Binary wavefront optimization using a simulated annealing algorithm

Fang, Longjie; Zuo, Haoyi; Yang, Zuogang; Zhang, Xicheng; Du, Jinglei; Pang, Lin

doi:10.1364/ao.57.001744

Cited by 26 publications

(8 citation statements)

References 28 publications

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“… 55 , 78 , 79 The input-output mapping is inevitably relaxed for adaptive modulation, and feedback-based optimization is therefore required. These optimization algorithms, including evolutional algorithms, 79 , 80 , 81 , 82 , 83 , 84 , 85 artificial intelligence algorithms, 86 , 87 , 88 and their combination, 89 , 90 can instantly modify the modulation patterns while screening the feedback variations. Encountering stronger variations (e.g., a dynamic medium), optimization with physics prior 91 , 92 , 93 works more efficiently, which quantifies the error in the optimized wavefront for optical focusing, while previously the number of to-be-corrected pixels on a spatial light modulator (SLM) is empirically guessed.…”

Section: Principlementioning

confidence: 99%

Wavefront shaping: A versatile tool to conquer multiple scattering in multidisciplinary fields

Zhong

et al. 2022

The Innovation

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Section: Principlementioning

confidence: 99%

Wavefront shaping: A versatile tool to conquer multiple scattering in multidisciplinary fields

Zhong

et al. 2022

The Innovation

View full text Add to dashboard Cite

“…In this technique, the wavefront of incident light is iteratively modulated by a spatial light modulator (SLM) according to the feedback signals from a detector (e.g., camera or photodetector) placed behind the scattering medium or a guidestar (e.g., fluorescent or photoacoustic emission as a virtual guidestar 40,41 ) within the scattering medium; hence, the optical distortions can be compensated and an optical focus or the desired output field can be obtained at the target location. Several metaheuristic optimization algorithms, such as genetic algorithm (GA), [17][18][19][20][21] particle swarm optimization (PSO), [22][23][24][25][26] simulated annealing algorithm (SA), 27,28 bat algorithm (BA), 31 ant colony optimization (ACO), 32 and separable natural evolution strategies (SNES), 33 have been demonstrated for successful optical focusing inside/through scattering media. Aiming for faster and better optimization results, researchers have improved different algorithms primarily in three ways: optimizing parameters, introducing variants of the algorithms, such as microgenetic algorithm (μGA), 19 particle swarm optimization with mutation, 26 and improved ant colony optimization (IACO); 32 and exploiting hybrid algorithms, such as parameter-free algorithm (PFA), a combination of genetic algorithm and bat algorithm, 30 and Genetic Neural Network (GeneNN), a hybrid of GA and deep neural networks.…”

Section: Introductionmentioning

confidence: 99%

Optimal efficiency of focusing diffused light through scattering media with iterative wavefront shaping

et al. 2022

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Iterative wavefront shaping is a powerful tool to overcome optical scattering and enable focusing of diffusive light, which has exciting potentials in many applications that desire localized light delivery at depths in tissue-like complex media. Unsatisfactory performance and efficiency, however, have been a long-standing problem, and the large discrepancy between theoretical and experimental results has hindered the wide applications of the technology. Currently, most algorithms guiding the iterative search of optimum phase compensation rely heavily on randomness to achieve solution diversity. It is similar to black-box optimization in which the mechanism of how a good solution is arrived at is unclear. The lack of clear guidance on the new solution generation process considerably affects the efficiency of optimization. Therefore, we propose a probability-based iterative algorithm combining genetic algorithm (GA) and ant colony optimization (ACO), in which the new solutions can be generated based on a probability map. Thanks to the clearer guidance provided by the probability map and the reduced involvement of randomness, we are able to obtain optimization results with optimal efficiency for single and multiple focuses behind scattering media. Besides, with the proposed algorithm, we also demonstrate higher adaptability in an unstable scattering environment and more spatially uniform optical focusing in the field of view. This study advances the state-of-the-art in the practice of iterative wavefront shaping. More importantly, the significant improvement in optimization efficiency and adaptability, if further engineered, can potentially inspire or open up wide applications that desire localized and enhanced optical delivery in situ.

