Deep learning reconstruction of ultrashort pulses from 2D spatial intensity patterns recorded by an all-in-line system in a single-shot

Ziv, Ron; Dikopoltsev, Alex; Zahavy, Tom; Rubinstein, Ittai; Sidorenko, Pavel; Cohen, Oren; Segev, Mordechai

doi:10.1364/oe.383217

Cited by 32 publications

(22 citation statements)

References 28 publications

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“…Again we normalize the pulse energy, here by means of N β , as before in Eqs. (1) and (9). The predicted spectra are shown in Fig.…”

Section: Prediction Of Spectra From Chirped Pulsesmentioning

confidence: 99%

“…Machine learning (ML) has recently been applied not only in physics 1,2,3 , but more specifically also in strong-field physics 4,5,6 . One of the most abundant topic has been the reconstruction of the temporal shape of an ultrashort laser pulse, aided by ML techniques 7,8,9 . The most popular technique for this reconstruction have been different variants of streaking techniques which require normally considerable additional experimental effort, namely a Terahertz laser light source.…”

Section: Introductionmentioning

confidence: 99%

“…However, also a Max Planck Institute for the Physics of Complex Systems Nöthnitzer Str. 38, 01187 Dresden, Germany b E-mail: sajal@pks.mpg.de c E-mail: lalonso@pks.mpg.de d E-mail: us@pks.mpg.de e E-mail: rost@pks.mpg.de a direct method from single-shot spectra has been introduced 9 .…”

Section: Introductionmentioning

confidence: 99%

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Perspectives for analyzing non-linear photo-ionization spectra with deep neural networks trained with synthetic Hamilton matrices

et al. 2021

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“…Again we normalize the pulse energy, here by means of N β , as before in Eqs. (1) and (9). The predicted spectra are shown in Fig.…”

Section: Prediction Of Spectra From Chirped Pulsesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Perspectives for analyzing non-linear photo-ionization spectra with deep neural networks trained with synthetic Hamilton matrices

et al. 2021

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“…Previously, neural networks were shown to be successful in pulse retrieval from 2D data-sets: FROG traces [21,22,23,24], D-Scan traces [25], speckles at the output of a multi-mode fiber [26], and streak traces characterising attosecond pulses [27]. However, neural-network-assisted reconstruction of ultrashort pulses from 1D interferometric cross-correlation data-sets, to the best of our knowledge, have not been demonstrated previously, and our proof-of-principle work aims to fill this gap, as summarized below.…”

Section: Introductionmentioning

confidence: 99%

Neural-network-powered pulse reconstruction from one-dimensional interferometric cross-correlation traces

Kolesnichenko¹,

Zigmantas²

2021

Preprint

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Any ultrafast optical spectroscopy experiment is usually accompanied by the necessary routine of ultrashort-pulse characterisation. The majority of pulse characterisation approaches solve either a one-dimensional (e.g. via interferometry) or a two-dimensional (e.g. via frequency-resolved measurements) problem.Solution of the two-dimensional pulse-retrieval problem is generally more consistent due to problem's over-determined nature. In contrast, the one-dimensional pulse-retrieval problem is impossible to solve unambiguously as ultimately imposed by the fundamental theorem of algebra. In cases where additional constraints are involved, the one-dimensional problem may be possible to solve, however, existing iterative algorithms lack generality, and often stagnate for complicated pulse shapes. Here we use a deep neural network to unambiguously solve a constrained one-dimensional pulse-retrieval problem and show the potential of fast, reliable and complete pulse characterisation using interferometric cross-correlation time traces (determined by the pulses with partial spectral 1

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“…Recent trends in artificial intelligence have led to a proliferation of studies on deep learning (DL) algorithm and its utilization in diverse fields, such as biology [26][27][28], chemistry [29][30][31], and physics [32][33][34]. In particular, one important aspect pertaining to DL is its capability of characterizing and predicting the physical properties for photonic structures [35][36][37], including the reconstruction of ultrashort pulses [38,39], the wave-front sensing [40], and the design of metasurfaces [41], chiral metamaterials [42,43] and electromagnetic nanostructures [44][45][46][47]. Furthermore, the DL scheme has also penetrated into computational physics, covering the areas of estimating stress distribution [48], assisting computational mechanics [49], capturing nonlinear material behaviors [50] and predicting plasmonic colors [51], whose main advantages over the conventional finite element method are that it not only speeds up the investigation process, but also creates many nonintuitive designs with distinguished performance.…”

Section: Introductionmentioning

confidence: 99%

Exploiting deep learning network in optical chirality tuning and manipulation of diffractive chiral metamaterials

Tao

Zhang

You³

et al. 2020

Nanophotonics

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AbstractDeep-learning (DL) network has emerged as an important prototyping technology for the advancements of big data analytics, intelligent systems, biochemistry, physics, and nanoscience. Here, we used a DL model whose key algorithm relies on deep neural network to efficiently predict circular dichroism (CD) response in higher-order diffracted beams of two-dimensional chiral metamaterials with different parameters. To facilitate the training process of DL network in predicting chiroptical response, the traditional rigorous coupled wave analysis (RCWA) method is utilized. Notably, these T-like shaped chiral metamaterials all exhibit the strongest CD response in the third-order diffracted beams whose intensities are the smallest, when comparing up to four diffraction orders. Our comprehensive results reveal that by means of DL network, the complex and nonintuitive relations between T-like metamaterials with different chiral parameters (i. e., unit period, width, bridge length, and separation length) and their CD performances are acquired, which owns an ultrafast computational speed that is four orders of magnitude faster than RCWA and a high accuracy. The insights gained from this study may be of assistance to the applications of DL network in investigating different optical chirality in low-dimensional metamaterials and expediting the design and optimization processes for hyper-sensitive ultrathin devices and systems.

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Deep learning reconstruction of ultrashort pulses from 2D spatial intensity patterns recorded by an all-in-line system in a single-shot

Cited by 32 publications

References 28 publications

Perspectives for analyzing non-linear photo-ionization spectra with deep neural networks trained with synthetic Hamilton matrices

Perspectives for analyzing non-linear photo-ionization spectra with deep neural networks trained with synthetic Hamilton matrices

Neural-network-powered pulse reconstruction from one-dimensional interferometric cross-correlation traces

Exploiting deep learning network in optical chirality tuning and manipulation of diffractive chiral metamaterials

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