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Authors: Yunhui Gao ([email protected]) and Liangcai Cao ([email protected])

HoloLab, Tsinghua University


Figure 1. Overview of the proposed method. (a) Schematic of the in-line holographic imaging system. (b) Captured raw hologram of a transparent Fresnel zone plate. Scale bar 1 mm. (c) Retrieved phase distribution. (d) Rendered surface height profile.

Requirements

Matlab 2019a or newer. Older visions may be sufficient but have not been tested.

Quick Start

  • Phase retrieval using simulated data. Run demo_sim.m with default parameters.
  • Phase retrieval using experimental data. First follow the instruction here to download the data. Then run demo_exp.m with default parameters.
  • Try on your own experiment data. Prepare a hologram and an optional reference image, run preprocessing.m and set the experiment parameters (e.g. pixel size, wavelength, and sample-to-sensor distance). Then run demo_exp.m and see how it works.

Accelerated Implementations

The basic demo codes provide intuitive and proof-of-concept implementations for beginners, but are far from efficient. To facilitate faster reconstruction, we provide an optimized version based on CPU or GPU, which can be found at demo_sim_fast.m and demo_exp_fast.m for simulated and experimental data, respectively. To enable GPU usage, simply set gpu = true; in the code.

Table 1 and Figure 2 show the runtime (200 iterations) for different image dimensions. The results are obtained using a laptop computer with Intel® Core™ i7-12700H (2.30 GHz) CPU and Nvidia GeForce RTX™ 3060 GPU.

Image dimension CPU runtime (s) GPU runtime (s)
128 $\times$ 128 0.673 0.704
256 $\times$ 256 2.76 0.824
512 $\times$ 512 8.76 1.25
1024 $\times$ 1024 31.8 3.67
2048 $\times$ 2048 130.8 13.2

Table 1. Runtimes (for 200 iterations) using GPU and CPU for different image dimensions.

Figure 2. Runtimes (for 200 iterations) using GPU and CPU for different image dimensions.

Theories and References

For algorithm derivation and implementation details, please refer to our paper:

  • Yunhui Gao and Liangcai Cao, "Iterative projection meets sparsity regularization: towards practical single-shot quantitative phase imaging with in-line holography," Light: Advanced Manufacturing 4(1), 37-53 (2023). Publication page | Paper (PDF) | Supplement (PDF)

Citation

@article{gao2023iterative,
  title={Iterative projection meets sparsity regularization: towards practical single-shot quantitative phase imaging with in-line holography},
  author={Gao, Yunhui and Cao, Liangcai},
  journal={Light: Advanced Manufacturing},
  volume={4},
  number={1},
  pages={37--53},
  year={2023},
  publisher={Light: Advanced Manufacturing}
}