Resolving ambiguities in phase correction term for optical field encoding.
Optics Letters
|August 15, 2024
View abstract on PubMed
Summary
This study clarifies phase correction terms in optical field encoding. Consistent phase-wrapping conventions yield equivalent results, resolving interpretation conflicts in phase and amplitude encoding.
Area of Science:
- Optics and Photonics
- Signal Processing
Background:
- Phase and amplitude optical field encoding techniques are crucial for data transmission and sensing.
- Ambiguities exist regarding the definition and necessity of a phase correction term in these methods.
Purpose of the Study:
- To resolve ambiguities surrounding the phase correction term in optical field encoding.
- To provide a unified theoretical framework for phase and amplitude encoding.
Main Methods:
- Development of a generalized mixed Fourier-Taylor series expansion.
- Theoretical analysis of the expansion for arbitrary phase-wrapping intervals.
- Numerical simulations and experimental validation.
Main Results:
- The generalized expansion is valid for any phase-wrapping interval.
- Demonstration that consistent application of a phase-wrapping convention leads to equivalent results.
- Reconciliation of previously conflicting interpretations of phase correction terms.
Conclusions:
- The existence and definition of a phase correction term are dependent on the chosen phase-wrapping convention.
- A consistent approach to phase-wrapping eliminates ambiguity and ensures accurate optical field encoding.
- This work provides a robust theoretical foundation for phase and amplitude optical field encoding techniques.
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