Maintained by Difan Deng and Marius Lindauer.
The following list considers papers related to neural architecture search. It is by no means complete. If you miss a paper on the list, please let us know.
Please note that although NAS methods steadily improve, the quality of empirical evaluations in this field are still lagging behind compared to other areas in machine learning, AI and optimization. We would therefore like to share some best practices for empirical evaluations of NAS methods, which we believe will facilitate sustained and measurable progress in the field. If you are interested in a teaser, please read our blog post or directly jump to our checklist.
Transformers have gained increasing popularity in different domains. For a comprehensive list of papers focusing on Neural Architecture Search for Transformer-Based spaces, the awesome-transformer-search repo is all you need.
5555
4015.
Zhu, Huijuan; Xia, Mengzhen; Wang, Liangmin; Xu, Zhicheng; Sheng, Victor S.
A Novel Knowledge Search Structure for Android Malware Detection Journal Article
In: IEEE Transactions on Services Computing, no. 01, pp. 1-14, 5555, ISSN: 1939-1374.
@article{10750332,
title = { A Novel Knowledge Search Structure for Android Malware Detection },
author = {Huijuan Zhu and Mengzhen Xia and Liangmin Wang and Zhicheng Xu and Victor S. Sheng},
url = {https://doi.ieeecomputersociety.org/10.1109/TSC.2024.3496333},
doi = {10.1109/TSC.2024.3496333},
issn = {1939-1374},
year = {5555},
date = {5555-11-01},
urldate = {5555-11-01},
journal = {IEEE Transactions on Services Computing},
number = {01},
pages = {1-14},
publisher = {IEEE Computer Society},
address = {Los Alamitos, CA, USA},
abstract = {While the Android platform is gaining explosive popularity, the number of malicious software (malware) is also increasing sharply. Thus, numerous malware detection schemes based on deep learning have been proposed. However, they are usually suffering from the cumbersome models with complex architectures and tremendous parameters. They usually require heavy computation power support, which seriously limit their deployment on actual application environments with limited resources (e.g., mobile edge devices). To surmount this challenge, we propose a novel Knowledge Distillation (KD) structure—Knowledge Search (KS). KS exploits Neural Architecture Search (NAS) to adaptively bridge the capability gap between teacher and student networks in KD by introducing a parallelized student-wise search approach. In addition, we carefully analyze the characteristics of malware and locate three cost-effective types of features closely related to malicious attacks, namely, Application Programming Interfaces (APIs), permissions and vulnerable components, to characterize Android Applications (Apps). Therefore, based on typical samples collected in recent years, we refine features while exploiting the natural relationship between them, and construct corresponding datasets. Massive experiments are conducted to investigate the effectiveness and sustainability of KS on these datasets. Our experimental results show that the proposed method yields an accuracy of 97.89% to detect Android malware, which performs better than state-of-the-art solutions.},
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While the Android platform is gaining explosive popularity, the number of malicious software (malware) is also increasing sharply. Thus, numerous malware detection schemes based on deep learning have been proposed. However, they are usually suffering from the cumbersome models with complex architectures and tremendous parameters. They usually require heavy computation power support, which seriously limit their deployment on actual application environments with limited resources (e.g., mobile edge devices). To surmount this challenge, we propose a novel Knowledge Distillation (KD) structure—Knowledge Search (KS). KS exploits Neural Architecture Search (NAS) to adaptively bridge the capability gap between teacher and student networks in KD by introducing a parallelized student-wise search approach. In addition, we carefully analyze the characteristics of malware and locate three cost-effective types of features closely related to malicious attacks, namely, Application Programming Interfaces (APIs), permissions and vulnerable components, to characterize Android Applications (Apps). Therefore, based on typical samples collected in recent years, we refine features while exploiting the natural relationship between them, and construct corresponding datasets. Massive experiments are conducted to investigate the effectiveness and sustainability of KS on these datasets. Our experimental results show that the proposed method yields an accuracy of 97.89% to detect Android malware, which performs better than state-of-the-art solutions.
4014.
Zhang, Feifei; Li, Mao; Ge, Jidong; Tang, Fenghui; Zhang, Sheng; Wu, Jie; Luo, Bin
Privacy-Preserving Federated Neural Architecture Search With Enhanced Robustness for Edge Computing Journal Article
In: IEEE Transactions on Mobile Computing, no. 01, pp. 1-18, 5555, ISSN: 1558-0660.
