Electrical contactor

The invention claimed is: 1. An electrical contactor comprising: a first terminal having a fixed member with at least one fixed electrical contact; a second terminal; an electrically-conductive movable arm in electrical communication with the second terminal and having a movable electrical contact thereon; and actuator including a centrally mounted magnet, first and second drivable coils located either side of the magnet, a magnetically-attractable rocking armature pivotable at a point between the first and second coils, and an actuation element connected to an end of the rocking armature for actuating the movable arm; a further first terminal, a further second terminal, a further movable arm, and a further actuation element, connected to a second end of the rocking armature for actuating the further movable arm, wherein driving the first coil causes a decrease of magnetic flux in the first coil, causing a corresponding increase in magnetic flux in the second coil, the rocking armature thus latching to the second coil, thereby actuating the movable arm in a first direction, and driving the second coil causes a decrease of magnetic flux in the second coil, causing a corresponding increase in magnetic flux in the first coil, the rocking armature thus latching to the first coil, thereby actuating the movable arm in a second direction, and wherein latching the rocking armature to the first coil actuates the further movable arm in the first direction, and latching the rocking armature to the second coil actuates the further movable arm in the second direction. 2. The electrical contactor of claim 1 , wherein the first and second coils are interconnected to a common center connection. 3. The electrical contactor of claim 1 , wherein the movable arm is a bladed switch. 4. The electrical contactor of claim 1 , wherein the movable arm is split into a blade set having a plurality of movable contacts. 5. The electrical contactor of claim 4 , wherein the movable arm is tri-bladed switch. 6. The electrical contactor of claim 1 , wherein the movable arm includes at least two electrically-conductive overlying layers, thereby reducing a flexure force. 7. The electrical contactor of claim 1 , wherein a contra-flowing current passes through the movable arm and the further movable arm, imparting a repulsive force supplementarily urging the movable arms apart in the contacts-closed configuration. 8. The electrical contactor of claim 1 , wherein the rocking armature includes two armlets positioned at an obtuse angle to one another. 9. The electrical contactor of claim 1 , further comprising a DC power supply for energizing the first and/or second coils, the DC power supply outputting drive pulses via a drive circuit. 10. The electrical contactor of claim 1 , further comprising an AC power supply for energizing the first and/or second coil, the AC power supply outputting drive pulses via a drive circuit. 11. The electrical contactor of claim 10 , wherein the drive pulse has a truncated waveform profile, so as to reduce erosion energy between the contacts. 12. The electrical contactor of claim 11 , wherein the drive pulse has a half-cycle waveform profile, so as to reduce erosion energy between the contacts. 13. The electrical contactor of claim 11 , wherein the drive pulse has a quarter-cycle waveform profile, so as to prevent contact separation prior to peak load current. 14. The electrical contactor of claim 10 , wherein the driving of one of the coils induces an electromagnetic field in the other coil, causing a mean tempering flux and damping effect to synchronize or substantially synchronize the opening and closing of the contacts with the AC waveform zero-crossing. 15. The electrical contactor of claim 14 , wherein the said driving of one of the coils induces an electromagnetic field in the other coil, when the first and second coils are connected in series. 16. A method of controlling electrical contact closing and opening delay of the electrical contactor of claim 1 , the method comprising the steps of driving a first coil of a magnetized dual-coil actuator to reduce a magnetic flux in the first coil, thereby increasing a net magnetic flux within a second coil, an armature latching to the second coil thereby causing an actuation to open or close electrical contacts. 17. The method of claim 16 , wherein magnetic flux is increased in the second coil when connected in series to the first coil. 18. The method of claim 16 , wherein the first coil of the actuator is energized with a truncated waveform drive pulse to reduce or limit erosion energy between contacts. 19. The method of claim 18 , wherein the truncated waveform drive pulse is a half-cycle waveform drive pulse to reduce or limit erosion energy between contacts. 20. The method of claim 19 , wherein the truncated waveform drive pulse is a quarter-cycle waveform drive pulse to prevent or limit contact separation and/or closure prior to peak load current.