Multichannel correlation analysis for displacement device

We claim: 1. An apparatus for estimating a parameter of interest, comprising: a displacement sensor comprising: a displacement device configured for displacement responsive to the parameter of interest and spring oscillation of the displacement device due to environmental noise; a detector array configured to provide information comprising a first signal and a second signal both relating to the displacement, wherein the first signal is at least as sensitive to the displacement as the second signal; and at least one processor configured to mitigate effects of the environmental noise on the information by determining correlated portions of each corresponding signal representative of effects of common mode elements of the environmental noise on each corresponding signal, and estimate the parameter of interest from the information; wherein the displacement device is an optical displacement device configured to receive a first electromagnetic beam with a first value of a beam property and a second electromagnetic beam with a second value of the beam property, wherein the first value is different than the second value, the optical displacement device comprising a displacement element configured for displacement responsive to the parameter of interest and the environmental noise; and wherein the information comprises a first signal relating to the displacement responsive to a received part of the first electromagnetic beam and a second signal relating to the displacement responsive to a received part of the second electromagnetic beam, wherein the received part of the first electromagnetic beam and the received part of the second electromagnetic beam both pass through at least part of the optical displacement device. 2. The apparatus of claim 1 wherein the at least one processor is configured to: use the correlated portions of each corresponding signal to estimate a corresponding noise signal for the second signal, the corresponding noise signal representing a portion of the second signal attributable to the environmental noise; and modify the first signal using the corresponding noise signal for the second signal to attenuate the effects of the environmental noise on the first signal. 3. The apparatus of claim 2 wherein the at least one processor is configured to subtract the noise signal of the second signal from the first signal. 4. The apparatus of claim 2 wherein the at least one processor is configured to select the first signal from a plurality of signals each responsive to a received part of a corresponding electromagnetic beam having passed through at least part of the optical displacement device, the selection comprising identifying the first signal as the most sensitive of the plurality of signals to displacement. 5. The apparatus of claim 2 wherein the at least one processor is configured to select the second signal from a plurality of signals each responsive to a received part of a corresponding electromagnetic beam having passed through at least part of the optical displacement device, the selection comprising identifying the second signal as the most correlated of the plurality of signals to the first signal. 6. The apparatus of claim 2 wherein the at least one processor is configured to: remove the mean of the first signal from the first signal to derive a cyclical response; determine the corresponding noise signal by removing the mean of the second signal from the second signal; normalize the corresponding noise signal to the cyclical response of the first signal, such that the linear components are of the same magnitude; and perform a point-by-point subtraction of the corresponding noise signal from the cyclical response. 7. The apparatus of claim 2 wherein each corresponding noise signal has a higher frequency than the remainder of the signal to which it corresponds. 8. The apparatus of claim 2 wherein the at least one processor is configured to: select the second signal and at least one other signal from a plurality of signals each responsive to a received part of a corresponding electromagnetic beam having passed through at least part of the optical displacement device, the selection comprising identifying the second signal and the at least one other signal as the most correlated of the plurality of signals to the first signal; estimate a corresponding noise signal for each of the second signal and the at least one other signal; and determine a corresponding common mode suppressed signal for each of the second signal and the at least one other signal by modifying the first signal using the corresponding noise signal for each of the second signal and the at least one other signal; and combine the corresponding common mode suppressed signals. 9. The apparatus of claim 1 wherein the at least one processor is configured to use singular value decomposition to estimate a common mode output across the first signal, the second signal, and at least one other signal responsive to a received part of a corresponding electromagnetic beam having passed through at least part of the optical displacement device. 10. The apparatus of claim 9 wherein a mode of the largest singular value is assumed to be composed of the gravitational acceleration and a distortion component and the remaining modes are assumed to be the result of channel distortion and uncorrelated noise. 11. A method for estimating a parameter of interest, comprising: estimating the parameter of interest using a detector array configured to provide information comprising a first signal and a second signal both relating to displacement of a displacement device of a displacement sensor, the displacement device configured for displacement responsive to the parameter of interest and spring oscillation of the displacement device due to environmental noise, wherein the first signal is at least as sensitive to the displacement as the second signal, the estimation comprising mitigating effects of the environmental noise on the information by determining correlated portions of the first signal and the second signal representative of effects of the environmental noise on the corresponding signal; wherein the displacement device is an optical displacement device configured to receive a first electromagnetic beam with a first value of a beam property and a second electromagnetic beam with a second value of the beam property, wherein the first value is different than the second value, the optical displacement device comprising a displacement element configured for displacement responsive to the parameter of interest and the environmental noise; and wherein the information comprises a first signal relating to the displacement responsive to a received part of the first electromagnetic beam and a second signal relating to the displacement responsive to a received part of the second electromagnetic beam, wherein the received part of the first electromagnetic beam and the received part of the second electromagnetic beam both pass through at least part of the optical displacement device. 12. The method of claim 11 comprising: using the correlated portions of each corresponding signal to estimate a corresponding noise signal for the second signal, the corresponding noise signal representing a portion of the second signal attributable to the environmental noise; and modifying the first signal using the corresponding noise signal for the second signal to attenuate the effects of the environmental noise on the first signal. 13. The method of claim 12 comprising selecting the first signal from a plurality of signals each responsive to a received part of a corresponding electromagnetic beam hav