@article{10742476,
title = { Privacy-Preserving Federated Neural Architecture Search With Enhanced Robustness for Edge Computing },
author = {Feifei Zhang and Mao Li and Jidong Ge and Fenghui Tang and Sheng Zhang and Jie Wu and Bin Luo},
url = {https://doi.ieeecomputersociety.org/10.1109/TMC.2024.3490835},
doi = {10.1109/TMC.2024.3490835},
issn = {1558-0660},
year = {5555},
date = {5555-11-01},
urldate = {5555-11-01},
journal = {IEEE Transactions on Mobile Computing},
number = {01},
pages = {1-18},
publisher = {IEEE Computer Society},
address = {Los Alamitos, CA, USA},
abstract = {With the development of large-scale artificial intelligence services, edge devices are becoming essential providers of data and computing power. However, these edge devices are not immune to malicious attacks. Federated learning (FL), while protecting privacy of decentralized data through secure aggregation, struggles to trace adversaries and lacks optimization for heterogeneity. We discover that FL augmented with Differentiable Architecture Search (DARTS) can improve resilience against backdoor attacks while compatible with secure aggregation. Based on this, we propose a federated neural architecture search (NAS) framwork named SLNAS. The architecture of SLNAS is built on three pivotal components: a server-side search space generation method that employs an evolutionary algorithm with dual encodings, a federated NAS process based on DARTS, and client-side architecture tuning that utilizes Gumbel softmax combined with knowledge distillation. To validate robustness, we adapt a framework that includes backdoor attacks based on trigger optimization, data poisoning, and model poisoning, targeting both model weights and architecture parameters. Extensive experiments demonstrate that SLNAS not only effectively counters advanced backdoor attacks but also handles heterogeneity, outperforming defense baselines across a wide range of backdoor attack scenarios.},
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With the development of large-scale artificial intelligence services, edge devices are becoming essential providers of data and computing power. However, these edge devices are not immune to malicious attacks. Federated learning (FL), while protecting privacy of decentralized data through secure aggregation, struggles to trace adversaries and lacks optimization for heterogeneity. We discover that FL augmented with Differentiable Architecture Search (DARTS) can improve resilience against backdoor attacks while compatible with secure aggregation. Based on this, we propose a federated neural architecture search (NAS) framwork named SLNAS. The architecture of SLNAS is built on three pivotal components: a server-side search space generation method that employs an evolutionary algorithm with dual encodings, a federated NAS process based on DARTS, and client-side architecture tuning that utilizes Gumbel softmax combined with knowledge distillation. To validate robustness, we adapt a framework that includes backdoor attacks based on trigger optimization, data poisoning, and model poisoning, targeting both model weights and architecture parameters. Extensive experiments demonstrate that SLNAS not only effectively counters advanced backdoor attacks but also handles heterogeneity, outperforming defense baselines across a wide range of backdoor attack scenarios.
4013.
Zhang, Yu-Ming; Hsieh, Jun-Wei; Lee, Chun-Chieh; Fan, Kuo-Chin
RATs-NAS: Redirection of Adjacent Trails on Graph Convolutional Networks for Predictor-based Neural Architecture Search Journal Article
In: IEEE Transactions on Artificial Intelligence, vol. 1, no. 01, pp. 1-11, 5555, ISSN: 2691-4581.