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“…However, due to the inhomogeneities of refractive index in biological tissue, photons are multiply scattered in tissue sample and the amount of ballistic photons decays exponentially with increasing propagation depth, limiting high-resolution optical imaging to a depth of ~1 mm beneath the skin or tissue surface 1 . Thanks to the emergence of optical wavefront shaping techniques, scattering-induced wavefront distortions nowadays can be compensated via various approaches, such as optical phase conjugation [2][3][4][5][6][7][8] , transmission matrix method 9-12 , iterative optimization [13][14][15][16][17][18][19][20][21][22][23][24][25][26][27][28][29] , and artificialintelligence-assisted methods [30][31][32][33] , allowing optical focusing or imaging inside/through scattering media. Iterative optimization approaches are widely adopted because they are straightforward and less technically demanding.…”

Section: Introductionmentioning

confidence: 99%

“…In this technique, the wavefront of incident light is iteratively modulated by a spatial light modulator (SLM) according to the feedback signals from a detector (e.g., camera or photodetector) placed behind the scattering medium or a guidestar (e.g., fluorescent or photoacoustic emission as a virtual guidestar 34,35 ) within the scattering medium, so that the optical distortions can be compensated and an optical focus or a desired output field can be obtained at the target location. Several metaheuristic optimization algorithms, such as genetic algorithm (GA) [15][16][17][18] , particle swarm optimization (PSO) [19][20][21][22][23] , simulated annealing algorithm (SA) 24,25 , bat algorithm (BA) 28 , and separable natural evolution strategies (SNES) 29 , have been demonstrated for successful optical focusing inside/through scattering media. Aiming for faster and better optimization results, researchers have improved different algorithms primarily in three ways: optimizing parameters, introducing variants of the algorithms (e.g., microgenetic algorithm (μGA) 17 and particle swarm optimization with mutation 23 ), and exploiting hybrid algorithms (e.g., parameter-free algorithm (PFA), a combination of genetic algorithm and bat algorithm 27 , and Genetic Neural Network (GeneNN), a hybrid of GA and deep neural networks 31 ).…”

Section: Introductionmentioning

confidence: 99%

Approaching the optimum focusing of diffused light through scattering media with iterative wavefront shaping by a probability-based algorithm

Woo

Zhao

Zhong

et al. 2022

Preprint

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Iterative wavefront shaping is a powerful tool to overcome medium scattering and enable focusing of diffusive light, which has exciting potentials in many applications that desire localized light delivery at depths in tissue-like complex media. Unsatisfactory performance and efficiency, however, have been a long-standing problem, and the large discrepancy between theoretical and experimental results has hindered the wide applications of the technology. Currently, most algorithms guiding the iterative search of optimal phase compensation rely heavily on randomness to achieve solution diversity. The lack of clear guidance on the new solution generation process considerably affects the optimization efficiency. Therefore, we propose a probability-based iterative algorithm that the new solutions are generated based on a probability map. With the clearer guidance provided by the probability map and less involvement of randomness, we can obtain optimization results that efficiently approach the theoretical optimal value. Moreover, with the proposed algorithm, we demonstrate higher adaptability in an unstable scattering environment and more spatially uniform optical focusing in the field of view. This study advances the state of the art in the practice of iterative wavefront shaping and can potentially inspire or open up wide applications that desire localized and enhanced optical delivery in situ.

show abstract

Binary wavefront optimization using a simulated annealing algorithm

Cited by 26 publications

References 28 publications

Wavefront shaping: A versatile tool to conquer multiple scattering in multidisciplinary fields

Wavefront shaping: A versatile tool to conquer multiple scattering in multidisciplinary fields

Optimal efficiency of focusing diffused light through scattering media with iterative wavefront shaping

Approaching the optimum focusing of diffused light through scattering media with iterative wavefront shaping by a probability-based algorithm

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