Bayesian Active Learning for Scanning Probe Microscopy: From Gaussian Processes to Hypothesis Learning

Ziatdinov, Maxim; Liu, Yongtao; Kelley, Kyle P.; Vasudevan, Rama K.; Kalinin, Sergei V.

doi:10.1021/acsnano.2c05303

Cited by 39 publications

(24 citation statements)

References 92 publications

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“…We implemented our system in an experimental set up and demonstrated that the strain mapping task can be performed in nearly 2.4 h instead of the typical 6 h for a specific study on an AM steel part. Our work builds on a larger trend of moving towards autonomous scanning probe imaging systems [18,25] in cases where the time to measure is significantly higher than the sum of the time to re-position the object and computation of the next informative measurement to make. In such systems, there can be an overall saving in experimental measurement time while providing a progressively improved image resolution by employing a powerful algorithm that can infer the underlying structure from a sparse set of measurement points.…”

Section: Discussionmentioning

confidence: 99%

“…where X prev is the set of all the previous locations on the grid at which a measurement has been made. This type of approach is called BO [25] because we effectively compute the posterior distribution parameters based on some underlying prior model to infer the next point(s) to measure. A simple acquisition function is one that simply uses the variance estimates ('uncertainty') at each position from equation ( 5) and chooses to measure the next point at the position corresponding to the highest variance.…”

Section: Gp Regression and Bomentioning

confidence: 99%

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Adaptive sampling for accelerating neutron diffraction-based strain mapping ^*

Venkatakrishnan

Fancher

Ziatdinov³

et al. 2023

Mach. Learn.: Sci. Technol.

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Neutron diffraction is a useful technique for mapping residual strains in dense metal objects. The technique works by placing an object in the path of a neutron beam, measuring the diffracted signals and inferring the local lattice strain values from the measurement. In order to map the strains across the entire object, the object is stepped one position at a time in the path of the neutron beam, typically in raster order, and at each position a strain value is estimated. Typical dwell times at neutron diffraction instruments result in an overall measurement that can take several hours to map an object that is several tens of centimeters in each dimension at a resolution of a few millimeters, during which the end users do not have an estimate of the global strain features and are at risk of incomplete information in case of instruments outages. In this paper, we propose an object adaptive sampling strategy to measure the significant points first. We start with a small initial uniform set of measurement points across the object to be mapped, compute the strain in those positions and use a machine learning technique to predict the next position to measure in the object. Specifically,we use a Bayesian optimization based on a Gaussian process regression method to infer the underlying strain field from a sparse set of measurements and predict the next most informative positions to measure based on estimates of the mean and variance in the strain fields estimated from the previously measured points. We demonstrate our real-time measure-infer-predict workflow on additively manufactured steel parts- demonstrating that we can get an accurate strain estimate even with 30-40% of the typical number of measurements - leading the path to faster strain mapping with useful real-time feedback. We emphasize that the proposed method is general and can be used for fast mapping of other material properties such as phase fractions from time-consuming point-wise neutron measurements.

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Section: Discussionmentioning

confidence: 99%

Section: Gp Regression and Bomentioning

confidence: 99%

Adaptive sampling for accelerating neutron diffraction-based strain mapping ^*

Venkatakrishnan

Fancher

Ziatdinov³

et al. 2023

Mach. Learn.: Sci. Technol.

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“…DKL poses to be one of the potential solutions to the problems that are discussed so far. DKL is a method that combines the power of deep neural networks with the flexibility of Gaussian Processes (GPs) to model and make predictions on complex target functions in high-dimensional spaces [59][60][61][62][63]. The ability to efficiently explore the high-dimensional input space and learn the relationship between the inputs and target function, makes it a powerful tool for optimization and prediction tasks.…”

Section: Latent Distributions For the Dkl Of Model Datamentioning

confidence: 99%

Deep kernel methods learn better: from cards to process optimization

Valleti,

Vasudevan,

Ziatdinov

et al. 2024

Mach. Learn.: Sci. Technol.