@article{10685480,
title = { RATs-NAS: Redirection of Adjacent Trails on Graph Convolutional Networks for Predictor-based Neural Architecture Search },
author = {Yu-Ming Zhang and Jun-Wei Hsieh and Chun-Chieh Lee and Kuo-Chin Fan},
url = {https://doi.ieeecomputersociety.org/10.1109/TAI.2024.3465433},
doi = {10.1109/TAI.2024.3465433},
issn = {2691-4581},
year = {5555},
date = {5555-09-01},
urldate = {5555-09-01},
journal = {IEEE Transactions on Artificial Intelligence},
volume = {1},
number = {01},
pages = {1-11},
publisher = {IEEE Computer Society},
address = {Los Alamitos, CA, USA},
abstract = {Manually designed CNN architectures like VGG, ResNet, DenseNet, and MobileNet have achieved high performance across various tasks, but design them is time-consuming and costly. Neural Architecture Search (NAS) automates the discovery of effective CNN architectures, reducing the need for experts. However, evaluating candidate architectures requires significant GPU resources, leading to the use of predictor-based NAS, such as graph convolutional networks (GCN), which is the popular option to construct predictors. However, we discover that, even though the ability of GCN mimics the propagation of features of real architectures, the binary nature of the adjacency matrix limits its effectiveness. To address this, we propose Redirection of Adjacent Trails (RATs), which adaptively learns trail weights within the adjacency matrix. Our RATs-GCN outperform other predictors by dynamically adjusting trail weights after each graph convolution layer. Additionally, the proposed Divide Search Sampling (DSS) strategy, based on the observation of cell-based NAS that architectures with similar FLOPs perform similarly, enhances search efficiency. Our RATs-NAS, which combine RATs-GCN and DSS, shows significant improvements over other predictor-based NAS methods on NASBench-101, NASBench-201, and NASBench-301.},
keywords = {},
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Manually designed CNN architectures like VGG, ResNet, DenseNet, and MobileNet have achieved high performance across various tasks, but design them is time-consuming and costly. Neural Architecture Search (NAS) automates the discovery of effective CNN architectures, reducing the need for experts. However, evaluating candidate architectures requires significant GPU resources, leading to the use of predictor-based NAS, such as graph convolutional networks (GCN), which is the popular option to construct predictors. However, we discover that, even though the ability of GCN mimics the propagation of features of real architectures, the binary nature of the adjacency matrix limits its effectiveness. To address this, we propose Redirection of Adjacent Trails (RATs), which adaptively learns trail weights within the adjacency matrix. Our RATs-GCN outperform other predictors by dynamically adjusting trail weights after each graph convolution layer. Additionally, the proposed Divide Search Sampling (DSS) strategy, based on the observation of cell-based NAS that architectures with similar FLOPs perform similarly, enhances search efficiency. Our RATs-NAS, which combine RATs-GCN and DSS, shows significant improvements over other predictor-based NAS methods on NASBench-101, NASBench-201, and NASBench-301.
4012.
Chen, X.; Yang, C.
CIMNet: Joint Search for Neural Network and Computing-in-Memory Architecture Journal Article
In: IEEE Micro, no. 01, pp. 1-12, 5555, ISSN: 1937-4143.
@article{10551739,
title = {CIMNet: Joint Search for Neural Network and Computing-in-Memory Architecture},
author = {X. Chen and C. Yang},
url = {https://www.computer.org/csdl/magazine/mi/5555/01/10551739/1XyKBmSlmPm},
doi = {10.1109/MM.2024.3409068},
issn = {1937-4143},
year = {5555},
date = {5555-06-01},
urldate = {5555-06-01},
journal = {IEEE Micro},
number = {01},
pages = {1-12},
publisher = {IEEE Computer Society},
address = {Los Alamitos, CA, USA},
abstract = {Computing-in-memory (CIM) architecture has been proven to effectively transcend the memory wall bottleneck, expanding the potential of low-power and high-throughput applications such as machine learning. Neural architecture search (NAS) designs ML models to meet a variety of accuracy, latency, and energy constraints. However, integrating CIM into NAS presents a major challenge due to additional simulation overhead from the non-ideal characteristics of CIM hardware. This work introduces a quantization and device aware accuracy predictor that jointly scores quantization policy, CIM architecture, and neural network architecture, eliminating the need for time-consuming simulations in the search process. We also propose reducing the search space based on architectural observations, resulting in a well-pruned search space customized for CIM. These allow for efficient exploration of superior combinations in mere CPU minutes. Our methodology yields CIMNet, which consistently improves the trade-off between accuracy and hardware efficiency on benchmarks, providing valuable architectural insights.},
keywords = {},
pubstate = {published},
tppubtype = {article}
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Computing-in-memory (CIM) architecture has been proven to effectively transcend the memory wall bottleneck, expanding the potential of low-power and high-throughput applications such as machine learning. Neural architecture search (NAS) designs ML models to meet a variety of accuracy, latency, and energy constraints. However, integrating CIM into NAS presents a major challenge due to additional simulation overhead from the non-ideal characteristics of CIM hardware. This work introduces a quantization and device aware accuracy predictor that jointly scores quantization policy, CIM architecture, and neural network architecture, eliminating the need for time-consuming simulations in the search process. We also propose reducing the search space based on architectural observations, resulting in a well-pruned search space customized for CIM. These allow for efficient exploration of superior combinations in mere CPU minutes. Our methodology yields CIMNet, which consistently improves the trade-off between accuracy and hardware efficiency on benchmarks, providing valuable architectural insights.
