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Technology readiness levels for machine learning systems

Author

Listed:
  • Alexander Lavin

    (Pasteur Labs & ISI
    NASA Frontier Development Lab)

  • Ciarán M. Gilligan-Lee

    (Spotify
    University College London)

  • Alessya Visnjic

    (WhyLabs)

  • Siddha Ganju

    (NASA Frontier Development Lab
    Nvidia)

  • Dava Newman

    (Massachusetts Institute of Technology)

  • Sujoy Ganguly

    (Unity AI)

  • Danny Lange

    (Unity AI)

  • Atílím Güneş Baydin

    (University of Oxford)

  • Amit Sharma

    (Microsoft Research)

  • Adam Gibson

    (Konduit)

  • Stephan Zheng

    (Salesforce Research)

  • Eric P. Xing

    (Petuum
    Carnegie Mellon University)

  • Chris Mattmann

    (NASA Jet Propulsion Lab)

  • James Parr

    (NASA Frontier Development Lab)

  • Yarin Gal

    (Alan Turing Institute)

Abstract

The development and deployment of machine learning systems can be executed easily with modern tools, but the process is typically rushed and means-to-an-end. Lack of diligence can lead to technical debt, scope creep and misaligned objectives, model misuse and failures, and expensive consequences. Engineering systems, on the other hand, follow well-defined processes and testing standards to streamline development for high-quality, reliable results. The extreme is spacecraft systems, with mission critical measures and robustness throughout the process. Drawing on experience in both spacecraft engineering and machine learning (research through product across domain areas), we’ve developed a proven systems engineering approach for machine learning and artificial intelligence: the Machine Learning Technology Readiness Levels framework defines a principled process to ensure robust, reliable, and responsible systems while being streamlined for machine learning workflows, including key distinctions from traditional software engineering, and a lingua franca for people across teams and organizations to work collaboratively on machine learning and artificial intelligence technologies. Here we describe the framework and elucidate with use-cases from physics research to computer vision apps to medical diagnostics.

Suggested Citation

  • Alexander Lavin & Ciarán M. Gilligan-Lee & Alessya Visnjic & Siddha Ganju & Dava Newman & Sujoy Ganguly & Danny Lange & Atílím Güneş Baydin & Amit Sharma & Adam Gibson & Stephan Zheng & Eric P. Xing &, 2022. "Technology readiness levels for machine learning systems," Nature Communications, Nature, vol. 13(1), pages 1-19, December.
    • Handle: RePEc:nat:natcom:v:13:y:2022:i:1:d:10.1038_s41467-022-33128-9
    DOI: 10.1038/s41467-022-33128-9
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    References listed on IDEAS

    as
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    2. Jonathan G. Richens & Ciarán M. Lee & Saurabh Johri, 2020. "Publisher Correction: Improving the accuracy of medical diagnosis with causal machine learning," Nature Communications, Nature, vol. 11(1), pages 1-1, December.
    3. Dean Eckles & Eytan Bakshy, 2021. "Bias and High-Dimensional Adjustment in Observational Studies of Peer Effects," Journal of the American Statistical Association, Taylor & Francis Journals, vol. 116(534), pages 507-517, April.
    4. Jonathan G. Richens & Ciarán M. Lee & Saurabh Johri, 2020. "Improving the accuracy of medical diagnosis with causal machine learning," Nature Communications, Nature, vol. 11(1), pages 1-9, December.
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