Artificial intelligence methods for applied superconductivity: material, design, manufacturing, testing, operation, and condition monitoring

Yazdani-Asrami, Mohammad; Sadeghi, Alireza; Song, Wenjuan; Madureira, Ana; Pina, João Murta; Morandi, Antonio; Parizh, Michael

doi:10.1088/1361-6668/ac80d8

Cited by 38 publications

(30 citation statements)

References 357 publications

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“…Superconducting magnets face multiple challenges during design, manufacturing, and test stages such as manufacturing tolerances, shimming coil design, inhomogeneity of magnetic field, quench-related issues, and the extremely time-consuming magnetic field computation procedure. Artificial intelligence (AI)-based techniques are the shortcuts towards the solutions for these challenges [4,5].…”

Section: Introductionmentioning

confidence: 99%

Ultra-fast Surrogate Model for Magnetic Field Computation of a Superconducting Magnet Using Multi-layer Artificial Neural Networks

Yazdani-Asrami

Sadeghi

Song

2023

J Supercond Nov Magn

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Due to the inherent nonlinear and sophisticated nature of superconducting wires/tapes, magnetic field computation of superconducting magnets by means of finite element methods (FEMs) is a time-consuming and complicated procedure. Although Legendre series method (LSM) was proposed as an alternative of FEMs, LSMs are not still fast enough. In current research, a surrogate model based on multi-layer artificial neural networks (ANNs) was introduced for the first time to dramatically reduce the computation time of a magnetic resonance imaging (MRI) magnet. To do this, firstly, the data related to the magnetic field were extracted based on LSM simulations for around 5000 different coil geometries. After that, the geometries of coils were used as inputs to a semi-deep learning ANN-based model in MATLAB software package. The minimum magnetic field in diameter spherical volume, maximum and minimum of total magnetic field were considered as outputs of the model, known as field indices. Then, ANN model was trained to calculate these field indices for any coil geometry. By doing so, magnetic field indices were estimated with a high accuracy based on the target values and also with extremely higher speed, comparing to FEM and LSM. Results showed that it takes 15 to 17 s for the proposed model to calculate the field indices for 750 different geometries whereas it takes for LSM-based model about 4 h.

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Section: Introductionmentioning

confidence: 99%

Ultra-fast Surrogate Model for Magnetic Field Computation of a Superconducting Magnet Using Multi-layer Artificial Neural Networks

Yazdani-Asrami

Sadeghi

Song

2023

J Supercond Nov Magn

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“…UPERCONDUCTING technology is generally very promising for being used for applications in power systems, aviation industry, and healthcare sector in devices such as magnetic resonance imaging/nuclear magnetic resonance magnets [1]- [5], High Temperature Superconducting (HTS) cables [6]- [8], superconducting machines [9], [10], superconducting fault current limiters [11], [12], superconducting magnetic energy storage units [13], [14], and HTS transformers [15], [16]. In superconducting magnets, as one of the most successfully commercialised applications of superconductors, low temperature superconducting wires and This manuscript was received 04 May 2022, revised 10 July 2022, accepted 22 July 2022.…”

Section: Introductionmentioning

confidence: 99%

“…These models are capable of considering multiple variables for determining the characteristic of HTS tapes without giving up on the accuracy or estimation speed. Last recently, AI models were used to design [21], monitor [22], and estimate [23] different characteristics and performances of superconducting devices. In [24], a novel AI approach was introduced to estimate the stress and Jc in HTS tapes.…”

Section: Introductionmentioning

confidence: 99%

DC Electro-Magneto-Mechanical Characterization of 2G HTS Tapes for Superconducting Cable in Magnet System Using Artificial Neural Networks

Yazdani-Asrami

Sadeghi

Seyyedbarzegar

et al. 2022

IEEE Trans. Appl. Supercond.

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“…In the search for high critical temperature (T c ) superconductors, significant progress has been made during the last decade [1][2][3]. Among thousands of hydride-based superconducting materials computationally predicted [4][5][6][7][8][9][10][11][12], mostly at very high pressures, e.g., P 100 GPa, dozens of them, e.g., H 3 S [1], LaH 10 [2], and CSH [3], were synthesized and tested. This active research area is presumably motivated by Ashcroft, who, in 2004, predicted [13] that high-T c superconductivity may be found in hydrogen dominant metallic alloys, probably at high P .…”

Section: Introductionmentioning

confidence: 99%

“…Machine-learning (ML) methods have recently emerged in the discoveries of superconductors [9,10]. As sketched in Fig.…”

Section: Introductionmentioning

confidence: 99%

Machine-learning approach for discovery of conventional superconductors

Huan¹,

Vu²

2022

Preprint

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First-principles computations are the driving force behind numerous discoveries of hydride-based superconductors, mostly at high pressures, during the last decade. Machine-learning (ML) approaches can further accelerate the future discoveries if their reliability can be improved. The main challenge of current ML approaches, typically aiming at predicting the critical temperature Tc of a solid from its chemical composition and target pressure, is that the correlations to be learned are deeply hidden, indirect, and uncertain. In this work, we showed that predicting superconductivity at any pressure from the atomic structure is sustainable and reliable. For a demonstration, we curated a diverse dataset of 584 atomic structures for which λ and ω log , two parameters of the electronphonon interactions, were computed. We then trained some ML models to predict λ and ω log , from which Tc can be computed in a post-processing manner. The models were validated and used to identify two possible superconductors whose Tc 10 − 15K and zero pressure. Going forward, this strategy will be improved to better contribute to the discoveries of new superconductors.

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Artificial intelligence methods for applied superconductivity: material, design, manufacturing, testing, operation, and condition monitoring

Cited by 38 publications

References 357 publications

Ultra-fast Surrogate Model for Magnetic Field Computation of a Superconducting Magnet Using Multi-layer Artificial Neural Networks

Ultra-fast Surrogate Model for Magnetic Field Computation of a Superconducting Magnet Using Multi-layer Artificial Neural Networks

DC Electro-Magneto-Mechanical Characterization of 2G HTS Tapes for Superconducting Cable in Magnet System Using Artificial Neural Networks

Machine-learning approach for discovery of conventional superconductors

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