4011.
Dong, Yukang; Pan, Fanxing; Gui, Yi; Jiang, Wenbin; Wan, Yao; Zheng, Ran; Jin, Hai
Comprehensive Architecture Search for Deep Graph Neural Networks Journal Article
In: IEEE Transactions on Big Data, no. 01, pp. 1-15, 5555, ISSN: 2332-7790.
@article{10930718,
title = { Comprehensive Architecture Search for Deep Graph Neural Networks },
author = {Yukang Dong and Fanxing Pan and Yi Gui and Wenbin Jiang and Yao Wan and Ran Zheng and Hai Jin},
url = {https://doi.ieeecomputersociety.org/10.1109/TBDATA.2025.3552336},
doi = {10.1109/TBDATA.2025.3552336},
issn = {2332-7790},
year = {5555},
date = {5555-03-01},
urldate = {5555-03-01},
journal = {IEEE Transactions on Big Data},
number = {01},
pages = {1-15},
publisher = {IEEE Computer Society},
address = {Los Alamitos, CA, USA},
abstract = {In recent years, Neural Architecture Search (NAS) has emerged as a promising approach for automatically discovering superior model architectures for deep Graph Neural Networks (GNNs). Different methods have paid attention to different types of search spaces. However, due to the time-consuming nature of training deep GNNs, existing NAS methods often fail to explore diverse search spaces sufficiently, which constrains their effectiveness. To crack this hard nut, we propose CAS-DGNN, a novel comprehensive architecture search method for deep GNNs. It encompasses four kinds of search spaces that are the composition of aggregate and update operators, different types of aggregate operators, residual connections, and hyper-parameters. To meet the needs of such a complex situation, a phased and hybrid search strategy is proposed to accommodate the diverse characteristics of different search spaces. Specifically, we divide the search process into four phases, utilizing evolutionary algorithms and Bayesian optimization. Meanwhile, we design two distinct search methods for residual connections (All-connected search and Initial Residual search) to streamline the search space, which enhances the scalability of CAS-DGNN. The experimental results show that CAS-DGNN achieves higher accuracy with competitive search costs across ten public datasets compared to existing methods.},
keywords = {},
pubstate = {published},
tppubtype = {article}
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In recent years, Neural Architecture Search (NAS) has emerged as a promising approach for automatically discovering superior model architectures for deep Graph Neural Networks (GNNs). Different methods have paid attention to different types of search spaces. However, due to the time-consuming nature of training deep GNNs, existing NAS methods often fail to explore diverse search spaces sufficiently, which constrains their effectiveness. To crack this hard nut, we propose CAS-DGNN, a novel comprehensive architecture search method for deep GNNs. It encompasses four kinds of search spaces that are the composition of aggregate and update operators, different types of aggregate operators, residual connections, and hyper-parameters. To meet the needs of such a complex situation, a phased and hybrid search strategy is proposed to accommodate the diverse characteristics of different search spaces. Specifically, we divide the search process into four phases, utilizing evolutionary algorithms and Bayesian optimization. Meanwhile, we design two distinct search methods for residual connections (All-connected search and Initial Residual search) to streamline the search space, which enhances the scalability of CAS-DGNN. The experimental results show that CAS-DGNN achieves higher accuracy with competitive search costs across ten public datasets compared to existing methods.
4010.
Yan, J.; Liu, J.; Xu, H.; Wang, Z.; Qiao, C.
Peaches: Personalized Federated Learning with Neural Architecture Search in Edge Computing Journal Article
In: IEEE Transactions on Mobile Computing, no. 01, pp. 1-17, 5555, ISSN: 1558-0660.
