Systems and methods for determining proper phase rotation in downhole linear motors

What is claimed is: 1. A method for determining proper phase rotation in a linear motor, wherein phase rotations associated with power and return strokes are initially unknown, the method comprising: providing power to a linear motor, wherein the power drives the motor for a plurality of cycles, wherein each cycle includes a stroke in which a mover of the motor moves in a first direction and a stroke in which the mover moves in a second direction which is opposite the first direction; monitoring a load on the motor during the plurality of cycles; determining, for each of the first and second directions, whether the load on the motor during the strokes in the corresponding direction increases over the plurality of cycles; if the load on the motor during the strokes in the first direction increases and the load on the motor during the strokes in the second direction remains substantially constant, associating the first direction with a power stroke and associating the second direction with a return stroke; if the load on the motor during the strokes in the second direction increases and the load on the motor during the strokes in the first direction remains substantially constant, associating the second direction with the power stroke and associating the first direction with the return stroke; and provide power to the linear motor having respective power output characteristics associated with the power stroke and return stroke. 2. The method of claim 1 , wherein power which has a first phase rotation causes the mover to move in the first direction and power which has a second phase rotation causes the mover to move in the second direction; wherein if the load on the motor during the strokes in the first direction increases and the load on the motor during the strokes in the second direction remains substantially constant, the first phase rotation is associated with the power stroke and the second phase rotation is associated with the return stroke; wherein if the load on the motor during the strokes in the second direction increases and the load on the motor during the strokes in the first direction remains substantially constant, the second phase rotation is associated with the power stroke and the first phase rotation is associated with the return stroke. 3. The method of claim 1 , wherein determining the load on the motor during the strokes in each of the first and second directions comprises determining a current drawn by the motor during the strokes in each of the first and second directions, wherein the load on the motor is proportional to the current drawn by the motor. 4. The method of claim 3 , wherein, for each of the first and second directions, determining whether the current drawn by the motor during the strokes in the corresponding direction increases over the plurality of cycles comprises comparing the current for the stroke in the corresponding direction in each successive one of the plurality of cycles. 5. The method of claim 1 , wherein the motor is initially stopped and the power is provided to the motor in a startup phase of operation, wherein the load on the motor is monitored for a predetermined number of cycles during the startup phase, and wherein after the load on the motor is monitored for the predetermined number of cycles and each of the first and second directions is associated with the corresponding one of the power and return strokes in the startup phase, the motor is operated normally. 6. A method for determining proper phase rotation in a linear motor, wherein phase rotations associated with power and return strokes are initially unknown, the method comprising: providing power to a linear motor, wherein the power drives the motor for a plurality of cycles, wherein each cycle drives a mover of the motor in a stroke in a first direction and a stroke in a second direction which is opposite the first direction; monitoring a load on the motor during the plurality of cycles; identifying one of the first and second directions for which the load on the motor increases during corresponding strokes over the plurality of cycles; if the load on the motor during the strokes in the first direction increases, providing power to the linear motor having power stroke characteristics during strokes in the first direction and providing power to the linear motor having return stroke characteristics during strokes in the second direction; and if the load on the motor during the strokes in the second direction increases, providing power to the linear motor having power stroke characteristics during strokes in the second direction and providing power to the linear motor having return stroke characteristics during strokes in the first direction. 7. The method of claim 6 , wherein power having a first phase rotation drives the motor in the first direction and power having a second phase rotation which is opposite the first phase rotation drives the motor in the second direction. 8. The method of claim 6 , wherein determining the load on the motor during the strokes in each of the first and second directions comprises determining cycle-to-cycle differences in a current drawn by the motor during the strokes in each of the first and second directions, wherein the load on the motor is proportional to the current drawn by the motor. 9. The method of claim 6 , wherein the motor is initially stopped and the power is provided to the motor in a startup phase of operation, wherein the load on the motor is monitored for a predetermined number of cycles during the startup phase, and wherein after the load on the motor is monitored for the predetermined number of cycles and each of the first and second directions is associated with the corresponding one of the power and return strokes in the startup phase, the motor is operated normally. 10. The method of claim 9 , further comprising installing the linear motor in a well and splicing a plurality of conductors of a power cable electrically connecting the linear motor to a surface controller. 11. A method for determining proper phase rotation in a linear motor, wherein phase rotations associated with power and return strokes are initially unknown, the method comprising: providing power to a linear motor, wherein the power drives the motor for a plurality of cycles, wherein each cycle drives a mover of the motor in a stroke in a first direction and a stroke in a second direction which is opposite the first direction; monitoring a load on the motor during the plurality of cycles; identifying one of the first and second directions for which the load on the motor remains substantially constant during corresponding strokes over the plurality of cycles; if the load on the motor during the strokes in the first direction remains substantially constant, providing power to the linear motor having return stroke characteristics during strokes in the first direction and providing power to the linear motor having power stroke characteristics during strokes in the second direction; and if the load on the motor during the strokes in the second direction remains substantially constant, providing power to the linear motor having return stroke characteristics during strokes in the second direction and providing power to the linear motor having power stroke characteristics during strokes in the first direction.