sFEA: A Lightweight, Scalable, and Secure Finite Element Analysis Technique

Chaduvula, Siva Chaitanya; Atallah, Mikhail J.; Panchal, Jitesh H.

doi:10.1115/detc2018-85566

Volume 1A: 38th Computers and Information in Engineering Conference 2018

DOI: 10.1115/detc2018-85566

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sFEA: A Lightweight, Scalable, and Secure Finite Element Analysis Technique

Siva Chaitanya Chaduvula

Mikhail J. Atallah

Jitesh H. Panchal

Abstract: Designers need a way to overcome information related risks, including information leakage and misuse from their own collaborators during a collaborative product realization process. Existing cryptographic techniques aimed at overcoming these information related risks are computationally expensive and slow even for moderate problem sizes, and legal approaches (e.g., the use of non-disclosure agreements) are not effective. The computational practicality problem is particularly pronounced for simulation computati… Show more

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“…We believe that further research in this direction can help designers preserve confidential information while performing engineering analysis securely. This work was presented at the ASME IDETC/CIE 2018 conference [13].…”

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confidence: 99%

sFEA: A Secure Finite Element Analysis Technique

Chaduvula

Atallah

Panchal

2019

Journal of Computing and Information Science in Engineering

Self Cite

View full text Add to dashboard Cite

Designers need a way to overcome information-related risks, including information leakage and misuse by their own collaborators during collaborative product realization. Existing cryptographic techniques aimed at overcoming these information-related risks are computationally expensive and impractical even for moderate problem sizes, and legal approaches such as nondisclosure agreements are not effective. The computational practicality problem is particularly pronounced for computational techniques, such as the finite element analysis (FEA). In this paper, we propose a technique that enables designers to perform simulations, such as FEA computations, without the need for revealing their information to anyone, including their design collaborators. We present a new approach, the secure finite element analysis approach, which enables designers to perform FEA without having to reveal structural/material information to their counterparts even though the computed answer depends on all the collaborators' confidential information. We build secure finite element analysis (sFEA) using computationally efficient protocols implementing a secure codesign (SCD) framework. One of our findings is that the direct implementation of using SCD framework (termed as naïve sFEA) suffers from lack of scalability. To overcome these limitations, we propose hybrid sFEA that implements performance improvement strategies. We document and discuss the experiments we conducted to determine the computational overhead imposed by both naïve and hybrid sFEA. The results indicate that the computational burden imposed by hybrid sFEA makes it challenging for large-scale FEA—our scheme significantly increases the problem sizes that can be handled when compared to implementations using previous algorithms and protocols, but large enough problem sizes will swamp our scheme as well (in some sense this is unavoidable because of the cubic nature of the FEA time complexity).

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confidence: 99%

sFEA: A Secure Finite Element Analysis Technique

Chaduvula

Atallah

Panchal

2019

Journal of Computing and Information Science in Engineering

Self Cite

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Security in Cyber-Enabled Design and Manufacturing: A Survey

Chaduvula

Dachowicz

Atallah

et al. 2018

Journal of Computing and Information Science in Engineering

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Developments in digital technology and manufacturing processes have expanded the horizon of designer innovation in creating products. In addition to this, real-time collaborative platforms help designers shorten the product development cycle by enabling collaborations with domain experts from concept generation to product realization and after-market. These collaborations are extending beyond enterprise and national boundaries, contributing to a growing concern among designers regarding the security of their sensitive information such as intellectual property (IP) and trade secrets. The source of such sensitive information leaks could be external (e.g., hacker) or internal (e.g., disgruntled employee) to the collaboration. From a designer's perspective, this fear can inhibit participation in a collaboration even though it might result in better products or services. In this paper, we aim to contextualize this evolving security space by discussing various security practices in digital domains, such as encryption and secret sharing, as well as manufacturing domains, such as physically unclonable function (PUF) and physical part watermarking for anticounterfeiting and tamper evidence purposes. Further, we classify these practices with respect to their performance against different adversarial models for different stages in product development. Such a classification can help designers to make informed decisions regarding security practices during the product realization process.

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sFEA: A Lightweight, Scalable, and Secure Finite Element Analysis Technique

Cited by 2 publications

References 23 publications

sFEA: A Secure Finite Element Analysis Technique

sFEA: A Secure Finite Element Analysis Technique

Security in Cyber-Enabled Design and Manufacturing: A Survey

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