Literature on Neural Architecture Search

1301.

Chitty-Venkata, Krishna Teja; Somani, Arun K.

Array-Aware Neural Architecture Search Inproceedings

In: 2021 IEEE 32nd International Conference on Application-specific Systems, Architectures and Processors (ASAP), pp. 125-132, 2021.

1300.

Boutros, Fadi; Siebke, Patrick; Klemt, Marcel; Damer, Naser; Kirchbuchner, Florian; Kuijper, Arjan

PocketNet: Extreme Lightweight Face Recognition Network using Neural Architecture Search and Multi-Step Knowledge Distillation Technical Report

, 2021.

EMONAS-Net: Efficient multiobjective neural architecture search using surrogate-assisted evolutionary algorithm for 3D medical image segmentation Journal Article

1299.

Calisto, Maria Baldeon; Lai-Yuen, Susana K.

In: Artificial Intelligence in Medicine, 119 , pp. 102154, 2021, ISSN: 0933-3657.

@article{BALDEONCALISTO2021102154,

title = {EMONAS-Net: Efficient multiobjective neural architecture search using surrogate-assisted evolutionary algorithm for 3D medical image segmentation},

author = {Maria Baldeon Calisto and Susana K. Lai-Yuen},

url = {https://www.sciencedirect.com/science/article/pii/S0933365721001470},

doi = {https://doi.org/10.1016/j.artmed.2021.102154},

issn = {0933-3657},

year  = {2021},

date = {2021-01-01},

urldate = {2021-01-01},

journal = {Artificial Intelligence in Medicine},

volume = {119},

pages = {102154},

abstract = {Deep learning plays a critical role in medical image segmentation. Nevertheless, manually designing a neural network for a specific segmentation problem is a very difficult and time-consuming task due to the massive hyperparameter search space, long training time and large volumetric data. Therefore, most designed networks are highly complex, task specific and over-parametrized. Recently, multiobjective neural architecture search (NAS) methods have been proposed to automate the design of accurate and efficient segmentation architectures. However, they only search for either the micro- or macro-structure of the architecture, do not use the information produced during the optimization process to increase the efficiency of the search, or do not consider the volumetric nature of medical images. In this work, we present EMONAS-Net, an Efficient MultiObjective NAS framework for 3D medical image segmentation that optimizes both the segmentation accuracy and size of the network. EMONAS-Net has two key components, a novel search space that considers the configuration of the micro- and macro-structure of the architecture and a Surrogate-assisted Multiobjective Evolutionary based Algorithm (SaMEA algorithm) that efficiently searches for the best hyperparameter values. The SaMEA algorithm uses the information collected during the initial generations of the evolutionary process to identify the most promising subproblems and select the best performing hyperparameter values during mutation to improve the convergence speed. Furthermore, a Random Forest surrogate model is incorporated to accelerate the fitness evaluation of the candidate architectures. EMONAS-Net is tested on the tasks of prostate segmentation from the MICCAI PROMISE12 challenge, hippocampus segmentation from the Medical Segmentation Decathlon challenge, and cardiac segmentation from the MICCAI ACDC challenge. In all the benchmarks, the proposed framework finds architectures that perform better or comparable with competing state-of-the-art NAS methods while being considerably smaller and reducing the architecture search time by more than 50%.},

keywords = {},

pubstate = {published},

tppubtype = {article}

}

Deep learning plays a critical role in medical image segmentation. Nevertheless, manually designing a neural network for a specific segmentation problem is a very difficult and time-consuming task due to the massive hyperparameter search space, long training time and large volumetric data. Therefore, most designed networks are highly complex, task specific and over-parametrized. Recently, multiobjective neural architecture search (NAS) methods have been proposed to automate the design of accurate and efficient segmentation architectures. However, they only search for either the micro- or macro-structure of the architecture, do not use the information produced during the optimization process to increase the efficiency of the search, or do not consider the volumetric nature of medical images. In this work, we present EMONAS-Net, an Efficient MultiObjective NAS framework for 3D medical image segmentation that optimizes both the segmentation accuracy and size of the network. EMONAS-Net has two key components, a novel search space that considers the configuration of the micro- and macro-structure of the architecture and a Surrogate-assisted Multiobjective Evolutionary based Algorithm (SaMEA algorithm) that efficiently searches for the best hyperparameter values. The SaMEA algorithm uses the information collected during the initial generations of the evolutionary process to identify the most promising subproblems and select the best performing hyperparameter values during mutation to improve the convergence speed. Furthermore, a Random Forest surrogate model is incorporated to accelerate the fitness evaluation of the candidate architectures. EMONAS-Net is tested on the tasks of prostate segmentation from the MICCAI PROMISE12 challenge, hippocampus segmentation from the Medical Segmentation Decathlon challenge, and cardiac segmentation from the MICCAI ACDC challenge. In all the benchmarks, the proposed framework finds architectures that perform better or comparable with competing state-of-the-art NAS methods while being considerably smaller and reducing the architecture search time by more than 50%.

