Model Inference from Electrospray Thruster Array Tests

In trained deep neural networks, unstructured pruning can reduce redundant weights to lower storage cost. However, it requires the customization of hardwares to speed up practical inference. Another trend accelerates sparse model inference on general-purpose hardwares by adopting coarse-grained sparsity to prune or regularize consecutive weights for efficient computation. But this method often sacrifices model accuracy. In this paper, we propose a novel fine-grained sparsity approach, Balanced Sparsity, to achieve high model accuracy with commercial hardwares efficiently. Our approach adapts to high parallelism property of GPU, showing incredible potential for sparsity in the widely deployment of deep learning services. Experiment results show that Balanced Sparsity achieves up to 3.1x practical speedup for model inference on GPU, while retains the same high model accuracy as finegrained sparsity.

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Exploit Camera Raw Data for Video Super- Resolution via Hidden Markov Model Inference

IEEE Transactions on Image Processing ◽

10.1109/tip.2021.3049974 ◽

2021 ◽

Vol 30 ◽

pp. 2127-2140

Author(s):

Xiaohong Liu ◽

Kangdi Shi ◽

Zhe Wang ◽

Jun Chen

Keyword(s):

Markov Model ◽

Hidden Markov Model ◽

Hidden Markov ◽

Super Resolution ◽

Raw Data ◽

Model Inference

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Multi-model inference of network properties from incomplete data

Journal of Integrative Bioinformatics ◽

10.1515/jib-2006-32 ◽

2006 ◽

Vol 3 (2) ◽

pp. 123-136 ◽

Cited By ~ 3

Author(s):

Michael P. H. Stumpf ◽

Thomas Thorne

Keyword(s):

Network Models ◽

Network Data ◽

Global Networks ◽

New Approach ◽

Model Inference ◽

Novel Approach ◽

Eukaryotic Species ◽

Network Properties ◽

Experimental Approaches ◽

Saccaromyces Cerevisiae

Summary It has previously been shown that subnets differ from global networks from which they are sampled for all but a very limited number of theoretical network models. These differences are of qualitative as well as quantitative nature, and the properties of subnets may be very different from the corresponding properties in the true, unobserved network. Here we propose a novel approach which allows us to infer aspects of the true network from incomplete network data in a multi-model inference framework. We develop the basic theoretical framework, including procedures for assessing confidence intervals of our estimates and evaluate the performance of this approach in simulation studies and against subnets drawn from the presently available PIN network data in Saccaromyces cerevisiae. We then illustrate the potential power of this new approach by estimating the number of interactions that will be detectable with present experimental approaches in sfour eukaryotic species, inlcuding humans. Encouragingly, where independent datasets are available we obtain consistent estimates from different partial protein interaction networks. We conclude with a discussion of the scope of this approaches and areas for further research

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