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Robust Neural Architecture Search Under Adversarial Training: Benchmark, Theory, and Insights


Konsep Inti
Addressing the challenges of robust architectures in NAS through benchmarking and theoretical insights.
Abstrak

1. Introduction

  • Importance of expert-designed architectures in deep learning.
  • Evolution of Neural Architecture Search (NAS) to automate network discovery.
  • Need for robust architectures due to vulnerability to adversarial attacks.

2. Challenges in Robust NAS

  • Lack of benchmark evaluations under adversarial training.
  • Theoretical guarantees for architectures under adversarial training are unclear.

3. Contributions and Insights

  • Release of NAS-RobBench-201 for evaluating robust architectures.
  • Comprehensive assessment of the benchmark performance.
  • Theoretical framework for analyzing architecture search under multi-objective settings.

4. Benchmark Construction

  • Search space based on NAS-Bench-201 with 6 edges and 5 operators.
  • Evaluation on CIFAR-10/100 and ImageNet-16 datasets under adversarial training.

5. Statistics of the Benchmark

  • Boxplots showing clean accuracy and robust accuracy distribution.
  • Impact of operator selection on architecture design.
  • Architecture ranking consistency across different datasets.

6. Generalization Guarantees Under NAS

  • Theoretical analysis using NTK-based methods for FCNNs and CNNs.

7. Correlation Between NTK and Accuracy

  • Spearman correlation between NTK scores and various metrics.

8. Conclusion

  • Release of NAS-RobBench-201 for robust architecture evaluation.
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Statistik
107k GPU hours required to build the benchmark on three datasets (CIFAR-10/100, ImageNet). 6466 unrepeated network architectures evaluated under adversarial training.
Kutipan
"We release a comprehensive dataset encompassing clean accuracy and robust accuracy." "Our theory provides a solid foundation for designing robust NAS algorithms."

Wawasan Utama Disaring Dari

by Yongtao Wu,F... pada arxiv.org 03-21-2024

https://arxiv.org/pdf/2403.13134.pdf
Robust NAS under adversarial training

Pertanyaan yang Lebih Dalam

How can the findings from this research impact the development of future neural architecture search algorithms

The findings from this research can significantly impact the development of future neural architecture search (NAS) algorithms in several ways: Robust Architecture Design: The benchmark NAS-RobBench-201 provides a comprehensive evaluation of robust architectures under adversarial training, enabling researchers to identify architectures that exhibit high performance and robustness against malicious data. Future NAS algorithms can leverage this benchmark to prioritize the search for architectures with improved robustness. Theoretical Foundation: The theoretical insights provided in the research offer a solid foundation for designing robust NAS algorithms. By understanding how various Neural Tangent Kernels (NTKs) affect the generalization and performance of neural networks, researchers can develop more effective optimization strategies and regularization techniques in NAS. Algorithm Performance: By studying the correlation between NTK scores and accuracy metrics on NAS-RobBench-201, researchers can optimize their NAS algorithms to prioritize architectures that align with favorable NTK characteristics associated with better performance and generalization. Transfer Learning: The benchmark's evaluation across multiple datasets highlights transferable architectures that perform consistently well across different tasks, motivating future research towards developing transferable NAS approaches for diverse applications. Overall, these findings provide valuable insights into building more efficient, reliable, and robust neural architecture search algorithms.

What counterarguments exist against the use of NTK-based methods for generalization guarantees in deep learning

While NTK-based methods offer valuable insights into understanding the generalization properties of deep learning models like FCNNs and CNNs, there are some counterarguments against their use for generalization guarantees: Limited Real-world Applicability: Critics argue that NTK-based analyses often operate in a simplified linear regime that may not fully capture the complexities of real-world non-linear deep learning systems. As such, extrapolating results from NTK analysis to practical scenarios may lead to inaccuracies or oversights. Overfitting Concerns: Some experts raise concerns about potential overfitting when relying solely on NTK-based analyses for model optimization or architectural decisions without considering broader factors influencing model performance outside the linear approximation context. Scalability Challenges: Scaling up NTK calculations to larger models or complex network structures could pose computational challenges due to increased memory requirements and processing time constraints.

How might the environmental impact of large-scale computational efforts like this be mitigated in future research endeavors

Mitigating the environmental impact of large-scale computational efforts like those seen in this research endeavor can be approached through several strategies: Energy-Efficient Computing: Researchers can explore energy-efficient computing solutions such as optimizing code efficiency, utilizing specialized hardware accelerators like GPUs or TPUs designed for machine learning workloads, or leveraging cloud services with green computing initiatives. Resource Sharing: Collaborative efforts within research communities could involve resource sharing agreements where computational resources are pooled together efficiently rather than duplicating efforts across individual projects. Carbon Offsetting: Research institutions could consider carbon offset programs where they invest in environmentally friendly projects to compensate for carbon emissions generated during extensive computational tasks like training neural networks on large datasets. 4 .Optimized Workflows: Implementing optimized workflows by reducing redundant computations through parallel processing techniques or algorithmic improvements can help minimize energy consumption while maintaining research productivity. By implementing these measures alongside responsible computing practices, researchers can reduce the environmental footprint associated with large-scale computational experiments while advancing scientific progress effectively.
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