1298.

Peng, Jiefeng; Zhang, Jiqi; Li, Changlin; Wang, Guangrun; Liang, Xiaodan; Lin, Liang

Pi-NAS: Improving Neural Architecture Search by Reducing Supernet Training Consistency Shift Technical Report

, 2021.

1297.

Fan, Yi; Zhou, Quoqiang; Zhang, Weifeng; Bao, Shudi; Shen, Jun

Determining learning direction via multi-controller model for stably searching generative adversarial networks Journal Article

In: Neurocomputing, 464 , pp. 37-47, 2021, ISSN: 0925-2312.

1296.

Hou, Pengfei; Jin, Ying; Chen, Yukang

Single-DARTS: Towards Stable Architecture Search Technical Report

, 2021.

1295.

Wang, Ruochen; Chen, Xiangning; Cheng, Minhao; Tang, Xiaocheng; Hsieh, Cho-Jui

RANK-NOSH: Efficient Predictor-Based Architecture Search via Non-Uniform Successive Halving Technical Report

, 2021.

1294.

Ganepola, Vayangi Vishmi Vishara; Wirasingha, Torin

Generative Adversarial Networks Using Neural Architecture Search for Semantic Image Segmentation Inproceedings

In: 2021 IEEE 4th International Conference on Big Data and Artificial Intelligence (BDAI), pp. 236-241, 2021.

1293.

Kim, Youngkee; Yun, Won Joon; Lee, Youn Kyu; Jung, Soyi; Kim, Joongheon

Trends in Neural Architecture Search: Towards the Acceleration of Search Technical Report

, 2021.

1292.

Liu, Chia-Hsiang; Han, Yu-Shin; Sung, Yuan-Yao; Lee, Yi; Chiang, Hung-Yueh; Wu, Kai-Chiang

FOX-NAS: Fast, On-device and Explainable Neural Architecture Search Technical Report

, 2021.

1291.

Lyu, Bo; Yang, Yin; Wen, Shiping; Huang, Tingwen; Li, Ke

Neural Architecture Search for Portrait Parsing Journal Article

In: IEEE Transactions on Neural Networks and Learning Systems, pp. 1-10, 2021.

1290.

Zhao, Pengyu; Xiao, Kecheng; Zhang, Yuanxing; Bian, Kaigui; Yan, Wei

AMEIR: Automatic Behavior Modeling, Interaction Exploration and MLP Investigation in the Recommender System Inproceedings

In: Zhou, Zhi-Hua (Ed.): Proceedings of the Thirtieth International Joint Conference on Artificial Intelligence, IJCAI 2021, Virtual Event / Montreal, Canada, 19-27 August 2021, pp. 2104–2110, ijcai.org, 2021.

1289.

Tang, Sheyang; Hosseini, Mahdi S.; Chen, Lina; Varma, Sonal; Rowsell, Corwyn; Damaskinos, Savvas; Plataniotis, Konstantinos N.; Wang, Zhou

Probeable DARTS with Application to Computational Pathology Technical Report

, 2021.

1288.

Zhao, Changsheng; Hua, Ting; Shen, Yilin; Lou, Qian; Jin, Hongxia

Automatic Mixed-Precision Quantization Search of BERT Inproceedings

In: Zhou, Zhi-Hua (Ed.): Proceedings of the Thirtieth International Joint Conference on Artificial Intelligence, IJCAI 2021, Virtual Event / Montreal, Canada, 19-27 August 2021, pp. 3427–3433, ijcai.org, 2021.

