Towards Machine-FAIR: Representing software and datasets to facilitate reuse and scientific discovery by machines

IF 4 2区医学 Q2 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS

Journal of Biomedical Informatics Pub Date : 2024-04-30 DOI:10.1016/j.jbi.2024.104647

Michael M. Wagner , William R. Hogan , John D. Levander , Matthew Diller

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引用次数: 0

Abstract

Objective

To use software, datasets, and data formats in the domain of Infectious Disease Epidemiology as a test collection to evaluate a novel M1 use case, which we introduce in this paper. M1 is a machine that upon receipt of a new digital object of research exhaustively finds all valid compositions of it with existing objects.

Method

We implemented a data-format-matching-only M1 using exhaustive search, which we refer to as M1_DFM. We then ran M1_DFM on the test collection and used error analysis to identify needed semantic constraints.

Results

Precision of M1_DFM search was 61.7%. Error analysis identified needed semantic constraints and needed changes in handling of data services. Most semantic constraints were simple, but one data format was sufficiently complex to be practically impossible to represent semantic constraints over, from which we conclude limitatively that software developers will have to meet the machines halfway by engineering software whose inputs are sufficiently simple that their semantic constraints can be represented, akin to the simple APIs of services. We summarize these insights as M1-FAIR guiding principles for composability and suggest a roadmap for progressively capable devices in the service of reuse and accelerated scientific discovery.

Conclusion

Algorithmic search of digital repositories for valid workflow compositions has potential to accelerate scientific discovery but requires a scalable solution to the problem of knowledge acquisition about semantic constraints on software inputs. Additionally, practical limitations on the logical complexity of semantic constraints must be respected, which has implications for the design of software.

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迈向 "机器-公平"：表征软件和数据集，促进机器重用和科学发现

目标使用传染病流行病学领域的软件、数据集和数据格式作为测试集合，评估我们在本文中介绍的新型 M1 用例。M1 是一种机器，在接收到新的数字研究对象时，它能穷举地找到该对象与现有对象的所有有效组合。方法我们使用穷举搜索实现了仅数据格式匹配的 M1，我们称之为 M1DFM。然后，我们在测试集合上运行了 M1DFM，并利用误差分析确定了所需的语义约束。结果M1DFM 搜索的精确度为 61.7%。错误分析确定了所需的语义约束和数据服务处理中需要的更改。大多数语义约束都很简单，但有一种数据格式非常复杂，实际上无法表示语义约束，由此我们得出一个有限的结论，即软件开发人员必须满足机器的一半要求，即工程软件的输入必须足够简单，以便能够表示其语义约束，类似于服务的简单应用程序接口。我们将这些见解总结为可组合性的M1-FAIR指导原则，并提出了逐步提高设备能力的路线图，以服务于重复使用和加速科学发现。结论通过算法搜索数字资源库中的有效工作流组合具有加速科学发现的潜力，但需要一个可扩展的解决方案来解决有关软件输入语义约束的知识获取问题。此外，必须尊重对语义约束逻辑复杂性的实际限制，这对软件设计也有影响。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Biomedical Informatics 医学-计算机：跨学科应用

CiteScore

8.90

自引率

6.70%

发文量

243

审稿时长

32 days

期刊介绍： The Journal of Biomedical Informatics reflects a commitment to high-quality original research papers, reviews, and commentaries in the area of biomedical informatics methodology. Although we publish articles motivated by applications in the biomedical sciences (for example, clinical medicine, health care, population health, and translational bioinformatics), the journal emphasizes reports of new methodologies and techniques that have general applicability and that form the basis for the evolving science of biomedical informatics. Articles on medical devices; evaluations of implemented systems (including clinical trials of information technologies); or papers that provide insight into a biological process, a specific disease, or treatment options would generally be more suitable for publication in other venues. Papers on applications of signal processing and image analysis are often more suitable for biomedical engineering journals or other informatics journals, although we do publish papers that emphasize the information management and knowledge representation/modeling issues that arise in the storage and use of biological signals and images. System descriptions are welcome if they illustrate and substantiate the underlying methodology that is the principal focus of the report and an effort is made to address the generalizability and/or range of application of that methodology. Note also that, given the international nature of JBI, papers that deal with specific languages other than English, or with country-specific health systems or approaches, are acceptable for JBI only if they offer generalizable lessons that are relevant to the broad JBI readership, regardless of their country, language, culture, or health system.