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The ability of deep learning methods to perform classification and regression tasks relies heavily on their capacity to uncover manifolds in high-dimensional data spaces and project them into low-dimensional representation spaces. In this study, we investigate the structure and character of the manifolds generated by classical variational autoencoder (VAE) approaches and deep kernel learning (DKL). In the former case, the structure of the latent space is determined by the properties of the input data alone, while in the latter, the latent manifold forms as a result of an active learning process that balances the data distribution and target functionalities. We show that DKL with active learning can produce a more compact and smooth latent space which is more conducive to optimization compared to previously reported methods, such as the VAE. We demonstrate this behavior using a simple cards data set and extend it to the optimization of domain-generated trajectories in physical systems. Our findings suggest that latent manifolds constructed through active learning have a more beneficial structure for optimization problems, especially in feature-rich target-poor scenarios that are common in domain sciences, such as materials synthesis, energy storage, and molecular discovery. The jupyter notebooks that encapsulate the complete analysis accompany the article.

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“…Moreover, much of modern microscopy has advanced with applications of deep learning [16] and other machine learning methods, [17] assisting in everything from data cleaning, [18] to improved functional fits, [19] image segmentation, [20] and recently, to autonomous microscopy operations. [21,22] Therefore, datasets should be able to be used in distributed systems or supercomputer centers. As such, with the recent advancement in automated platforms, standardizing the data model and processing pipelines is an imperative for maximizing the utility of microscopy, and for reducing the significant bottlenecks in the analysis, storage, processing, and retrieval that are currently within traditional experimental paradigms.…”

Section: Introductionmentioning

confidence: 99%

A Processing and Analytics System for Microscopy Data Workflows: The Pycroscopy Ecosystem of Packages

Vasudevan,

Valleti,

Ziatdinov

et al. 2023

Advcd Theory and Sims

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Major advancements in fields as diverse as biology and quantum computing have relied on a multitude of microscopy techniques. Despite the considerable proliferation of these instruments, significant bottlenecks remain in terms of processing, analysis, storage, and retrieval of the acquired datasets. Aside from lack of file standards, individual domain‐specific analysis packages are often disjoint from the underlying datasets, and thus keeping track of analysis and processing steps remains tedious for the end‐user, hampering reproducibility. Here, the pycroscopy ecosystem of packages is introduced, an open‐source python‐based ecosystem underpinned by a common data model. The data model, termed the N‐dimensional spectral imaging data format, is realized in pycroscopy's sidpy package. This package is built on top of dask arrays, thus leveraging dask array attributes, but expanding them to accelerate microscopy relevant analysis and visualization. Several examples of the use of the pycroscopy ecosystem to create workflows for data ingestion and analysis of scanning transmission electron microscopy (STEM) and scanning probe microscopy data are shown. Adoption of such standardized routines will be critical to usher in the next generation of autonomous instruments where processing, computation, and meta‐data storage will be critical to overall experimental operations.

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Bayesian Active Learning for Scanning Probe Microscopy: From Gaussian Processes to Hypothesis Learning

Cited by 39 publications

References 92 publications

Adaptive sampling for accelerating neutron diffraction-based strain mapping ^*

Adaptive sampling for accelerating neutron diffraction-based strain mapping ^*

Deep kernel methods learn better: from cards to process optimization

A Processing and Analytics System for Microscopy Data Workflows: The Pycroscopy Ecosystem of Packages

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Bayesian Active Learning for Scanning Probe Microscopy: From Gaussian Processes to Hypothesis Learning

Cited by 39 publications

References 92 publications

Adaptive sampling for accelerating neutron diffraction-based strain mapping *

Adaptive sampling for accelerating neutron diffraction-based strain mapping *

Deep kernel methods learn better: from cards to process optimization

A Processing and Analytics System for Microscopy Data Workflows: The Pycroscopy Ecosystem of Packages

Contact Info

Product

Resources

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Adaptive sampling for accelerating neutron diffraction-based strain mapping ^*

Adaptive sampling for accelerating neutron diffraction-based strain mapping ^*