Limitations of Deep Learning for Inverse Problems on Digital Hardware

被引:4
|
作者
Boche, Holger [1 ,2 ,3 ,4 ]
Fono, Adalbert [5 ]
Kutyniok, Gitta [6 ,7 ]
机构
[1] Tech Univ Munich, Inst Theoret Informat Technol, D-80333 Munich, Germany
[2] Ruhr Univ Bochum, BMBF Res Hub 6G Life Excellence Cluster Cyber Secu, D-44801 Bochum, Germany
[3] Munich Ctr Quantum Sci & Technol MCQST, D-80799 Munich, Germany
[4] Munich Quantum Valley MQV, D-80807 Munich, Germany
[5] Ludwig Maximilians Univ Munchen, Dept Math, D-80539 Munich, Germany
[6] Ludwig Maximilians Univ Munchen, Dept Math, D-80539 Munich, Germany
[7] Munich Ctr Machine Learning MCML, D-80538 Munich, Germany
来源
IEEE TRANSACTIONS ON INFORMATION THEORY | 2023年 / 69卷 / 12期
关键词
Neural networks; Computational modeling; Hardware; Inverse problems; Deep learning; Approximation algorithms; Task analysis; Computing theory; deep learning; signal processing; turing machine; THRESHOLDING ALGORITHM; ADVERSARIAL ATTACKS; RECURSIVE FUNCTIONS; NON-COMPUTABILITY; SIGNAL RECOVERY; NEURAL-NETWORKS; SPARSE SIGNALS; RECONSTRUCTION; CIRCUIT;
D O I
10.1109/TIT.2023.3326879
中图分类号
TP [自动化技术、计算机技术];
学科分类号
0812 ;
摘要
Deep neural networks have seen tremendous success over the last years. Since the training is performed on digital hardware, in this paper, we analyze what actually can be computed on current hardware platforms modeled as Turing machines, which would lead to inherent restrictions of deep learning. For this, we focus on the class of inverse problems, which, in particular, encompasses any task to reconstruct data from measurements. We prove that finite-dimensional inverse problems are not Banach-Mazur computable for small relaxation parameters. Even more, our results introduce a lower bound on the accuracy that can be obtained algorithmically.
引用
收藏
页码:7887 / 7908
页数:22
相关论文
共 50 条
  • [41] Hardware for Deep Learning Acceleration
    Song, Choongseok
    Ye, Changmin
    Sim, Yonguk
    Jeong, Doo Seok
    ADVANCED INTELLIGENT SYSTEMS, 2024, 6 (10)
  • [42] PROBLEMS AND LIMITATIONS OF PROGRAMMED LEARNING
    VONCUBE, F
    FOLIA HUMANISTICA, 1970, 8 (90) : 513 - 518
  • [43] Preface for Inverse Problems special issue on learning and inverse problems
    Schonlieb, Carola-Bibiane
    Carlos De los Reyes, Juan
    Haber, Eldad
    INVERSE PROBLEMS, 2017, 33 (07)
  • [44] Deep learning methods for solving linear inverse problems: Research directions and paradigms
    Bai, Yanna
    Chen, Wei
    Chen, Jie
    Guo, Weisi
    SIGNAL PROCESSING, 2020, 177 (177)
  • [45] An Early Fusion Deep Learning Framework for Solving Electromagnetic Inverse Scattering Problems
    Wang, Yan
    Zhao, Yanwen
    Wu, Lifeng
    Yin, Xiaojie
    Zhou, Hongguang
    Hu, Jun
    Nie, Zaiping
    IEEE TRANSACTIONS ON GEOSCIENCE AND REMOTE SENSING, 2023, 61 : 1 - 14
  • [46] Deep Learning for Seismic Inverse Problems: Toward the Acceleration of Geophysical Analysis Workflows
    Adler, Amir
    Araya-Polo, Mauricio
    Poggio, Tomaso
    IEEE SIGNAL PROCESSING MAGAZINE, 2021, 38 (02) : 89 - 119
  • [47] Ambiguity in Solving Imaging Inverse Problems with Deep-Learning-Based Operators
    Evangelista, Davide
    Morotti, Elena
    Piccolomini, Elena Loli
    Nagy, James
    JOURNAL OF IMAGING, 2023, 9 (07)
  • [48] Benchmarking deep learning-based models on nanophotonic inverse design problems
    Taigao Ma
    Mustafa Tobah
    Haozhu Wang
    L.Jay Guo
    Opto-Electronic Science, 2022, 1 (01) : 29 - 43
  • [49] Deep learning-based solvability of underdetermined inverse problems in medical imaging
    Hyun, Chang Min
    Baek, Seong Hyeon
    Lee, Mingyu
    Lee, Sung Min
    Seo, Jin Keun
    MEDICAL IMAGE ANALYSIS, 2021, 69 (69)
  • [50] Near-Exact Recovery for Tomographic Inverse Problems via Deep Learning
    Genzel, Martin
    Guehring, Ingo
    Macdonald, Jan
    Maerz, Maximilian
    INTERNATIONAL CONFERENCE ON MACHINE LEARNING, VOL 162, 2022,
12345