Additive-to-multiplicative moiré fringe transition in simultaneous dual-wavelength interferometry.

• STP method can retrieve the synthetic-wavelength phase from moiré fringe patterns in simultaneous dual-wavelength interferometry. • In STP method, by the additive-to-multiplicative moiré fringe transition, the measured synthetic-wavelength interferometry information exists directly and is demodulated conveniently. • STP method is implemented with π/(2k) phase shift at the synthetic wavelength to be retrieved by the conventional phase-shift algorithm. • STP method releases the restriction of spatial carrier for spectrum separation and the requirement of quadratic polar coordinate transform for the circle carrier. • The separation distance of the phase lobes in spectrum for STP method is longer than 9.56 times of the distance for traditional temporal FT method. Simultaneous dual-wavelength interferometry (SDWI) could extend the measured range of each single-wavelength interferometry, and has higher efficiency when the two single wavelengths work simultaneously. However, the directly measured phase demodulation at the long synthetic wavelength (λ S) from the generated moiré fringe patterns in SDWI is rather arduous. To reduce the difficulty of the processing for the moiré fringe patterns, a synthetic wavelength temporal phase retrieval method (STP) with the π/(2k) phase shift at λ S was proposed in this paper. By the additive-to-multiplicative moiré fringe transition, the synthetic-wavelength interferometry information exists in the form of the superposition with other wavelength information. And then for the longer separation distance of the phase lobes in spectrum, the synthetic-wavelength spectrum in STP method could be filter out more easily than traditional temporal Fourier transform (FT) method. After a low-pass filtering in the spectrum of the multiplicative moiré fringe intensity and adopting the π/(2k) phase shift at λ S , the synthetic-wavelength phase is retrieved by the conventional phase-shift algorithm from the obtained synthetic-wavelength phase-shift interferograms with the interval of π/2 phase shift. Compared with the spatial FT method with the introduction of spatial carrier, STP method releases the restriction of spatial carrier for spectrum separation and the requirement of quadratic polar coordinate transform for the circle carrier. Finally, the feasibility and applicability of the STP method are verified using simulation and experimental results. [ABSTRACT FROM AUTHOR]