Exploring the Design Space of Deep Convolutional Neural Networks at Large Scale
This addresses the challenge for researchers and practitioners in efficiently finding suitable CNN architectures, though it appears incremental as it builds on existing exploration techniques.
The paper tackles the problem of the vast design space of convolutional neural networks (CNNs) by developing a methodology for systematic exploration, enabling the discovery of optimal architectures for specific applications.
In recent years, the research community has discovered that deep neural networks (DNNs) and convolutional neural networks (CNNs) can yield higher accuracy than all previous solutions to a broad array of machine learning problems. To our knowledge, there is no single CNN/DNN architecture that solves all problems optimally. Instead, the "right" CNN/DNN architecture varies depending on the application at hand. CNN/DNNs comprise an enormous design space. Quantitatively, we find that a small region of the CNN design space contains 30 billion different CNN architectures. In this dissertation, we develop a methodology that enables systematic exploration of the design space of CNNs. Our methodology is comprised of the following four themes. 1. Judiciously choosing benchmarks and metrics. 2. Rapidly training CNN models. 3. Defining and describing the CNN design space. 4. Exploring the design space of CNN architectures. Taken together, these four themes comprise an effective methodology for discovering the "right" CNN architectures to meet the needs of practical applications.