Electromagnetic actuator and method of use

What is claimed is: 1. An electromagnetic actuator comprising: a plunger moveable between a first position and a second position; a yoke comprising a first yoke portion proximate the first position and a second yoke portion proximate the second position; and a first coil proximally disposed with said first yoke portion, said first coil configured to generate a first magnetic field when energized, the first magnetic field causing said plunger to move toward the first position, said first coil further configured to generate a first magnetic flux through a first magnetic circuit, said first magnetic circuit comprising: said first yoke portion; said plunger; a first primary air gap at least partially defined by said first yoke portion and said plunger, said first primary air gap configured to diminish as said plunger moves toward the first position; a first secondary air gap at least partially defined by said first yoke portion and said plunger, said first secondary air gap configured to diminish as said plunger moves toward the first position; and a variable air gap at least partially defined by said first yoke portion and said plunger, said variable air gap having a cross-section configured to enlarge as said plunger moves toward the first position, wherein enlarging the cross-section of the variable air gap includes linearly translating the plunger perpendicular to a length dimension between the plunger and the first yoke portion. 2. The electromagnetic actuator in accordance with claim 1 further comprising a plurality of permanent magnets disposed within said plunger and configured to latch said plunger when in the first position and when in the second position. 3. The electromagnetic actuator in accordance with claim 1 further comprising a second coil proximate said second yoke portion and, when energized, said second coil is configured to generate a second magnetic field that causes said plunger to move toward the second position, said second coil further configured to generate a second magnetic flux through a second magnetic circuit, said second magnetic circuit comprising: said second yoke portion; said plunger; a first secondary air gap at least partially defined by said second yoke portion and said plunger, said first secondary air gap configured to diminish as said plunger moves toward the second position; and a second secondary air gap at least partially defined by said second yoke portion and said plunger, said second secondary air gap configured to diminish as said plunger moves toward the second position. 4. The electromagnetic actuator in accordance with claim 1 , wherein said plunger and said first yoke portion are coupled to a plurality of poles disposed to at least partially define said first primary air gap, said first secondary air gap, and said variable air gap. 5. The electromagnetic actuator in accordance with claim 4 , wherein said plunger, said first yoke portion, and said plurality of poles comprise a ferromagnetic material. 6. The electromagnetic actuator in accordance with claim 1 , wherein said variable air gap comprises a non-ferrous material. 7. The electromagnetic actuator in accordance with claim 1 , wherein said first primary air gap and first secondary air gap diminish at a same rate as the cross-section of said variable air gap enlarges, causing a net-zero change in the first-magnetic flux through said magnetic circuit. 8. The electromagnetic actuator in accordance with claim 1 , wherein said first primary air gap defines a first length between said first yoke portion and said plunger and said first secondary air gap defines a second length between said first yoke portion and said plunger, and wherein said first length and said second length are configured to diminish as said plunger moves toward the first position. 9. A method of operating an electromagnetic actuator including a plunger movable between a first position and a second position, the electromagnetic actuator including an armature including a first yoke portion proximate the first position and a second yoke portion proximate the second position, said method comprising: latching the plunger in the second position; energizing a first coil to generate a first magnetic flux through the plunger, the first yoke portion, a first primary air gap, a first secondary air gap, and a variable air gap; generating a first electromotive force, corresponding to the first magnetic flux, upon the plunger, causing the plunger to travel toward the first yoke portion; and reducing a first length of the first primary air gap, reducing a second length of the first secondary air gap, and enlarging a cross-section of the variable air gap to regulate the electromotive force upon the plunger, wherein enlarging the cross-section of the variable air gap comprises linearly translating the plunger perpendicular to a length dimension between the plunger and the first yoke portion. 10. The method in accordance with claim 9 , wherein latching the plunger comprises employing at least one permanent magnet in the plunger to latch the plunger to the second yoke portion. 11. The method in accordance with claim 9 , wherein energizing the first coil to generate the first magnetic flux comprises generating the first magnetic flux at least partially as a function of a size of the variable air gap, said variable air gap at least partially defined by the plunger and the first yoke portion. 12. The method in accordance with claim 9 , wherein energizing the first coil comprises applying a voltage to the first coil. 13. The method in accordance with claim 9 further comprising: latching the plunger in the first position; energizing a second coil to generate a second magnetic flux through the plunger, the second yoke portion, a second primary air gap, and a second secondary air gap, each of the second primary air gap and the second secondary air gap at least partially defined by the second yoke portion and the plunger; generating a second electromotive force, corresponding to the second magnetic flux, upon the plunger, causing the plunger to linearly travel toward the second yoke portion; and reducing a first length of the second primary air gap and a second length of the second secondary air gap to regulate the second electromotive force upon the plunger. 14. A vacuum circuit breaker comprising: a first contact; a second contact configured to translate between an open position and a closed position in which said second contact is further configured to engage said first contact; and an electromagnetic actuator comprising: a plunger coupled to said second contact and moveable between the open position and the closed position, wherein said plunger comprises at least one permanent magnet; a first yoke proximally disposed about the open position; a second yoke proximally disposed about the closed position; and an opening coil proximally disposed with said first yoke and, when energized, said opening coil configured to generate an opening magnetic field that causes said plunger to move toward the open position, said opening coil further configured to generate an opening magnetic flux through an opening magnetic circuit, said opening magnetic circuit comprising: said first yoke; said plunger; a first primary air gap at least partially defined by said first yoke and said plunger, said first primary air gap configured to diminish as said plunger moves toward the open position with an opening force; a first secondary air gap at least partially defined by said first yoke and said plunger, said first secondary air gap configured to diminish as said plunger moves toward