Electromagnetic seat attachment and seat power

The invention claimed is: 1. A seat assembly, comprising: a seat having an attachment post extending from a bottom of the seat, the attachment post comprising a ferromagnetic material; a floor assembly including at least one floor panel and an electromagnetic rail positioned in the floor assembly adapted to engage with the attachment post of the seat, the electromagnetic rail comprising a pair of sidewalls having a top side and a bottom side, the pair of sidewalls arranged to be spaced apart and parallel; a pair of lips projecting perpendicularly inwards from the top side of the pair of sidewalls, the pair of lips having a top engagement surface that engages with the attachment post of the seat; and a plurality of crossbars connecting the bottom side of one of the pair of sidewalls to the bottom side of another of the sidewalls at regularly spaced intervals along the length of the electromagnetic rail; an electromagnetic coupling between the seat and the floor assembly comprising a plurality of magnetic coils wound around the crossbars of the electromagnetic rail and spaced apart along a length of the electromagnetic rail; and a power supply that supplies electricity to the plurality of magnetic coils to generate a magnetic field around the electromagnetic rail when the power supply is turned on to secure the seat to the floor assembly, and when the power supply is turned off, the seat is released from the floor assembly. 2. The seat assembly of claim 1 , wherein the electromagnetic rail further comprises a mounting flange projecting perpendicularly outward from the top side of the pair of sidewalls, a bottom surface of the floor panel being mounted on the mounting flange. 3. The seat assembly of claim 1 , wherein the top side of the pair of sidewalls provides a support surface for the floor panel. 4. The seat assembly of claim 1 , wherein the electromagnetic rail further comprises a reinforcement flange projecting perpendicularly outward from the bottom side of the pair of sidewalls. 5. The seat assembly of claim 1 , further comprising a resonant inductive coupling power system for wirelessly supplying electrical power to the seat, the resonant inductive coupling power system comprising: a transmit coil positioned in the floor assembly that generates an oscillating magnetic field; a transmit coil power supply that supplies electricity to the transmit coil to generate the oscillating magnetic field; and a receive coil positioned in the seat to receive magnetic energy from the oscillating magnetic field and convert the magnetic energy into electrical power for the seat. 6. A seat assembly, comprising: a seal having an attachment post extending from a bottom of the seat, the attachment post comprising a ferromagnetic material; a floor assembly including at least one floor panel and a electromagnetic rail positioned in the floor assembly to engage with the attachment post of the seat; an electromagnetic coupling between the seat and the floor assembly comprising a plurality of magnetic coils wound around a portion of the electromagnetic rail and spaced apart along a length of the electromagnetic rail; a power supply that supplies electricity to the plurality of magnetic coils to generate a magnetic field around the electromagnetic rail when the power supply is turned on to secure the seat to the floor assembly, and when the power supply is turned off, the seat is released from the floor assembly, and a seat track having an open channel positioned within the floor assembly, the open channel of the seat track positioned to be exposed through the floor panel and the electromagnetic rail positioned within the open channel of the seat track. 7. The seat assembly of claim 6 , wherein the attachment post of the seat is positioned in the open channel of the seat track and on top of the electromagnetic rail. 8. The seat assembly of claim 6 , wherein the electromagnetic rail comprises: a first rail and a second rail arranged to be spaced apart and separate from each other, the first rail and the second rail having an upper surface that engages with the attachment post of the seat; and wherein the plurality of magnetic coils are wound separately around the first rail and the second rail at spaced intervals along the first rail and the second rail, and the power supply supplies electricity to the plurality of magnetic coils wound around the first rail and the second rail. 9. The seat assembly of claim 8 , wherein the first rail and the second rail are positioned at a lower portion of the open channel, and the attachment post is positioned between the upper surface of the electromagnetic rail and a top of the seat track. 10. The seat assembly of claim 8 , wherein the first rail and the second rail are positioned at a top of the open channel. 11. A vehicle, comprising: a plurality of seats arranged in rows, one or more of the plurality of seats having an attachment post comprising a ferromagnetic material extending from a bottom thereof, a floor assembly including at least one floor panel and an electromagnetic rail positioned in the floor assembly, the electromagnetic rail adapted to engage with the attachment post; an electromagnetic coupling between one or more of the plurality of seats and the floor assembly, the electromagnetic coupling comprising a first plurality of magnetic coils wound around a portion of the electromagnetic rail and spaced apart along a length of the electromagnetic rail; a seat track having an open channel positioned with the floor assembly, the open channel of the seat track positioned to be exposed through the floor panel and the electromagnetic rail positioned within the open channel of the seat track; and a power supply that supplies electricity to the first plurality of magnetic coils to generate a magnetic field around the electromagnetic rail when the power supply is turned on to secure the one or more of the plurality of seats to the floor assembly, and when the power supply is turned off, the one or more of the plurality of seats are released from the floor assembly to permit the one or more of the plurality of seats to be removed to change an arrangement of or spacing between the rows of the plurality of seats. 12. The vehicle of claim 11 , further comprising sensors that measure operational data of the vehicle and a controller that controls the power supply, the controller that receives the operational data from the sensors and is programmed to adjust a strength of the electromagnetic coupling based on the operational data from the sensors. 13. The vehicle of claim 11 , wherein the electromagnetic rail comprises: a pair of sidewalls having a top side and a bottom side, the pair of sidewalls arranged to be spaced apart and parallel; a pair of lips projecting perpendicularly inwards from the top side of the pair of sidewalls, the pair of lips having a top engagement surface that engages with the attachment post of the seat; and a plurality of crossbars connecting the bottom side of one of the pair of sidewalls to the bottom side of another of the sidewalls at regularly spaced intervals along the length of the electromagnetic rail, wherein the plurality of magnetic coils are wound around the crossbars. 14. The vehicle of claim 13 , wherein the electromagnetic rail further comprises a mounting flange projecting perpendicularly outward from the top side of the pair of sidewalls, a bottom surface of the floor panel being mounted on the mounting flange. 15. A method of attaching seats to a floor of a vehicle having a seat track in the floor, the seat track having an open channel positio