destination. 7. The controller of claim 6 , configured to set the target state of charge in response to a determination whether the energy storage device will be recharged at the destination. 8. The controller of claim 7 , operable to determine whether the energy storage device will be recharged at the destination in response to at least one selected from amongst data in respect of a historical journey made by the vehicle, a database of recharging facilities and an input received from a user. 9. The controller of claim 1 , arranged to determine, for each operational mode of the HEV, an amount of energy that would be required to complete each route segment in that mode and a change in state of charge of the energy storage device over a route segment at a prescribed average speed in that mode said speed being a speed in respect of each route segment, the controller being further configured to determine an optimum operational mode for each route segment and an optimum target state of charge value of the energy storage device that is to be achieved by the end of each route segment according to one or more optimisation control algorithms. 10. The controller of claim 9 arranged to apply the control algorithm thereby to minimise a total amount of energy consumed by the plurality of actuators over the route. 11. The controller of claim 9 , further configured to apply a deterministic dynamic programming control algorithm to determine which of the HEV operational modes should be employed over each route segment of the journey. 12. The controller of claim 1 , wherein data pertaining to said at least one route segment is selected from amongst a length thereof, a type of road thereof, an expected average speed of a HEV therealong, an expected variance of speed of a HEV therealong, an expected average journey time therealong and an indication whether a route segment corresponds to a built-up area. 13. The controller of claim 1 , configured to determine the target value of state of charge of the energy storage device to be achieved at the end of each route segment in order to improve one or more performance parameters of the HEV relative to operation in a HEV mode in which only at least one fuel burning actuator is switched on and employed to provide traction to drive the HEV for each route segment of the journey. 14. The controller of claim 13 , wherein the one or more performance parameters correspond to one or more selected from amongst an amount of a given gas emitted by at least one fuel burning actuator of the vehicle over the course of a journey, an amount of fuel consumed by at least one fuel burning actuator over the course of a journey and an amount of time for which at least one fuel burning actuator is switched on over the course of a journey. 15. The controller of claim 1 , wherein the route comprises a plurality of route segments, the controller being configured to determine a respective target value of state of charge of the energy storage device of the HEV for each route segment that is to be achieved at the end of each route segment. 16. The controller of claim 1 , further configured to determine that the at least one electric machine is not charging the energy device at an expected rate of charge for a given torque loading applied to the at least one fuel burning actuator by the at least one electric machine and to increase the torque loading applied by the at least one electric machine to the at least one fuel burning actuator, thereby to generate an increased rate of charging of the energy storage device. 17. A hybrid electric vehicle (HEV), comprising: a plurality of actuators including at least one fuel burning actuator and at least one electric machine; and a controller operable to control the HEV to assume one of a plurality of modes of operation in each of which each of the plurality of actuators is controlled to assume a prescribed operational state, wherein the controller is configured to control the HEV to assume a selected one of the plurality of operational modes based on data pertaining to a route of a journey to be made by the HEV, the route comprising a plurality of route segments, the controller being configured to determine, for an end of each of said plurality of route segments, a target state of charge of an energy storage device of the HEV that is to be achieved based on the data pertaining to the route, wherein the controller is configured to control the HEV to achieve the target state of charge at the end of said at least one route segment, and wherein the controller is configured to monitor a deviation of an actual state of charge of the energy storage device at an end of a given one of the plurality of route segments from the target state of charge for the given one of the plurality of route segments, and to detect whether a fault exists with the vehicle responsive to the deviation, and to recal