N-wavelength interrogation system and method for multiple wavelength interferometers

Accordingly, we claim: 1. An interferometric method of facilitating a measurement of an absolute optical path-length difference, the method comprising the steps of: (a) receiving in memory, a first fringe spectrum, from an interferometer comprising two optical paths having an absolute optical path-length difference therebetween that is to be measured, the first fringe spectrum comprising a plurality of non-quadrature spaced light intensity samples, each sample corresponding to a different wavelength of light from a plurality of monitored wavelengths, and the plurality of samples representing at least one full fringe cycle within the first fringe spectrum; (b) determining based on, at least in part, the first fringe spectrum a base estimate of the absolute optical path-length difference, a fringe number, and a quadrant; (c) selecting by a first processor a set of non-quadrature spaced samples from the plurality of samples; (d) computing by the first processor a first relative-phase measurement of the absolute optical path-length difference using the selected non-quadrature spaced light-intensity samples, by expressing each light intensity sample as a combination comprising: (i) a term based on a relative phase φ that is based on a reference wavelength and is independent of the monitored wavelengths, and (ii) a term based on a phase shift estimate δ i (L) relating to both the monitored wavelength corresponding to the light intensity sample and the base estimate of the absolute optical path-length difference; and (e) computing a first measurement of the absolute optical path-length difference by aggregating the first relative-phase measurement, the fringe number, and the quadrant. 2. The method of claim 1 , wherein: a number of wavelengths in the plurality of wavelengths ranges from 3 up to 4096; and the fringe spectrum comprises a plurality of fringe cycles, and a number of fringe cycles is up to 2048. 3. The method of claim 1 , wherein: the plurality of wavelengths range from a low wavelength up to a high wavelength that is greater than the low wavelength by a bandwidth; the low wavelength ranges from 600 nm up to 1590 nm; the high wavelength ranges from 610 nm up to 1600 nm; and the bandwidth ranges from 10 nm up to 200 nm. 4. The method of claim 1 , wherein the selected set comprises at least three non-quadrature spaced samples representing the at least one full fringe cycle. 5. The method of claim 1 , wherein the computing step comprises solving a set of equations, each equation corresponding to a different wavelength in the plurality of wavelengths and comprising: (i) a term based on a relative phase φ, and (ii) a term based on a phase shift estimate δ i (L) relating to both the wavelength corresponding to the equation and the base estimate of the absolute optical path-length difference. 6. The method of claim 1 , further comprising normalizing by the first processor the first fringe spectrum to update the samples, prior to the selecting step (b). 7. The method of claim 1 , further comprising determining by the first processor a number of samples in the set based on, at least in part, a specified minimum resolution of the first relative phase measurement. 8. The method of claim 7 , wherein the minimum resolution is specified as a fraction of a reference wavelength in the plurality of wavelengths, and the fraction ranges from 1/1,000 up to 1/100,000. 9. The method of claim 1 , further comprising: obtaining the first fringe spectrum using the interferometer; and generating a sensor measurement based on the first measurement of the absolute optical path-length difference. 10. The method of claim 1 , further comprising determining by a second processor a number of wavelengths and the wavelengths in the plurality of wavelengths based on, at least in part, a parameter of the first measurement of the absolute optical path-length difference, the parameter comprising at least one of a specified optical path-length difference upper limit and a specified resolution. 11. The method of claim 10 , wherein the specified optical path-length difference upper limit ranges from 2 mm up to 10 mm and the specified resolution ranges from 10 pm up to 1 nm. 12. The method of claim 1 , further comprising: designating the first measurement of the absolute optical path-length difference as the base estimate; updating, for at least one monitored wavelength, the term based on a phase shift estimate; and repeating the computing step (c) to obtain a refined first relative-phase measurement based on the at least one updated phase shift estimate; and repeating the computing step (e) to obtain a refined first measurement of the absolute optical path-length difference by aggregating the refined first relative-phase measurement, the fringe number, and the quadrant. 13. The method of claim 1 , further comprising: (g) receiving in the memory a second fringe spectrum comprising a plurality of non-quadrature spaced light intensity samples, each sample corresponding to a different wavelength of light from the plurality of wavelengths, and the plurality of samples representing at least one full fringe cycle within the second fringe spectrum; (h) repeating steps (c) and (e) using the second fringe spectrum to obtain a second relative-phase measurement of the absolute optical path-length difference, wherein the base estimate of the absolute optical path-length difference comprises the first measurement; and (i) computing by the first processor a second measurement of the absolute optical path-length difference by aggregating the second relative-phase measurement, the fringe number, and the quadrant. 14. The method of claim 1 , further comprising the step of using the first measurement to calculate a parameter of interest of a physical system. 15. The method of claim 14 , wherein the parameter of interest is selected from the group consisting of salinity, pressure, temperature, strain, vibration, distance, refractive index of a medium, and changes thereof. 16. A system for measuring a parameter of interest using a measurement of absolute optical path-length difference, the system comprising: a receiver for receiving a first fringe spectrum from an interferometer comprising two optical paths having an absolute optical path-length difference therebetween that is to be measured, the first fringe spectrum comprising a plurality of non-quadrature spaced light intensity samples, each sample corresponding to a different wavelength of light from a plurality of wavelengths, and the plurality of samples representing at least one full fringe cycle within the first fringe spectrum; a coarse estimator configured for: (a) selecting a reference wavelength in the plurality of wavelengths: and (b) determining: (i) a base estimate of the absolute optical path-length difference, based on, at least in part, the first fringe spectrum, (ii) a fringe number and a quadrant based on, at least in part, the base estimate and the selected reference wavelength; a sampler in communication with the receiver for selecting a set of non-quadrature spaced samples from the plurality of samples; a relative-phase estimator for determining a relative-phase measurement of the absolute optical path-length difference using the selected non-quadrature spaced light-intensity samples, by expressing each light intensity sample as a combination comprising: (i) a term based on a relative phase φ that is based on a reference wavelength and is independent of the monitored wavelengths, and (ii) a term based on a phase shift estimate δ i (L) relating to both the moni