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

What is claimed is: 1. An apparatus comprising: a controller of an electric drive system for a linear motor, wherein in a startup phase of operation, the controller is configured to: control the electric drive system which provides power to the 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; monitor a load on the motor during the plurality of cycles; determine, 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, associate 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, associate the second direction with the power stroke and associating the first direction with the return stroke; provide power to the linear motor having respective power output characteristics associated with the power stroke and return stroke. 2. The apparatus of claim 1 , wherein the controller controls the electric drive system to provide power having a first phase rotation which causes the mover to move in the first direction and power having a second phase rotation which causes the mover to move in the second direction; wherein if the controller determines that 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 controller associates the first phase rotation with the power stroke and associates the second phase rotation with the return stroke; wherein if the controller determines that 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 controller associates the second phase rotation with the power stroke and associates the first phase rotation with the return stroke. 3. The apparatus of claim 1 , wherein the controller determines the load on the motor during the strokes in each of the first and second directions by 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 apparatus of claim 3 , wherein, for each of the first and second directions, the controller determines whether the current drawn by the motor during the strokes in the corresponding direction increases over the plurality of cycles by comparing the current for the stroke in the corresponding direction in each successive one of the plurality of cycles. 5. The apparatus of claim 1 , wherein the controller initially causes the electric drive system to provide no power to the motor, and then causes the electric drive system to provide power to the motor in a startup phase of operation, wherein the controller monitors the load on the motor for a predetermined number of cycles during the startup phase, and wherein after the controller monitors the load on the motor for the predetermined number of cycles and associates each of the first and second directions with the corresponding one of the power and return strokes in the startup phase, the controller controls the electric drive system to operate the motor normally. 6. A system comprising: an electric submersible pump (ESP) system installed in a well, wherein the ESP system includes a linear motor; an electric drive system positioned at the surface of the well; and one or more electrical cables coupled between the electric drive system and the ESP system, wherein the one or more electrical cables carry power from the electric drive system to the ESP system; wherein the electric drive system includes a controller for the linear motor of the ESP system; wherein in a startup phase of operation, the electric drive system is configured to provide power to the 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, monitor a load on the motor during the plurality of cycles, determine, 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, associate 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, associate 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. 7. The system of claim 6 , wherein the electric drive system generates power having a first phase rotation which causes the mover to move in the first direction and power having a second phase rotation which causes the mover to move in the second direction; wherein if the electric drive system determines that 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 electric drive system associates the first phase rotation with the power stroke and associates the second phase rotation with the return stroke; wherein if the electric drive system determines that 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 electric drive system associates the second phase rotation with the power stroke and associates the first phase rotation with the return stroke. 8. The system of claim 6 , wherein the electric drive system determines the load on the motor during the strokes in each of the first and second directions by 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. 9. The system of claim 8 , wherein, for each of the first and second directions, the electric drive system determines whether the current drawn by the motor during the strokes in the corresponding direction increases over the plurality of cycles by comparing the current for the stroke in the corresponding direction in each successive one of the plurality of cycles. 10. The system of claim 6 , wherein the electric drive system initially provides no power to the motor, and provides power to the motor in a startup phase of operation, wherein the electric drive system monitors the load on the motor for a predetermined number of cycles during the startup phase, and wherein after the electric drive system monitors the load on the motor for the predetermi