Systems and methods for operating a linear motor to prevent impacts with hard stops

What is claimed is: 1. An apparatus comprising: a linear motor having a stator and a mover, wherein the mover is positioned within a bore of the stator, wherein the mover moves in a reciprocating motion within the bore between a first end of a stroke and a second end of the stroke, wherein a first hard stop prevents the mover from moving past the first end of the stroke and a second hard stop prevents the mover from moving past the second end of the stroke; and a first set of sensors in the stator positioned proximate to the bore, wherein when the mover moves in the bore, the first set of sensors produce corresponding output signals except when the mover is in a position proximate to but not in contact with one of the hard stops wherein while the first set of sensors produce output signals indicating that the mover is not in the first position proximate to the second hard stop, the motor receives power having a current phase order, and wherein in response to determining that the first set of sensors do not produce output signals, the current phase order of the power is reversed, thereby reversing a direction of movement of the mover within the bore of the stator. 2. The apparatus of claim 1 , wherein the first set of sensors produce corresponding output signals except when the mover is in a first position proximate to but not in contact with the second hard stop, further comprising a second set of sensors in the stator positioned proximate to the bore, wherein when the mover moves in the bore, the second set of sensors produce corresponding output signals except when the mover is in a second position proximate to the first hard stop but not in contact with the first hard stop. 3. The apparatus of claim 1 , wherein the motor provides output from the first set of sensors to an electric drive system and receives power from the electric drive system, wherein while the electric drive system receives output signals from the first set of sensors indicating that the mover is not in the first position proximate to the second hard stop, the electric drive system provides power to the motor having a first phase order, and wherein when the electric drive system does not receive output signals from the first set of sensors, the electric drive system provides power to the motor having a second phase order which is the reverse of the first phase order. 4. The apparatus of claim 3 , wherein the first set of sensors comprise Hall-effect sensors, and wherein the mover comprises one or more permanent magnets, wherein when the mover is not in the first position, at least one of the first set of sensors overlaps with at least one of the one or more permanent magnets, and wherein when the mover is in the first position, none of the first set of sensors overlaps with any of the one or more permanent magnets. 5. The apparatus of claim 1 , further comprising combining circuitry that receives the output signals from the first set of sensors and produces a composite signal from the output signals of the first set of sensors. 6. The apparatus of claim 5 , wherein the combining circuitry performs an exclusive OR operation on (XOR's) the output signals from the first set of sensors and thereby produces the composite signal. 7. An electric submersible pump (ESP) system comprising: a reciprocating pump; a linear motor coupled to the pump and configured to drive the pump; and an electric drive coupled to the motor by a power cable and configured to produce power that drives the motor; wherein the motor includes a stator and a mover, wherein the mover is positioned within a bore of the stator, wherein the mover moves in a reciprocating motion within the bore between a first end of a stroke and a second end of the stroke, wherein a first hard stop prevents the mover from moving past the first end of the stroke and a second hard stop prevents the mover from moving past the second end of the stroke; wherein the motor includes a first set of sensors in the stator positioned proximate to the bore, wherein when the mover moves in the bore, the first set of sensors produce corresponding output signals except when the mover is in a position proximate to but not in contact with one of the hard stops; wherein the electric drive includes a controller, wherein when the motor is operating and the first set of sensors produce output signals, the electric drive provides power to the motor having a current phase order, and wherein in response to determining that the first set of sensors are not producing output signals, the controller reverses the current phase order of the power provided to the motor and thereby reverses a direction of movement of the mover within the bore of the stator. 8. The ESP system of claim 7 , wherein the first set of sensors produce corresponding output signals except when the mover is in a first position proximate to but not in contact with the second hard stop, wherein the motor includes a second set of sensors in the stator positioned proximate to the bore, and wherein when the mover moves in the bore, the second set of sensors produce corresponding output signals except when the mover is in a second position proximate to the first hard stop but not in contact with the first hard stop. 9. The ESP system of claim 7 , wherein the first set of sensors comprise Hall-effect sensors, and wherein the motor includes combining circuitry that receives the output signals from the first set of sensors and produces a composite signal from the output signals of the first set of sensors. 10. The ESP system of claim 9 , wherein the combining circuitry XOR's the output signals from the first set of sensors and thereby produces the composite signal. 11. A method for controlling a linear motor of an electric submersible pump (ESP) system, the method comprising: providing power to a linear motor of an ESP system, wherein the power has a first phase order that drives a mover of the motor in a first direction within a bore of a stator in the motor; monitoring a first set of sensors in the stator, wherein the first set of sensors produce corresponding output signals when the mover is moving, except when the mover is in a first position proximate to but not in contact with a first hard stop in the bore of the stator; while the first set of sensors output signals indicating movement of the mover, continuing to produce power having the first phase order that drives the mover in the first direction; and when the first set of sensors discontinue outputting signals indicating movement of the mover, producing power having a second phase order prior to the mover hitting the first hard stop, wherein the second phase order is the reverse of the first phase order, wherein the power having the second phase order drives the mover in a second direction which is opposite the first direction. 12. The method of claim 11 , further comprising, while producing power having the second phase order: monitoring a second set of sensors in the stator, wherein the second set of sensors produce corresponding output signals when the mover is moving, except when the mover is in a second position proximate to but not in contact with a second hard stop in the bore of the stator; while the second set of sensors output signals indicating movement of the mover, continuing to produce power having the second phase order that drives the mover in the second direction; and when the second set of sensors discontinue outputting signals indicating movement of the mover, producing power having the first phase order prior to the mover hitting the second hard stop, thereby driving the mover in the first direction. 13. The method of claim 11