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基于动态指导的深度学习模型稀疏化执行方法()

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《南京师范大学学报》（自然科学版）[ISSN:1001-4616/CN:32-1239/N]

卷:: 第42卷
期数:: 2019年03期

页码:: 11-19

栏目:: ·全国机器学习会议论文专栏·

出版日期:: 2019-09-30

文章信息/Info

Title:: Dynamic Sparse Method for Deep Learning Execution

文章编号:: 1001-4616(2019)03-0011-09

作者:: 孙茹君; 张鲁飞; 数学工程与先进计算国家重点实验室,江苏无锡 214125

Author(s):: Sun Rujun; Zhang Lufei; State Key Laboratory of Mathematical Engineering and Advanced Computing,Wuxi 214125,China

关键词:: 深度学习; 稀疏化方法; 资源受限; 动态调度

Keywords:: deep learning; sparse method; resource limitation; dynamic scheduling

分类号:: TP311

DOI:: 10.3969/j.issn.1001-4616.2019.03.002

文献标志码:: A

摘要:: 以深度学习为代表的人工智能技术迅速发展,庞大的数据、模型,更大的计算量和更复杂的计算都对模型的执行提出了挑战. 在实际应用中,资源和应用的动态特征以及用户的动态需求,需要模型执行的动态性来保证. 而稀疏化是在资源受限、用户需求调整情况下动态模型的执行重要手段. 目前主流的稀疏化技术主要是针对特定问题的稀疏化,且针对推理的多,针对训练的少,缺乏在训练执行阶段进行动态调整和稀疏化的手段. 本文在对深度学习领域的基本计算单元进行可稀疏性分析的基础上,进一步分析了模型执行的不同层面、不同组成部分的稀疏化能力; 经过对动态需求、模型稀疏化策略的建模后,提出了基于动态指导的深度学习模型稀疏化执行方法,并进行了基本实验; 最后从量化建模与量化实验的角度对今后的研究工作提出了展望.

Abstract:: Artificial intelligence,especially deep learning,is developing rapidly. Large data,large models,complex control flow,and more computations have challenged model execution in both training and inference stage. Practically,resources and user demands show dynamic characteristics,and need to be guaranteed by executing model dynamically. Finding sparsity is an important means of dynamically model execution under resource constraints and the changing user demand. At present,the main sparse method is focused on specific problems. Most of them are used in inference. We are in urgent need of dynamic sparse method in training. In this paper,we firstly analyzed the chance of sparsicy in basic deep learning models and further analyzed the sparseization ability of different layers and different components of models. After modeling the dynamic requirements and sparseness strategy,we proposed a sparse execution method of deep learning based on dynamic execution,and did some basic experiments. Finally,from the perspective of quantitative modeling and quantitative experiments,the future research work is prospected.

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备注/Memo

备注/Memo:: 收稿日期:2019-07-05.基金项目:国家重点研发计划(2016YFB1000505)、国家重点研发计划(2017YFB0202001)、国家自然科学基金项目(9143020017). 通讯联系人:孙茹君,博士研究生,研究方向:人工智能运行环境. E-mail:sun.rujun@meac-skl.cn

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更新日期/Last Update: 2019-09-30