Related papers: Data Publishing in Mechanics and Dynamics: Challenges, Guidelines, and Examples from Engineering Design

Data Publishing in Mechanics and Dynamics: Challenges, Guidelines, and Examples from Engineering Design

URL: http://arxiv.org/abs/2410.18358v1
Date: Mon, 07 Oct 2024 18:26:05 GMT
Title: Data Publishing in Mechanics and Dynamics: Challenges, Guidelines, and Examples from Engineering Design
Authors: Henrik Ebel, Jan van Delden, Timo Lüddecke, Aditya Borse, Rutwik Gulakala, Marcus Stoffel, Manish Yadav, Merten Stender, Leon Schindler, Kristin Miriam de Payrebrune, Maximilian Raff, C. David Remy, Benedict Röder, Peter Eberhard,
Abstract summary: This article analyzes the value and challenges of data publishing in mechanics and dynamics. It shows that the latter raise also challenges and considerations not typical in fields where data-driven methods have been booming originally.
Score: 4.065325208853021
License:
Abstract: Data-based methods have gained increasing importance in engineering, especially but not only driven by successes with deep artificial neural networks. Success stories are prevalent, e.g., in areas such as data-driven modeling, control and automation, as well as surrogate modeling for accelerated simulation. Beyond engineering, generative and large-language models are increasingly performing and helping with tasks that, previously, were solely associated with creative human processes. Thus, it seems timely to seek artificial-intelligence-support for engineering design tasks to automate, help with, or accelerate purpose-built designs of engineering systems, e.g., in mechanics and dynamics, where design so far requires a lot of specialized knowledge. However, research-wise, compared to established, predominantly first-principles-based methods, the datasets used for training, validation, and test become an almost inherent part of the overall methodology. Thus, data publishing becomes just as important in (data-driven) engineering science as appropriate descriptions of conventional methodology in publications in the past. This article analyzes the value and challenges of data publishing in mechanics and dynamics, in particular regarding engineering design tasks, showing that the latter raise also challenges and considerations not typical in fields where data-driven methods have been booming originally. Possible ways to deal with these challenges are discussed and a set of examples from across different design problems shows how data publishing can be put into practice. The analysis, discussions, and examples are based on the research experience made in a priority program of the German research foundation focusing on research on artificially intelligent design assistants in mechanics and dynamics.

Related papers

Deep Learning and Machine Learning: Advancing Big Data Analytics and Management with Design Patterns [17.624263707781655]
The book explores the application of classical software engineering patterns to optimize the development, maintenance, and scalability of big data analytics systems. Key design patterns such as Singleton, Factory, Observer, and Strategy are analyzed for their impact on model management, deployment strategies, and team collaboration. This volume is an essential resource for developers, researchers, and engineers aiming to enhance their technical expertise in both machine learning and software design.
arXiv Detail & Related papers (2024-10-04T02:50:58Z)
AI Foundation Models in Remote Sensing: A Survey [6.036426846159163]
This paper provides a comprehensive survey of foundation models in the remote sensing domain. We categorize these models based on their applications in computer vision and domain-specific tasks. We highlight emerging trends and the significant advancements achieved by these foundation models.
arXiv Detail & Related papers (2024-08-06T22:39:34Z)
A spectrum of physics-informed Gaussian processes for regression in engineering [0.0]
Despite the growing availability of sensing and data in general, we remain unable to fully characterise many in-service engineering systems and structures from a purely data-driven approach. This paper pursues the combination of machine learning technology and physics-based reasoning to enhance our ability to make predictive models with limited data.
arXiv Detail & Related papers (2023-09-19T14:39:03Z)
Code Generation for Machine Learning using Model-Driven Engineering and SysML [0.0]
This work aims to facilitate the implementation of data-driven engineering in practice by extending the previous work of formalizing machine learning tasks. The presented method is evaluated for feasibility in a case study to predict weather forecasts. Results demonstrate the flexibility and the simplicity of the method reducing efforts for implementation.
arXiv Detail & Related papers (2023-07-10T15:00:20Z)
Design Automation for Fast, Lightweight, and Effective Deep Learning Models: A Survey [53.258091735278875]
This survey covers studies of design automation techniques for deep learning models targeting edge computing. It offers an overview and comparison of key metrics that are used commonly to quantify the proficiency of models in terms of effectiveness, lightness, and computational costs. The survey proceeds to cover three categories of the state-of-the-art of deep model design automation techniques.
arXiv Detail & Related papers (2022-08-22T12:12:43Z)
Assessing the Quality of Computational Notebooks for a Frictionless Transition from Exploration to Production [1.332560004325655]
Data scientists must transition from the explorative phase of Machine Learning projects to their production phase. To narrow the gap between these two phases, tools and practices adopted by data scientists might be improved by incorporating consolidated software engineering solutions. In my research project, I study the best practices for collaboration with computational notebooks and propose proof-of-concept tools to foster guidelines compliance.
arXiv Detail & Related papers (2022-05-24T10:13:38Z)
Enabling Automated Machine Learning for Model-Driven AI Engineering [60.09869520679979]
We propose a novel approach to enable Model-Driven Software Engineering and Model-Driven AI Engineering. In particular, we support Automated ML, thus assisting software engineers without deep AI knowledge in developing AI-intensive systems.
arXiv Detail & Related papers (2022-03-06T10:12:56Z)
Constructing Neural Network-Based Models for Simulating Dynamical Systems [59.0861954179401]
Data-driven modeling is an alternative paradigm that seeks to learn an approximation of the dynamics of a system using observations of the true system. This paper provides a survey of the different ways to construct models of dynamical systems using neural networks. In addition to the basic overview, we review the related literature and outline the most significant challenges from numerical simulations that this modeling paradigm must overcome.
arXiv Detail & Related papers (2021-11-02T10:51:42Z)
Knowledge as Invariance -- History and Perspectives of Knowledge-augmented Machine Learning [69.99522650448213]
Research in machine learning is at a turning point. Research interests are shifting away from increasing the performance of highly parameterized models to exceedingly specific tasks. This white paper provides an introduction and discussion of this emerging field in machine learning research.
arXiv Detail & Related papers (2020-12-21T15:07:19Z)
Model-Based Deep Learning [155.063817656602]
Signal processing, communications, and control have traditionally relied on classical statistical modeling techniques. Deep neural networks (DNNs) use generic architectures which learn to operate from data, and demonstrate excellent performance. We are interested in hybrid techniques that combine principled mathematical models with data-driven systems to benefit from the advantages of both approaches.
arXiv Detail & Related papers (2020-12-15T16:29:49Z)
Towards CRISP-ML(Q): A Machine Learning Process Model with Quality Assurance Methodology [53.063411515511056]
We propose a process model for the development of machine learning applications. The first phase combines business and data understanding as data availability oftentimes affects the feasibility of the project. The sixth phase covers state-of-the-art approaches for monitoring and maintenance of a machine learning applications.
arXiv Detail & Related papers (2020-03-11T08:25:49Z)

This list is automatically generated from the titles and abstracts of the papers in this site.