Rajgopal Kannan scite author profile

The Graph Convolutional Network (GCN) model and its variants are powerful graph embedding tools for facilitating classification and clustering on graphs. However, a major challenge is to reduce the complexity of layered GCNs and make them parallelizable and scalable on very large graphs -state-of the art techniques are unable to achieve scalability without losing accuracy and efficiency. In this paper, we propose novel parallelization techniques for graph samplingbased GCNs that achieve superior scalable performance on very large graphs without compromising accuracy. Specifically, our GCN guarantees work-efficient training and produces order of magnitude savings in computation and communication. To scale GCN training on tightly-coupled shared memory systems, we develop parallelization strategies for the key steps in training: For the graph sampling step, we exploit parallelism within and across multiple sampling instances, and devise an efficient data structure for concurrent accesses that provides theoretical guarantee of near-linear speedup with number of processing units. For the feature propagation step within the sampled graph, we improve cache utilization and reduce DRAM communication by data partitioning. We prove that our partitioning strategy is a 2approximation for minimizing the communication time compared to the optimal strategy. We demonstrate that our parallel graph embedding outperforms state-of-the-art methods in scalability (with respect to number of processors, graph size and GCN model size), efficiency and accuracy on several large datasets. On a 40-core Xeon platform, our parallel training achieves 64× speedup (with AVX) in the sampling step and 25× speedup in the feature propagation step, compared to the serial implementation, resulting in a net speedup of 21×. Our scalable algorithm enables deeper GCN, as demonstrated by 1306× speedup on a 3-layer GCN compared to Tensorflow implementation of state-of-the-art.

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Novel overlay/underlay cognitive radio waveforms using SD-SMSE framework to enhance spectrum efficiency- part i: theoretical framework and analysis in AWGN channel

Chakravarthy

et al. 2009

IEEE Trans. Commun.

138

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Comparative analysis of quality of service and memory usage for adaptive failure detectors in healthcare systems

Xiong

Vasilakos

Yang

et al. 2009

IEEE J. Select. Areas Commun.

157

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Random asynchronous wakeup protocol for sensor networks

Paruchuri

Basavaraju

Durresi

et al.

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Learning Sparse Feature Representations Using Probabilistic Quadtrees and Deep Belief Nets

Basu

Manohar

Ganguly

et al. 2016

Neural Process Lett

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Learning sparse feature representations is a useful instrument for solving an unsupervised learning problem. In this paper, we present three labeled handwritten digit datasets, collectively called n-MNIST. Then, we propose a novel framework for the classification of handwritten digits that learns sparse representations using probabilistic quadtrees and Deep Belief Nets. On the MNIST and n-MNIST datasets, our framework shows promising results and significantly outperforms traditional Deep Belief Networks.

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Rajgopal Kannan

Accurate, Efficient and Scalable Graph Embedding

Novel overlay/underlay cognitive radio waveforms using SD-SMSE framework to enhance spectrum efficiency- part i: theoretical framework and analysis in AWGN channel

Comparative analysis of quality of service and memory usage for adaptive failure detectors in healthcare systems

Random asynchronous wakeup protocol for sensor networks

Learning Sparse Feature Representations Using Probabilistic Quadtrees and Deep Belief Nets

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