Litcius/Paper detail

Exploring Multi-Fidelity Data in Materials Science: Challenges, Applications, and Optimized Learning Strategies

Ziming Wang, Xiaotong Liu, Haotian Chen, Tao Yang, Yurong He

2023Applied Sciences12 citationsDOIOpen Access PDF

Abstract

Machine learning techniques offer tremendous potential for optimizing resource allocation in solving real-world problems. However, the emergence of multi-fidelity data introduces new challenges. This paper offers an overview of the definition, applications, data preprocessing methodologies, and learning approaches associated with multi-fidelity data. To validate the algorithms, we examine three widely-used learning methods relevant to multi-fidelity data through the design of multi-fidelity datasets that encompass various types of noise. As we expected, employing multi-fidelity data learning methods yields better results compared to solely using high-fidelity data learning methods. Additionally, considering the inherent various types of noise within datasets, the comprehensive correction strategy proves to be the most effective. Moreover, multi-fidelity learning methods facilitate effective decision-making processes by enabling the combination of datasets from various sources. They extract knowledge from lower fidelity data, improving model accuracy compared to models solely relying on high-fidelity data.

Topics & Concepts

FidelityComputer sciencePreprocessorMachine learningData pre-processingArtificial intelligenceTelecommunicationsMachine Learning in Materials ScienceComputational Drug Discovery MethodsSoftware Engineering Research