Apparatus and method for dynamically balancing rotors

What is claimed is: 1. A method for balancing a rotor, the method comprising: rotating the rotor about an axis of an assembled system in which the rotor is assembled in a normal configuration for an intended operation; measuring an imbalance in the rotor by at least one accelerometer positioned on at least one plane of the rotor of the assembled system; mathematically calculating an adjustment to be made to a mass distribution of the rotor based on the measured imbalance such that, in the calculated adjustment, forces and moments of the mass distribution at the at least one plane become negligible; and after the calculating, adjusting the mass distribution to reduce the imbalance, by operating a laser to ablate material from the rotor according to operating parameters based on the adjustment calculated, wherein the measuring, calculating, and adjusting are performed while the rotor is rotating in the assembled system such that, after the balancing of the rotor is complete, the rotor is useable for the intended operation without disassembly from the assembled system. 2. The method of claim 1 , wherein the measuring, calculating, and adjusting are performed while the rotor is installed in a machine comprising a shaft and a plurality of bearings supporting the shaft for rotation about the axis, and wherein the rotor is attached to and rotates with the shaft. 3. The method of claim 2 , wherein the machine has a configuration selected from the group consisting of a pump, a turbine, a propeller, an impeller, a gear, a drum, a flywheel, and an engine. 4. The method of claim 2 , comprising transporting a rotor balancing apparatus to the machine, and operating the rotor balancing apparatus to perform the measuring, calculating, and adjusting. 5. The method of claim 1 , comprising repeating the measuring, calculating, and adjusting one or more times to further reduce the imbalance. 6. The method of claim 1 , wherein the rotor rotates with a shaft about the axis and the shaft is supported by at least a first bearing and a second bearing, and wherein the measuring the imbalance comprises measuring a radial acceleration in a first plane of the first bearing and measuring a radial acceleration in a second plane of the second bearing relative to the axis. 7. The method of claim 6 , wherein the measuring radial acceleration is selected from the group consisting of: measuring the radial acceleration of the first bearing and measuring the radial acceleration of the second bearing are done simultaneously; measuring the radial acceleration of the first bearing and measuring the radial acceleration of the second bearing are done sequentially; measuring the radial acceleration of the first bearing comprises operating a first accelerometer mounted to the first bearing or to a stator to which the first bearing is attached, and measuring the radial acceleration of the second bearing comprises operating a second accelerometer mounted to the second bearing or to a stator to which the second bearing is attached; measuring the radial acceleration of the first bearing comprises operating an accelerometer mounted to the first bearing or at a location on the stator coplanar with the first bearing, and measuring the radial acceleration of the second bearing comprises moving the accelerometer from the first bearing or from the location on the stator coplanar with the first bearing, to the second bearing or to a location on the stator coplanar with the second bearing; a combination of two or more of the foregoing. 8. The method of claim 1 , wherein the measuring the imbalance comprises measuring an initial imbalance, followed by measuring a first trial imbalance located at a first plane of the rotor and a second trial imbalance located at a second plane of the rotor at an axial distance from the first plane. 9. The method of claim 8 , wherein the measuring the first trial imbalance and the measuring the second trial imbalance are selected from the group consisting of: creating the first trial imbalance before measuring the first trial imbalance, and after measuring the first trial imbalance, creating the second trial imbalance; creating the first trial imbalance and creating the second trial imbalance by operating the laser to ablate material at the first plane and at the second plane, respectively; and both of the foregoing. 10. The method of claim 9 , comprising, after measuring the first trial imbalance, removing the first trial imbalance before creating the second trial imbalance. 11. The method of claim 10 , wherein the removing the first trial imbalance comprises operating the laser to ablate material from the rotor. 12. The method of claim 8 , wherein the calculating the adjustment to be made to the mass distribution of the rotor comprises calculating an adjustment to be made to the mass distribution at the first plane and an adjustment to be made in the mass distribution at the second plane. 13. The method of claim 8 , wherein the adjusting the mass distribution is selected from the group consisting of: operating the laser to ablate material from the first plane and the second plane; adjusting the mass distribution at the first plane and the second plane simultaneously; adjusting the mass distribution at the first plane and the second plane sequentially; and two or more of the foregoing. 14. The method of claim 1 , wherein the rotor rotates with a shaft, and further comprising generating a plurality of once-per-revolution pulses, each pulse corresponding to one revolution of the shaft, and normalizing the measured imbalance based on the pulses. 15. An apparatus for balancing a rotor, the apparatus comprising: an accelerometer configured for measuring an imbalance in the rotor while the rotor is rotating by measuring radial acceleration at a mounting location, and configured for outputting a measurement signal indicative of the measured radial acceleration; said accelerometer disposed in an assembled system in which the rotor is assembled in a normal configuration for an intended operation; a laser configured for ablating material from the rotor while the rotor is rotating; and a computing device configured for: receiving the measurement signal from the accelerometer; mathematically calculating an adjustment to be made to a mass distribution of the rotor based on the measurement signal such that, in the calculated adjustment, forces and moments of the mass distribution at at least one plane of the mounting location become negligible; and after the calculating, adjusting the mass distribution to reduce the imbalance, by controlling the laser to ablate material from the rotor while the rotor is rotating, according to operating parameters based on the adjustment calculated, wherein, after the balancing of the rotor is complete, the rotor is useable for the intended operation without disassembly from the assembled system. 16. The apparatus of claim 15 , comprising a machine configured for rotating the rotor, wherein the accelerometer is configured for being mounted at the machine, and the laser is configured for being mounted relative to the machine so as to be optically aligned with one or more selected balancing planes of the rotor. 17. The apparatus of claim 15 , wherein the accelerometer comprises a first accelerometer configured for being mounted at a first mounting location, and a second accelerometer configured for being mounted at a second mounting location. 18. The apparatus of claim 15 , wherein the computing device is configured for calculating the adj