Method and apparatus for operating an electric motor

What is claimed is: 1. An electric motor comprising: a stator comprising a plurality of stator teeth, each stator tooth having a stator coil mounted thereto; a rotor comprising a plurality of rotor teeth, the rotor being arranged to rotate relative to said stator during operation of the electric motor such that one or more of the rotor teeth periodically overlap with one or more of the stator teeth; control circuitry to energise the stator coils of a subset of the stator teeth during a given time period to attract a rotor tooth into alignment with each of the stator teeth in the subset over the given time period, wherein the control circuitry is configured to commence energization of a stator coil of at least one stator tooth in the subset during a portion of the given time period prior to the at least one stator tooth completely overlapping a corresponding rotor tooth; and driver circuitry to generate pulse signals to energize said stator coils, wherein the driver circuitry comprises boost generation circuitry to energize the stator coil of the at least one stator tooth during the given time period, buck circuitry to energize the stator coil of the at least one stator tooth during a time period subsequent to the given time period, and a storage capacitor to charge responsive to energy applied to the stator coil of the at least one stator tooth during the given time period and discharge into the stator coil of the at least one stator tooth during the time period subsequent to the given time period. 2. The electric motor according to claim 1 , wherein the stator coil of the at least one stator tooth is not energised during a portion of the given time period when the at least one stator tooth at least partially overlaps the corresponding rotor teeth. 3. The electric motor according to claim 1 , wherein the control circuitry is configured to further energise the stator coils of a second, different, subset of the stator teeth during a second time period, wherein the control circuitry is configured to energise a stator coil of at least one stator tooth in the second subset during a portion of the second time period before the stator teeth in the second subset overlap corresponding rotor teeth. 4. The electric motor according to claim 1 , wherein the control circuitry is configured to energise the stator coils of the plurality of stator teeth during a period of rotation of the rotor before the corresponding rotor teeth overlap with each respective stator tooth in the plurality of stator teeth. 5. The electric motor according to claim 1 , wherein the control circuitry is configured to energise stator coils of at least two of the stator teeth in the subset at different points during the given time period. 6. The electric motor according to claim 5 , wherein the control circuitry is configured to energise the stator coils of the at least two stator teeth for non-overlapping portions of the given time period. 7. The electric motor according to claim 5 , wherein the control circuitry is configured to energise the stator coils of the at least two stator teeth during the portion of the given time period before the stator teeth in the subset overlap the corresponding rotor teeth. 8. The electric motor according to claim 5 , wherein the control circuitry is configured to energise the stator coil of at the least one of the stator teeth in the subset during a portion of the given time period when the stator teeth in the subset at least partially overlap the corresponding rotor teeth. 9. The electric motor according to claim 1 , wherein the stator teeth in the subset are equally spaced circumferentially about the stator. 10. The electric motor according to claim 9 , wherein the stator teeth in the first subset are arranged to each overlap a corresponding rotor tooth at substantially the same time during rotation of the rotor. 11. The electric motor according to claim 1 , wherein the rotor tooth corresponding to a given stator tooth comprises a rotor tooth among the plurality of rotor teeth which is nearest to the given stator tooth at a given point in time during rotation of the rotor. 12. Circuitry for an electric motor comprising: driver circuitry to selectively energise stator coils of a stator having a plurality of stator teeth, each stator tooth having one of said stator coils mounted thereon; and control circuitry to cause the driver circuitry to energise stator coils of a subset of the stator teeth during a given time period to attract a corresponding rotor tooth into alignment with each of the stator teeth in the subset over the given time period, wherein the control circuitry is configured to trigger the driver circuitry to commence energization of the stator coil of at least one stator tooth in the subset during a portion of the given time period prior to the at least one stator tooth completely overlapping the corresponding rotor tooth, and wherein the driver circuitry comprises boost generation circuitry to energize the at least one stator coil during the given time period, buck circuitry to energize the at least one stator coil during a time period subsequent to the given time period, and a storage capacitor to charge responsive to energy applied to the at least one stator coil during the given time period and discharge into the at least one stator coil during the time period subsequent to the given time period. 13. A method of operating an electric motor, comprising: selectively energising the coils of a stator having a plurality of stator teeth, each stator tooth having one of said coils mounted thereon, the selectively energising comprising: energising the stator coils of a subset of the stator teeth during a given time period to attract a corresponding rotor tooth into alignment with a stator tooth in the subset over the given time period, wherein energization of the stator coil of at least one stator tooth in the subset commences during a portion of the given time period prior to the at least one stator tooth completely overlapping the corresponding rotor tooth; charging a storage capacitor responsive to energy applied to the stator coil of the at least one stator tooth during the given time period; and discharging the storage capacitor into the stator coil of the at least one stator tooth during a time period subsequent to the given time period to energize the stator coil of the at least one stator tooth. 14. The method according to claim 13 , wherein the stator coil of the at least one stator tooth is not energised during a portion of the given time period when the at least one stator tooth at least partially overlaps the corresponding rotor teeth. 15. The method according to claim 13 , wherein the stator teeth in the subset are equally spaced circumferentially about the stator, and wherein the stator teeth in the first subset are arranged to each overlap a corresponding rotor tooth at substantially the same time during rotation of the rotor. 16. The circuitry for the electric motor according to claim 12 , wherein the control circuitry is further configured to energise the stator coils of the plurality of stator teeth during a period of the rotation of the rotor before the corresponding rotor teeth overlap with each respective stator tooth in the plurality of stator teeth. 17. The circuitry for the electric motor according to claim 12 , wherein the control circuitry is further configured to energise the stator coils of at least two of the stator teeth in the subset of the stator teeth at different points in time during the given time period. 18. The circuitry of th