External adjustment device for distraction device

What is claimed is: 1. A controller, for magnetically generating rotational motion in a remote device, comprising: a first driver magnet, having a first elongate rotational axis, a north pole on a first side of the rotational axis, a south pole on a second side of the rotational axis and a first central magnetic axis extending transversely to the rotational axis and through the centers of the north and south poles; a second driver magnet, having a second elongate rotational axis, a north pole on a first side of the rotational axis, a south pole on a second side of the rotational axis and a second central magnetic axis extending transversely to the rotational axis and through the centers of the north and south poles; and a drive system for synchronous rotation of the first and second driver magnets about the first and second rotational axes; wherein the first and second central magnetic axes are oriented at an angular offset relative to each other. 2. The controller as in claim 1 , wherein at least one of the first and second driver magnets is a permanent magnet. 3. The controller as in claim 1 , wherein at least one of the first and second driver magnets is an electromagnet. 4. The controller as in claim 1 , further comprising a control mechanism for adjusting the angle between the first and second central magnetic axes. 5. The controller as in claim 4 , wherein the control mechanism is manually adjustable. 6. The controller as in claim 4 , wherein the control mechanism is automatically adjustable. 7. The controller as in claim 6 , wherein the control mechanism is automatically adjustable in response to a signal transmitted from the remote device. 8. The controller as in claim 7 , wherein the signal transmitted from the remote device indicates insufficient rotational motion in the remote device. 9. The controller as in claim 1 , further comprising a third magnet. 10. The controller as in claim 9 , wherein the third magnet is vertically offset from the first and second magnets. 11. The controller as in claim 10 , wherein the first, second and third magnets are arranged in a Halbach array. 12. A controller, for magnetically generating rotational motion in a remote device, comprising: a first driver magnet, having a first elongate rotational axis, a north pole on a first side of the rotational axis, a south pole on a second side of the rotational axis and a first central magnetic axis extending transversely to the rotational axis and through the centers of the north and south poles; a second driver magnet, having a second elongate rotational axis, a north pole on a first side of the rotational axis, a south pole on a second side of the rotational axis and a second central magnetic axis extending transversely to the rotational axis and through the centers of the north and south poles; a third driver magnet vertically offset from the first and second driver magnets; and a drive system for synchronous rotation of the first and second driver magnets about the first and second rotational axes; wherein the first and second central magnetic axes are oriented to maintain a bilaterally asymmetric magnetic flux density so as to shape the magnetic field produced by the first and the second driver magnets. 13. The controller as in claim 12 wherein the first, second and third driver magnets are arranged in a Halbach array. 14. An adjustable flux field controller for magnetically generating rotational motion in a remote device, comprising: first and second magnets which collectively generate a three dimensional flux field surrounding the magnets, each of the first and second magnets rotatable about respective first and second rotational axes; and a control unit for adjusting the relative rotational orientation of at least one of the first and second magnets to the other of the first and second magnet; wherein adjustment of the relative rotational orientation changes the shape of the three dimensional flux field. 15. The controller as in claim 14 , wherein at least one of the first and second magnets is a permanent magnet. 16. The controller as in claim 14 , wherein at least one of the first and second magnets is an electromagnet. 17. The controller as in claim 14 , further comprising a control mechanism for adjusting the angle between the first and second rotational axes. 18. The controller as in claim 17 , wherein the control mechanism is manually adjustable. 19. The controller as in claim 17 , wherein the control mechanism is automatically adjustable. 20. The controller as in claim 19 , wherein the control mechanism is automatically adjustable in response to a signal transmitted from the remote device.