Electric motor with plural stator components

The invention claimed is: 1. An electric motor stator comprising: first and second stator components arranged adjacent to each other along a longitudinal central axis of the stator, each stator component having a substantially hollow cylindrical form for receiving a rotor such that said rotor can rotate about the longitudinal central axis of the stator, the first and second stator components each comprising at least two protrusions arranged at different circumferential points on an inner surface of the respective stator component, wherein the first and second stator components are arranged such that the protrusions on the first stator component are rotationally offset with respect to the protrusions on the second stator component, such that when each of the protrusions have a winding mounted thereon, a portion of a winding on the first stator component extends into a gap between windings on the second stator component. 2. An electric motor stator according to claim 1 , comprising one or more windings mounted to one or more of said protrusions. 3. An electric motor stator according to claim 2 , wherein each of said first and second stator components comprises at least twelve said protrusions, each comprising a said winding. 4. An electric motor stator according to claim 1 , wherein each of said windings of each of said at least two stator components are independently controllable. 5. An electric motor stator according to claim 4 , wherein said windings on one of said at least two stator components are powerable independently to said windings on said adjacently mounted stator component. 6. An electric motor comprising: a rotor; and the electric motor stator according to claim 1 ; said rotor being mounted within said at least two stator components on a rotational mounting such that said rotor can rotate about a longitudinal central axis with respect to said stator. 7. An electric motor controller for controlling an electric motor according to claim 6 , comprising: control circuitry to generate control signals to control power supplied to said windings on each of said at least two stator components, such that power can be controlled to each of said at least two stator components independently of each other. 8. An electric motor controller according to claim 7 , wherein said control circuitry is capable of independently controlling said power supplied to each of said windings on each of said at least two stator components in order to control output torque generated by said motor. 9. An electric motor controller according to claim 7 , wherein said control circuitry is capable of controlling said power supplied to said windings on each of said at least two stator components such that said power supplied to said windings on one of said at least two stator components is controlled independently to said power supplied to windings on said adjacently mounted stator component, and said power supplied to each winding on each of said at least two stator components is controlled independently compared to an adjacent winding. 10. An electric motor controller according to claim 8 , wherein said control circuitry comprises rotational position detection circuitry for detecting a current position of said rotor relative to each of said at least two stator components, said control circuitry being configured to control said power supplied to said windings in dependence upon said detected current position.