1287.

Hosseini, Mahdi S.; Zhang, Jia Shu; Liu, Zhe; Fu, Andre; Su, Jingxuan; Tuli, Mathieu; Plataniotis, Konstantinos N.

CONet: Channel Optimization for Convolutional Neural Networks Technical Report

, 2021.

1286.

Li, Yanxi; Yang, Zhaohui; Wang, Yunhe; Xu, Chang

Neural Architecture Dilation for Adversarial Robustness Technical Report

, 2021.

1285.

Benmeziane, Hadjer; Maghraoui, Kaoutar El; Ouarnoughi, Hamza; Niar, Smaïl; Wistuba, Martin; Wang, Naigang

Hardware-Aware Neural Architecture Search: Survey and Taxonomy Inproceedings

In: Zhou, Zhi-Hua (Ed.): Proceedings of the Thirtieth International Joint Conference on Artificial Intelligence, IJCAI 2021, Virtual Event / Montreal, Canada, 19-27 August 2021, pp. 4322–4329, ijcai.org, 2021.

1284.

Chen, Boyu; Li, Peixia; Li, Baopu; Lin, Chen; Li, Chuming; Sun, Ming; Yan, Junjie; Ouyang, Wanli

BN-NAS: Neural Architecture Search with Batch Normalization Technical Report

, 2021.

1283.

Razali, Mohd Norhisham; Moung, Ervin Gubin; Yahya, Farashazillah; Hou, Chong Joon; Hanapi, Rozita; Mohamed, Raihani; Hashem, Ibrahim Abakr Targio

Indigenous Food Recognition Model Based on Various Convolutional Neural Network Architectures for Gastronomic Tourism Business Analytics Journal Article

In: Inf., 12 (8), pp. 322, 2021.

1282.

Geiping, Jonas; Lukasik, Jovita; Keuper, Margret; Moeller, Michael

DARTS for Inverse Problems: a Study on Hyperparameter Sensitivity Journal Article

In: CoRR, abs/2108.05647 , 2021.

1281.

Wang, Xin; Zhu, Wenwu

Automated Machine Learning on Graph Inproceedings

In: Proceedings of the 27th ACM SIGKDD Conference on Knowledge Discovery & Data Mining, pp. 4082–4083, Association for Computing Machinery, Virtual Event, Singapore, 2021, ISBN: 9781450383325.

Random Topology and Random Multiscale Mapping: An Automated Design of Multiscale and Lightweight Neural Network for Remote-Sensing Image Recognition Journal Article

1280.

Li, Jihao; Weinmann, Martin; Sun, Xian; Diao, Wenhui; Feng, Yingchao; Fu, Kun

In: IEEE Transactions on Geoscience and Remote Sensing, pp. 1-17, 2021.

1279.

Ding, Yuhui; Yao, Quanming; Zhao, Huan; Zhang, Tong

DiffMG: Differentiable Meta Graph Search for Heterogeneous Graph Neural Networks Inproceedings

In: Proceedings of the 27th ACM SIGKDD Conference on Knowledge Discovery & Data Mining, pp. 279–288, Association for Computing Machinery, Virtual Event, Singapore, 2021, ISBN: 9781450383325.

@inproceedings{10.1145/3447548.3467447,

title = {DiffMG: Differentiable Meta Graph Search for Heterogeneous Graph Neural Networks},

author = {Yuhui Ding and Quanming Yao and Huan Zhao and Tong Zhang},

url = {https://doi.org/10.1145/3447548.3467447},

doi = {10.1145/3447548.3467447},

isbn = {9781450383325},

year  = {2021},

date = {2021-01-01},

urldate = {2021-01-01},

booktitle = {Proceedings of the 27th ACM SIGKDD Conference on Knowledge Discovery & Data Mining},

pages = {279–288},

publisher = {Association for Computing Machinery},

address = {Virtual Event, Singapore},

series = {KDD '21},

abstract = {In this paper, we propose a novel framework to automatically utilize task-dependent 

semantic information which is encoded in heterogeneous information networks (HINs). 

