Linear electromagnetic machine system with bearing housings having pressurized gas

What is claimed is: 1. A linear electromagnetic machine (LEM) comprising: a stator comprising: a plurality of windings, and a stator bore comprising an axis; a translator configured to electromagnetically interact with the stator and arranged to move axially within the stator bore substantially along the axis, the translator comprising a translator bearing surface; a first bearing housing coupled to the stator at a first longitudinal location, wherein the first bearing housing and the translator bearing surface are capable of forming a first bearing gap, which comprises a first pressurized gas; a first assembly coupling the first bearing housing to the stator to provide at least mechanical stiffness to lateral displacement of the first bearing housing; a second bearing housing coupled to the stator at a second longitudinal location, wherein the second bearing housing and the translator bearing surface are capable of forming a second bearing gap, which comprises a second pressurized gas; and a second assembly coupling the second bearing housing to the stator to provide at least mechanical stiffness at least to lateral displacement of the second bearing housing. 2. The LEM of claim 1 , wherein each winding of the plurality of windings corresponds to a phase. 3. The LEM of claim 1 , wherein the LEM is configured for oil-less operation. 4. The LEM of claim 1 , wherein the translator further comprising a feature configured to constrain azimuthal rotation. 5. The LEM of claim 1 , wherein the plurality of windings are grouped into a plurality of phases, and wherein each phase of the plurality of phases comprises one or more windings of the plurality of windings. 6. The LEM of claim 5 , wherein the plurality of phases is equal to or greater than three. 7. The LEM of claim 1 , wherein the translator comprises a magnet section, and wherein the magnet section and the stator bore are capable of forming a motor air gap. 8. The LEM of claim 7 , wherein the translator further comprises at least one structural feature that engages at least one magnet of the magnet section to constrain axial motion of the at least one magnet. 9. The LEM of claim 7 , wherein the magnet section comprises a plurality of magnets bonded to a surface of the translator. 10. The LEM of claim 7 , wherein the translator further comprises a wrap positioned radially over the magnet section. 11. The LEM of claim 7 , wherein the magnet section comprises a first longitudinal length, and wherein the plurality of windings comprises a second longitudinal length greater than the first longitudinal length. 12. The LEM of claim 7 , wherein the magnet section comprises a first longitudinal length, and wherein the plurality of windings comprises a second longitudinal length less than or equal to the first longitudinal length. 13. The LEM of claim 7 , wherein the magnet section comprises a magnetic pole length, wherein the stator comprises a plurality of slots and teeth having a slot pitch, and wherein the magnetic pole length and the slot pitch are not substantially equal. 14. The LEM of claim 7 , wherein the magnet section comprises a plurality of magnets arranged in longitudinally stacked rows. 15. The LEM of claim 14 , wherein an interior row of the longitudinally stacked rows comprises magnets having a first axial length, and wherein a terminal row of the longitudinally stacked rows comprises magnets having a second axial length less than the first axial length. 16. The LEM of claim 7 , wherein: the magnet section comprises a plurality of magnets; the stator comprises: a plurality of stator teeth arranged azimuthally around the stator bore, the plurality of stator teeth comprising a pair of consecutive stator teeth, and a first azimuthal gap between the pair of consecutive stator teeth; and the magnet section comprises a second azimuthal gap between azimuthally consecutive magnets of the magnet section, wherein the first azimuthal gap and the second azimuthal gap are configured to substantially maintain azimuthal alignment. 17. The LEM of claim 16 , wherein the first azimuthal gap is larger than the second azimuthal gap in the azimuthal direction.