Controller and method

The invention claimed is: 1. A motor vehicle controller comprising a data processing apparatus, the data processing apparatus comprising: a first electrical connection terminal receiving a surface friction signal indicative of a coefficient of friction between a road wheel and a driving surface from a wheel sensor or a first controller; and a second electrical connection terminal receiving from an accelerator an input accelerator position signal indicative of a position of the accelerator with respect to an allowable range of positions; the data processing apparatus being configured to determine a powertrain torque limit value corresponding to an amount of powertrain torque at which the data processing apparatus determines that slip of a driving wheel will exceed a predetermined amount of slip, the powertrain torque limit value being determined at least in part in dependence on the surface friction signal; the data processing apparatus being configured to determine and output a powertrain torque demand signal corresponding to an instant amount of torque to be developed by a powertrain, the powertrain torque demand signal being determined in dependence at least in part on the input accelerator position signal according to a predetermined relationship between the powertrain torque demand signal and the input accelerator position signal, the data processing apparatus being further configured to determine a target accelerator position signal corresponding to the powertrain torque limit value, according to the predetermined relationship between the powertrain torque demand signal and the input accelerator position signal, the controller being configured such that when the input accelerator position signal approaches the target accelerator position signal and the input accelerator position signal has a value that is within a predetermined range of the target accelerator position signal corresponding to the powertrain torque limit value, such that the powertrain torque demand signal is within a predetermined range of the powertrain torque limit value, the relationship between powertrain torque demand signal and input accelerator position signal is modified relative to the predetermined relationship between the powertrain torque demand signal and the input accelerator position signal such that a response of the powertrain torque demand signal to the input accelerator position signal is reduced. 2. A controller according to claim 1 wherein the predetermined range corresponds with a predetermined proportion of the target accelerator position signal. 3. A controller according to claim 1 wherein the predetermined range corresponds with a predetermined proportion of one selected from amongst the powertrain torque limit value and the powertrain torque demand signal. 4. A controller according to claim 1 configured wherein the predetermined amount of slip is determined by the data processing apparatus in dependence at least in part on the surface friction signal. 5. A controller according to claim 4 configured to receive a reference speed signal indicative of an instant vehicle speed, the controller being configured to determine the predetermined amount of slip in further dependence on the reference speed signal. 6. A controller according to claim 1 configured to receive a terrain signal indicative of a nature of terrain over which a vehicle is driving, the controller being configured to determine the predetermined amount of slip in further dependence on the terrain signal and wherein the terrain signal comprises one or more of a signal indicative of an amount of drag on a vehicle and a driving mode signal indicative of a driving mode in which a vehicle is operating. 7. A motor vehicle control system comprising a controller according to claim 6 wherein the driving mode in which the vehicle is operating is one of a plurality of driving modes, the plurality of driving modes being a plurality of subsystem control modes of at least one subsystem of a plurality of subsystems of the vehicle, the control system having a subsystem controller for initiating control of a vehicle subsystem in a selected one of the plurality of subsystem control modes, each one of the driving modes corresponding to one or more different driving conditions for the vehicle and wherein in each subsystem control mode the system is configured to cause the at least one subsystem of the plurality of vehicle subsystems to be operated in a subsystem configuration mode in dependence on the one or more different driving conditions, said plurality of driving modes including one or more of the following: a plurality of subsystem control modes of at least one vehicle subsystem selected from amongst an engine management system, a transmission system, a steering system, a brakes system and a suspension system; a plurality of subsystem control modes of a suspension system, wherein the subsystem configuration mode is one of a plurality of subsystem configuration modes and the plurality of subsystem configuration modes provide a plurality of ride heights; a plurality of subsystem control modes of a fluid suspension system in which fluid interconnection can be made between suspensions for wheels on opposite sides of the vehicle, wherein the subsystem configuration mode is one of a plurality of subsystem configuration modes and wherein said plurality of subsystem configuration modes provide different levels of said interconnection; a plurality of subsystem control modes of a steering system which can provide steering assistance, wherein the subsystem configuration mode is one of a plurality of subsystem configuration modes and wherein said plurality of subsystem configuration modes provide different levels of said steering assistance; a plurality of subsystem control modes of a brakes system which can provide braking assistance, wherein the subsystem configuration mode is one of a plurality of subsystem configuration modes and wherein said plurality of subsystem configuration modes provide different levels of said braking assistance; a plurality of subsystem control modes of a brake control system which can provide an anti-lock function to control wheel slip, wherein the subsystem configuration mode is one of a plurality of subsystem configuration modes and wherein said plurality of subsystem configuration modes allow different levels of said wheel slip; a plurality of subsystem control modes of a powertrain system which includes a powertrain controller and an accelerator or throttle pedal, wherein the subsystem configuration mode is one of a plurality of subsystem configuration modes and wherein the plurality of subsystem configuration modes provide different levels of responsiveness of the powertrain controller to movement of the accelerator or throttle pedal; a plurality of subsystem control modes of a traction control system which is arranged to control wheel spin, wherein the subsystem configuration mode is one of a plurality of subsystem configuration modes and wherein said plurality of subsystem configuration modes allow different levels of said wheel spin a plurality of subsystem control modes of a yaw control system which is arranged to control vehicle yaw, wherein the subsystem configuration mode is one of a plurality of subsystem configuration modes and wherein said plurality of subsystem configuration modes allow different levels of divergence of said vehicle yaw from an expected yaw; a plurality of subsystem control modes of a range change transmission, wherein the subsystem configuration mode is one of a plurality of subsystem configuration modes and wherein said plurality of subsystem configuration modes may include a high range mode and a low range mode of said transmission; and a plurality of subsystem control modes of a