Specifically, we search for a meta graph, which can capture more complex semantic 

relations than a meta path, to determine how graph neural networks (GNNs) propagate 

messages along different types of edges. We formalize the problem within the framework 

of neural architecture search (NAS) and then perform the search in a differentiable 

manner. We design an expressive search space in the form of a directed acyclic graph 

(DAG) to represent candidate meta graphs for a HIN, and we propose task-dependent 

type constraint to filter out those edge types along which message passing has no 

effect on the representations of nodes that are related to the downstream task. The 

size of the search space we define is huge, so we further propose a novel and efficient 

search algorithm to make the total search cost on a par with training a single GNN 

once. Compared with existing popular NAS algorithms, our proposed search algorithm 

improves the search efficiency. We conduct extensive experiments on different HINs 

and downstream tasks to evaluate our method, and experimental results show that our 

method can outperform state-of-the-art heterogeneous GNNs and also improves efficiency 

compared with those methods which can implicitly learn meta paths.},

keywords = {},

pubstate = {published},

tppubtype = {inproceedings}

}

1278.

Shim, Jae-hun; Kang, Suk-ju

Neural Architecture Search for Light-weight Multi-touch Classification Inproceedings

In: 2021 36th International Technical Conference on Circuits/Systems, Computers and Communications (ITC-CSCC), pp. 1-3, 2021.

1277.

Xu, Hang; Kang, Ning; Zhang, Gengwei; Xie, Chuanlong; Liang, Xiaodan; Li, Zhenguo

NASOA: Towards Faster Task-oriented Online Fine-tuning with a Zoo of Models Technical Report

, 2021.

1276.

Vieira, Carlos; Cáceres, Leslie Pérez; Bezerra, Leonardo C T

Evaluating Anytime Performance on NAS-Bench-101 Inproceedings

In: 2021 IEEE Congress on Evolutionary Computation (CEC), pp. 1249-1256, 2021.

1275.

Andersen, Hayden; Stevenson, Sean; Ha, Tuan; Gao, Xiaoying; Xue, Bing

Evolving Neural Networks for Text Classification using Genetic Algorithm-based Approaches Inproceedings

In: 2021 IEEE Congress on Evolutionary Computation (CEC), pp. 1241-1248, 2021.

1274.

Huang, Junhao; Xue, Bing; Sun, Yanan; Zhang, Mengjie

A Flexible Variable-length Particle Swarm Optimization Approach to Convolutional Neural Network Architecture Design Inproceedings

In: 2021 IEEE Congress on Evolutionary Computation (CEC), pp. 934-941, 2021.

1273.

Zhang, Yuge; Yan, Chenqian; Zhang, Quanlu; Zhang, Li Lyna; Yang, Yaming; Gao, Xiaotian; Yang, Yuqing

AceNAS: Learning to Rank Ace Neural Architectures with Weak Supervision of Weight Sharing Technical Report

, 2021.

1272.

Zhao, Liang; Fang, Wei

An Efficient and Flexible Automatic Search Algorithm for Convolution Network Architectures Inproceedings

In: 2021 IEEE Congress on Evolutionary Computation (CEC), pp. 2203-2210, 2021.

1271.

Namekawa, Shizuma; Tezuka, Taro

Evolutionary Neural Architecture Search by Mutual Information Analysis Inproceedings

In: 2021 IEEE Congress on Evolutionary Computation (CEC), pp. 966-972, 2021.

1270.

Cai, Ronghong; Luo, Jianping

Multi-Task Learning for Multi-Objective Evolutionary Neural Architecture Search Inproceedings

In: 2021 IEEE Congress on Evolutionary Computation (CEC), pp. 1680-1687, 2021.

1269.

Shi, Rui; Luo, Jianping; Liu, Qiqi

Fast Evolutionary Neural Architecture Search Based on Bayesian Surrogate Model Inproceedings

In: 2021 IEEE Congress on Evolutionary Computation (CEC), pp. 1217-1224, 2021.

1268.

Zhou, Xun; Qin, A K; Sun, Yanan; Tan, Kay Chen

A Survey of Advances in Evolutionary Neural Architecture Search Inproceedings

In: 2021 IEEE Congress on Evolutionary Computation (CEC), pp. 950-957, 2021.

