Differentiable design of freeform lenses for partially coherent beam shaping

Shuo Jin; Zexin Feng

doi:10.1364/AO.561916

Differentiable design of freeform lenses for partially coherent beam shaping

Shuo Jin
, Zexin Feng^*

^*Corresponding author for this work

Beijing Institute of Technology

Research output: Contribution to journal › Article › peer-review

Abstract

Partially coherent beams (PCBs), with unique properties such as reduced speckles and self-reconstruction, hold great promise for optical communication, particle trapping, and laser material processing. However, designing optical elements for shaping PCBs remains a significant challenge. We present a differentiable design method of freeform lenses for shaping PCBs. This method employs multi-level B-splines to represent the freeform surface. The key issue of our differential design method lies in the integration with a fast-forward simulation approach. The forward simulation approach models the PCBs’ diffraction pattern by efficiently computing the convolution of the coherent diffraction pattern and a kernel determined by the degree of coherence. Specifically, for the beam shaping of a “π” pattern, the computational speed of our method is approximately 22 times that of the conventional modal representation method.

polynomials.

Original language	English
Pages (from-to)	5982-5988
Number of pages	7
Journal	Applied Optics
Volume	64
Issue number	21
DOIs	https://doi.org/10.1364/AO.561916
Publication status	Published - 20 Jul 2025
Externally published	Yes

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10.1364/AO.561916

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abstract = "Partially coherent beams (PCBs), with unique properties such as reduced speckles and self-reconstruction, hold great promise for optical communication, particle trapping, and laser material processing. However, designing optical elements for shaping PCBs remains a significant challenge. We present a differentiable design method of freeform lenses for shaping PCBs. This method employs multi-level B-splines to represent the freeform surface. The key issue of our differential design method lies in the integration with a fast-forward simulation approach. The forward simulation approach models the PCBs{\textquoteright} diffraction pattern by efficiently computing the convolution of the coherent diffraction pattern and a kernel determined by the degree of coherence. Specifically, for the beam shaping of a “π” pattern, the computational speed of our method is approximately 22 times that of the conventional modal representation method.polynomials.",

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AU - Jin, Shuo

AU - Feng, Zexin

PY - 2025/7/20

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N2 - Partially coherent beams (PCBs), with unique properties such as reduced speckles and self-reconstruction, hold great promise for optical communication, particle trapping, and laser material processing. However, designing optical elements for shaping PCBs remains a significant challenge. We present a differentiable design method of freeform lenses for shaping PCBs. This method employs multi-level B-splines to represent the freeform surface. The key issue of our differential design method lies in the integration with a fast-forward simulation approach. The forward simulation approach models the PCBs’ diffraction pattern by efficiently computing the convolution of the coherent diffraction pattern and a kernel determined by the degree of coherence. Specifically, for the beam shaping of a “π” pattern, the computational speed of our method is approximately 22 times that of the conventional modal representation method.polynomials.

AB - Partially coherent beams (PCBs), with unique properties such as reduced speckles and self-reconstruction, hold great promise for optical communication, particle trapping, and laser material processing. However, designing optical elements for shaping PCBs remains a significant challenge. We present a differentiable design method of freeform lenses for shaping PCBs. This method employs multi-level B-splines to represent the freeform surface. The key issue of our differential design method lies in the integration with a fast-forward simulation approach. The forward simulation approach models the PCBs’ diffraction pattern by efficiently computing the convolution of the coherent diffraction pattern and a kernel determined by the degree of coherence. Specifically, for the beam shaping of a “π” pattern, the computational speed of our method is approximately 22 times that of the conventional modal representation method.polynomials.

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Differentiable design of freeform lenses for partially coherent beam shaping

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