Drive circuit for electric motors

What is claimed is: 1. A drive circuit for an electric motor, said drive circuit comprising: an inverter configured to supply variable frequency current to the electric motor over a first duration, wherein said inverter is further configured to disable supply of the variable frequency current at expiration of the first duration; a solid state switch configured to begin supplying line frequency current to the electric motor after said inverter is disabled at the expiration of the first duration and before the variable frequency current in the electric motor decays below a current threshold and a motor speed falls below a threshold speed; a contactor coupled in parallel with said solid state switch and configured to supply the line frequency current to the electric motor over a second duration beginning when said contactor closes after the expiration of the first duration; and a bypass switch configured to route the variable frequency current from said inverter to a start winding of the motor during the first duration and to route the line frequency current to the start winding via a capacitor after the expiration of the first duration. 2. The drive circuit of claim 1 , wherein said solid state switch comprises a triode for alternating current (TRIAC). 3. The drive circuit of claim 1 , wherein said solid state switch is further configured to disable supply of the line frequency current through said solid state switch over the second duration. 4. The drive circuit of claim 1 , wherein said solid state switch is further configured to close after supply of the variable frequency current from said inverter is disabled, and to open after said contactor closes. 5. The drive circuit of claim 1 , wherein said contactor is further configured to commutate within two cycles of the line frequency current. 6. The drive circuit of claim 5 , wherein commutation of said contactor defines a transition duration, beginning at the expiration of the first duration and extending at least partially into the second duration, during which said solid state switch is commutated, wherein said solid state switch is further configured to commutate before the variable frequency current decays from windings of the electric motor and before motor speed falls below a threshold speed. 7. A permanent split capacitor (PSC) motor, comprising: a plurality of windings comprising a start winding; and a drive circuit coupled to said plurality of windings, comprising: an inverter configured to supply variable frequency current to said plurality of windings over a first duration when said inverter is enabled, wherein said inverter is further configured to disable supply of the variable frequency current at expiration of the first duration; a solid state switch configured to begin supplying line frequency current to said plurality of windings after said inverter is disabled at an expiration of the first duration and before the variable frequency current in said plurality of windings decays below a current threshold and a motor speed falls below a threshold speed; a contactor coupled in parallel with said solid state switch and configured to supply the line frequency current to said plurality of windings after said inverter is disabled; and a bypass switch configured to route the variable frequency current from said inverter to said start winding during the first duration and to route the line frequency current to said start winding via a capacitor after the expiration of the first duration. 8. The PSC motor of claim 7 , wherein said drive circuit is configured to open said solid state switch after said contactor is closed and conducting the line frequency current, and within ten cycles of the line frequency current. 9. The PSC motor of claim 7 , wherein said contactor comprises a mechanical contactor configured to commutate within two cycles of the line frequency current. 10. The PSC motor of claim 9 , wherein said plurality of windings are configured to conduct the variable frequency current for no more than one cycle of the line frequency current after said inverter is disabled. 11. The PSC motor of claim 10 , wherein said solid state switch is further configured to commutate in no more than three millisecond. 12. The PSC motor of claim 9 , wherein said solid state switch comprises a triode for alternating current (TRIAC) configured to withstand at least two cycles of the line frequency current in an over-current condition. 13. A method of operating a permanent split capacitor (PSC) motor, said method comprising: supplying, by an inverter, a variable frequency current to windings of the PSC motor; disabling supply of the variable frequency current, wherein disabling supply of the variable frequency current comprises receiving a control signal at the inverter and disabling output of the variable frequency current from the inverter in response to the control signal; closing a solid state switch after disabling supply of the variable frequency current to supply line frequency current to the windings before the variable frequency current in the windings decays below a current threshold and before a motor speed falls below a threshold speed; closing a contactor after disabling supply of the variable frequency current to supply the line frequency current to the windings; opening the solid state switch after the contactor is closed to redirect the line frequency current through the contactor; and actuating a bypass switch to provide the line frequency current to a start winding of the PSC motor via a capacitor after disabling the supply of variable frequency current. 14. The method of claim 13 , wherein supplying the variable frequency current comprises: supplying line frequency current to an inverter; converting the line frequency current to the variable frequency current; and supplying the variable frequency current from the inverter. 15. The method of claim 13 , wherein closing the solid state switch and closing the contactor are initiated upon disabling the supply of the variable frequency current. 16. The method of claim 15 , wherein closing the contactor comprises commutating a mechanical contactor over a duration of up to two cycles of the line frequency current. 17. The method of claim 16 , wherein closing the solid state switch comprises commutating the solid state switch over a duration of no more than three millisecond. 18. The method of claim 13 , wherein opening the solid state switch occurs within ten cycles of the line frequency current from closing the solid state switch.