1267.

Xie, Xiangning; Liu, Yuqiao; Sun, Yanan; Yen, Gary G; Xue, Bing; Zhang, Mengjie

BenchENAS: A Benchmarking Platform for Evolutionary Neural Architecture Search Technical Report

, 2021.

1266.

Yang, Shangshang; Tian, Ye; Xiang, Xiaoshu; Peng, Shichen; Zhang, Xingyi

Accelerating Evolutionary Neural Architecture Search via Multi-Fidelity Evaluation Technical Report

, 2021.

1265.

Repin, Denis; Petrov, Tatjana

Automated Deep Abstractions for Stochastic Chemical Reaction Networks Journal Article

In: Information and Computation, pp. 104788, 2021, ISSN: 0890-5401.

@article{REPIN2021104788,

title = {Automated Deep Abstractions for Stochastic Chemical Reaction Networks},

author = {Denis Repin and Tatjana Petrov},

url = {https://www.sciencedirect.com/science/article/pii/S0890540121001048},

doi = {https://doi.org/10.1016/j.ic.2021.104788},

issn = {0890-5401},

year  = {2021},

date = {2021-01-01},

journal = {Information and Computation},

pages = {104788},

abstract = {Predicting stochastic cellular dynamics as emerging from the mechanistic models of molecular interactions is a long-standing challenge in systems biology: low-level chemical reaction network (CRN) models give rise to a highly-dimensional continuous-time Markov chain (CTMC) which is computationally demanding and often prohibitive to analyse in practice. A recently proposed abstraction method uses deep learning to replace this CTMC with a discrete-time continuous-space process, by training a mixture density deep neural network with traces sampled at regular time intervals (which can be obtained either by simulating a given CRN or as time-series data from experiment). The major advantage of such abstraction is that it produces a computational model that is dramatically cheaper to execute, while it preserves the statistical features of the training data. In general, the abstraction accuracy improves with the amount of training data. However, depending on the CRN, the overall quality of the method – the efficiency gain and abstraction accuracy – will also depend on the choice of neural network architecture given by hyper-parameters such as the layer types and connections between them. As a consequence, in practice, the modeller has to take care of finding the suitable architecture manually, for each given CRN, through a tedious and time-consuming trial-and-error cycle. In this paper, we propose to further automatise deep abstractions for stochastic CRNs, through learning the neural network architecture along with learning the transition kernel of the abstract process. Automated search of the architecture makes the method applicable directly to any given CRN, which is time-saving for deep learning experts and crucial for non-specialists. We implement the method and demonstrate its performance on a number of representative CRNs with multi-modal emergent phenotypes. Moreover, we showcase that deep abstractions can be used for efficient multi-scale simulations, which are otherwise computationally intractable. To this end, we define a scenario where multiple CRN instances interact across a spatial grid via shared species. Finally, we discuss the limitations and challenges arising when using deep abstractions.},

keywords = {},

pubstate = {published},

tppubtype = {article}

}

Predicting stochastic cellular dynamics as emerging from the mechanistic models of molecular interactions is a long-standing challenge in systems biology: low-level chemical reaction network (CRN) models give rise to a highly-dimensional continuous-time Markov chain (CTMC) which is computationally demanding and often prohibitive to analyse in practice. A recently proposed abstraction method uses deep learning to replace this CTMC with a discrete-time continuous-space process, by training a mixture density deep neural network with traces sampled at regular time intervals (which can be obtained either by simulating a given CRN or as time-series data from experiment). The major advantage of such abstraction is that it produces a computational model that is dramatically cheaper to execute, while it preserves the statistical features of the training data. In general, the abstraction accuracy improves with the amount of training data. However, depending on the CRN, the overall quality of the method – the efficiency gain and abstraction accuracy – will also depend on the choice of neural network architecture given by hyper-parameters such as the layer types and connections between them. As a consequence, in practice, the modeller has to take care of finding the suitable architecture manually, for each given CRN, through a tedious and time-consuming trial-and-error cycle. In this paper, we propose to further automatise deep abstractions for stochastic CRNs, through learning the neural network architecture along with learning the transition kernel of the abstract process. Automated search of the architecture makes the method applicable directly to any given CRN, which is time-saving for deep learning experts and crucial for non-specialists. We implement the method and demonstrate its performance on a number of representative CRNs with multi-modal emergent phenotypes. Moreover, we showcase that deep abstractions can be used for efficient multi-scale simulations, which are otherwise computationally intractable. To this end, we define a scenario where multiple CRN instances interact across a spatial grid via shared species. Finally, we discuss the limitations and challenges arising when using deep abstractions.

