Phase sensitive beam tracking

What is claimed is: 1. A method comprising: receiving, at signal processing hardware, axis signals from a multi-axis position sensing detector, each axis signal indicative of a beam position of an optical beam incident on the multi-axis position sensing detector, each axis signal corresponding to an axis of the multi-axis position sensing detector; generating, by the signal processing hardware, a reference signal by summing the axis signals; for each axis of the multi-axis position sensing detector: converting, by the signal processing hardware, a phase of a first axis signal of the axis to have a 90 degree phase difference from a second axis signal of the axis, resulting in a phase converted first axis signal; generating, by the signal processing hardware, an axis-phasor signal by summing the phase converted first axis signal and the second axis signal, the axis-phasor signal having an angle that maps to the beam position of the optical beam; and comparing, by the signal processing hardware, the axis-phasor signal and the reference signal to determine a phase difference, the phase difference mapping to a beam position error along the corresponding axis on the multi-axis position sensing detector; determining, by the signal processing hardware, a mirror position of a mirror directing the optical beam based on the beam position error of each axis of the multi-axis position sensing detector; and actuating, by the signal processing hardware, the mirror to move to the mirror position. 2. The method of claim 1 , further comprising: receiving, at the signal processing hardware, photocurrents for each axis of the multi-axis position sensing detector, each photocurrent having an amplitude dependent on a beam power and the beam position of the optical beam; and converting, by at least one transimpedance amplifier of the signal processing hardware, the photocurrents to the corresponding axis signals, each axis signal being a voltage signal. 3. The method of claim 1 , further comprising high pass filtering each axis signal using at least one single or multi-pole filter of the signal processing hardware. 4. The method of claim 1 , further comprising low pass filtering each axis-phasor signal using at least one single or multi-pole filter of the signal processing hardware. 5. The method of claim 1 , further comprising modifying, by at least one limiting amplifier of the signal processing hardware, each axis-phasor signal and the reference signal to each represent a corresponding logarithmic gain. 6. The method of claim 5 , further comprising filtering, by at least one comparator of the signal processing hardware, the modified axis-phasor signals and the modified reference signal to perform an edge detection on each of the modified axis-phasor signals and the modified reference signal. 7. The method of claim 6 , further comprising synchronizing, by the signal processing hardware, the reference signal to a reference clock of the signal processing hardware. 8. The method of claim 7 , further comprising trimming a frequency of the reference signal using a digital potentiometer of the signal processing hardware. 9. The method of claim 1 , further comprising determining, by a controller of the signal processing hardware, the mirror position in consideration of a rate of change of the mirror position based on the beam position error of at least one axis of the multi-axis position sensing detector. 10. The method of claim 1 , further comprising filtering, by a notch filter in communication with the controller, the mirror position to attenuate a target frequency. 11. A method comprising: receiving, at signal processing hardware, a first X-signal, a second X-signal including an X-signal phase, a first Y-signal, and a second Y-signal including a Y-signal phase in relation to a beam position of an optical beam incident on a position sensing detector; shifting, by the signal processing hardware, the X-signal phase of the second X-signal by 90 degrees; shifting, by the signal processing hardware, the Y-signal phase of the second Y-signal by 90 degrees; generating, by the signal processing hardware, a summed X-signal by summing the first X-signal and the shifted second X-signal; generating, by the signal processing hardware, a summed Y-signal by summing the first Y-signal and the shifted second Y-signal; generating, by the signal processing hardware, a reference signal by summing the first X-signal, the second X-signal, first Y-signal and the second Y-signal; determining, by the signal processing hardware, a mirror position of a mirror directing the optical beam, the mirror position based on at least one of: a first signal difference between the reference signal and the summed X-signal; or a second signal difference between the reference signal and the summed Y-signal; and actuating, by the signal processing hardware, the mirror to move to the mirror position. 12. The method of claim 11 , further comprising: receiving, at the signal processing hardware, a first X-photocurrent, a second X-photocurrent, a first Y-photocurrent, and a second Y-photocurrent, each photocurrent having an amplitude dependent on a beam power and the beam position of the optical beam; and converting, by at least one transimpedance amplifier of the signal processing hardware, the first X-photocurrent, the second X-photocurrent, the first Y-photocurrent, and the second Y-photocurrent to the corresponding first X-signal, the second X-signal, the first Y-signal, and the second Y-signal, each signal being a voltage signal. 13. The method of claim 11 , further comprising high pass filtering, by at least one single or multi-pole filter of the signal processing hardware, the first X-signal, the second X-signal, the first Y-signal, and the second Y-signal. 14. The method of claim 11 , further comprising modifying, by at least one limiting amplifier of the signal processing hardware, the summed X-signal, the summed Y-signal, and the reference signal to each represent a corresponding logarithmic gain, the modified summed X-signal, the modified summed Y-signal, and the modified reference signal each proportional to a logarithm of the corresponding summed X-signal, the corresponding summed Y-signal, and the corresponding reference signal. 15. The method of claim 14 , further comprising amplifying, by the signal processing hardware, the modified summed X-signal, the modified summed Y-signal, and the modified reference signal to each represent the corresponding logarithmic gain. 16. The method of claim 14 , further comprising filtering, by at least one comparator of the signal processing hardware, the modified summed X-signal, the modified summed Y-signal, and the modified reference signal to perform an edge detection on each of the modified summed X-signal, the modified summed Y-signal, and the modified reference signal. 17. The method of claim 16 , further comprising trimming a frequency of the reference signal using a digital potentiometer of the signal processing hardware. 18. The method of claim 11 , further comprising determining, by a controller of the signal processing hardware, the mirror position in consideration of a rate of change of the mirror position based on at least one of the first signal difference or the second signal difference. 19. The method of claim 11 , further comprising filtering, by a notch filter in communication with the controller, the mirror position to attenuate a target frequency. 20. An optical beam tracking system comprising: a