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arxiv 1904.01569 v2 pith:TDY5FZ7Y submitted 2019-04-02 cs.CV cs.LG

Exploring Randomly Wired Neural Networks for Image Recognition

classification cs.CV cs.LG
keywords networksnetworkneuralrandomlywireddesignexploringwiring
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Neural networks for image recognition have evolved through extensive manual design from simple chain-like models to structures with multiple wiring paths. The success of ResNets and DenseNets is due in large part to their innovative wiring plans. Now, neural architecture search (NAS) studies are exploring the joint optimization of wiring and operation types, however, the space of possible wirings is constrained and still driven by manual design despite being searched. In this paper, we explore a more diverse set of connectivity patterns through the lens of randomly wired neural networks. To do this, we first define the concept of a stochastic network generator that encapsulates the entire network generation process. Encapsulation provides a unified view of NAS and randomly wired networks. Then, we use three classical random graph models to generate randomly wired graphs for networks. The results are surprising: several variants of these random generators yield network instances that have competitive accuracy on the ImageNet benchmark. These results suggest that new efforts focusing on designing better network generators may lead to new breakthroughs by exploring less constrained search spaces with more room for novel design.

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Cited by 1 Pith paper

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    cs.LG 2019-07 unverdicted novelty 5.0

    EPNAS uses a progressive search policy with REINFORCE performance prediction to search neural architectures in parallel, supporting multiple resource constraints and outperforming ENAS and PNAS on CIFAR-10 and ImageNe...