1264.

Zhang, Yongan; Fu, Yonggan; Jiang, Weiwen; Li, Chaojian; You, Haoran; Li, Meng; Chandra, Vikas; Lin, Yingyan

DIAN: Differentiable Accelerator-Network Co-Search Towards Maximal DNN Efficiency Inproceedings

In: 2021 IEEE/ACM International Symposium on Low Power Electronics and Design (ISLPED), pp. 1-6, 2021.

1263.

Li, Yuhong; Hao, Cong; Li, Pan; Xiong, Jinjun; Chen, Deming

Generic Neural Architecture Search via Regression Technical Report

, 2021.

1262.

Odema, Mohanad; Rashid, Nafiul; Faruque, Mohammad Abdullah Al

EExNAS: Early-Exit Neural Architecture Search Solutions for Low-Power Wearable Devices Inproceedings

In: 2021 IEEE/ACM International Symposium on Low Power Electronics and Design (ISLPED), pp. 1-6, 2021.

1261.

Li, Qing; Zhang, Wei; Zhao, Lin; Wu, Xia; Liu, Tianming

Evolutional Neural Architecture Search for Optimization of Spatiotemporal Brain Network Decomposition Journal Article

In: IEEE Transactions on Biomedical Engineering, pp. 1-1, 2021.

1260.

He, Xiaoyu; Wang, Yong; Wang, Xiaojing; Huang, Weihong; Zhao, Shuang; Chen, Xiang

Simple-Encoded Evolving Convolutional Neural Networks and Its Application to Skin Disease Image Classification Journal Article

In: Swarm and Evolutionary Computation, pp. 100955, 2021, ISSN: 2210-6502.

@article{HE2021100955,

title = {Simple-Encoded Evolving Convolutional Neural Networks and Its Application to Skin Disease Image Classification},

author = {Xiaoyu He and Yong Wang and Xiaojing Wang and Weihong Huang and Shuang Zhao and Xiang Chen},

url = {https://www.sciencedirect.com/science/article/pii/S2210650221001176},

doi = {https://doi.org/10.1016/j.swevo.2021.100955},

issn = {2210-6502},

year  = {2021},

date = {2021-01-01},

journal = {Swarm and Evolutionary Computation},

pages = {100955},

abstract = {Automatically searched architectures by neural architecture search (NAS) methods have shown promising performance in various visual recognition tasks. Among NAS methods, evolutionary neural architecture methods are popular because of their potential to find the global optimal convolutional neural networks (CNNs). These methods usually use an individual to represent a CNN, while often facing two challenges: 1) since a CNN has numerous encoded parameters and weights, the length of each individual is long which causes a large search space, and 2) due to the unknown optimal depth of a CNN, it is necessary to deal with a variable-length optimization problem, which leads to the search in a messy way since search spaces with different dimensions may have different optimal solutions. In this paper, we propose a genetic algorithm with a simple encoding scheme (SEECNN) for evolving CNNs to address image classification problems. In our encoding scheme, the parameters and weights of each layer are encoded into an individual and the whole population represents an entire CNN. Over the course of evolution, three offspring subpopulations are separately produced by genetic operators on three subpopulations. In each subpopulation, the lengths of individuals are short and equal. Afterward, we design a stable search strategy to update the population based on the performance improvement, where we only insert, replace, and remove one individual to generate candidate populations. SEECNN is compared with 24 well-known algorithms on nine benchmark datasets and five state-of-the-art methods on a real-world skin disease image classification case. The results demonstrate its effectiveness.},

keywords = {},

pubstate = {published},

tppubtype = {article}

}

1259.

Mok, Jisoo; Na, Byunggook; Choe, Hyeokjun; Yoon, Sungroh

AdvRush: Searching for Adversarially Robust Neural Architectures Technical Report

, 2021.