@article{10460163,
title = {Peaches: Personalized Federated Learning with Neural Architecture Search in Edge Computing},
author = {J. Yan and J. Liu and H. Xu and Z. Wang and C. Qiao},
doi = {10.1109/TMC.2024.3373506},
issn = {1558-0660},
year = {5555},
date = {5555-03-01},
urldate = {5555-03-01},
journal = {IEEE Transactions on Mobile Computing},
number = {01},
pages = {1-17},
publisher = {IEEE Computer Society},
address = {Los Alamitos, CA, USA},
abstract = {In edge computing (EC), federated learning (FL) enables numerous distributed devices (or workers) to collaboratively train AI models without exposing their local data. Most works of FL adopt a predefined architecture on all participating workers for model training. However, since workers' local data distributions vary heavily in EC, the predefined architecture may not be the optimal choice for every worker. It is also unrealistic to manually design a high-performance architecture for each worker, which requires intense human expertise and effort. In order to tackle this challenge, neural architecture search (NAS) has been applied in FL to automate the architecture design process. Unfortunately, the existing federated NAS frameworks often suffer from the difficulties of system heterogeneity and resource limitation. To remedy this problem, we present a novel framework, termed Peaches, to achieve efficient searching and training in the resource-constrained EC system. Specifically, the local model of each worker is stacked by base cell and personal cell, where the base cell is shared by all workers to capture the common knowledge and the personal cell is customized for each worker to fit the local data. We determine the number of base cells, shared by all workers, according to the bandwidth budget on the parameters server. Besides, to relieve the data and system heterogeneity, we find the optimal number of personal cells for each worker based on its computing capability. In addition, we gradually prune the search space during training to mitigate the resource consumption. We evaluate the performance of Peaches through extensive experiments, and the results show that Peaches can achieve an average accuracy improvement of about 6.29% and up to 3.97× speed up compared with the baselines.},
keywords = {},
pubstate = {published},
tppubtype = {article}
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In edge computing (EC), federated learning (FL) enables numerous distributed devices (or workers) to collaboratively train AI models without exposing their local data. Most works of FL adopt a predefined architecture on all participating workers for model training. However, since workers' local data distributions vary heavily in EC, the predefined architecture may not be the optimal choice for every worker. It is also unrealistic to manually design a high-performance architecture for each worker, which requires intense human expertise and effort. In order to tackle this challenge, neural architecture search (NAS) has been applied in FL to automate the architecture design process. Unfortunately, the existing federated NAS frameworks often suffer from the difficulties of system heterogeneity and resource limitation. To remedy this problem, we present a novel framework, termed Peaches, to achieve efficient searching and training in the resource-constrained EC system. Specifically, the local model of each worker is stacked by base cell and personal cell, where the base cell is shared by all workers to capture the common knowledge and the personal cell is customized for each worker to fit the local data. We determine the number of base cells, shared by all workers, according to the bandwidth budget on the parameters server. Besides, to relieve the data and system heterogeneity, we find the optimal number of personal cells for each worker based on its computing capability. In addition, we gradually prune the search space during training to mitigate the resource consumption. We evaluate the performance of Peaches through extensive experiments, and the results show that Peaches can achieve an average accuracy improvement of about 6.29% and up to 3.97× speed up compared with the baselines.
4009.
Sun, Genchen; Liu, Zhengkun; Gan, Lin; Su, Hang; Li, Ting; Zhao, Wenfeng; Sun, Biao
SpikeNAS-Bench: Benchmarking NAS Algorithms for Spiking Neural Network Architecture Journal Article
In: IEEE Transactions on Artificial Intelligence, vol. 1, no. 01, pp. 1-12, 5555, ISSN: 2691-4581.
@article{10855683,
title = { SpikeNAS-Bench: Benchmarking NAS Algorithms for Spiking Neural Network Architecture },
author = {Genchen Sun and Zhengkun Liu and Lin Gan and Hang Su and Ting Li and Wenfeng Zhao and Biao Sun},
url = {https://doi.ieeecomputersociety.org/10.1109/TAI.2025.3534136},
doi = {10.1109/TAI.2025.3534136},
issn = {2691-4581},
year = {5555},
date = {5555-01-01},
urldate = {5555-01-01},
journal = {IEEE Transactions on Artificial Intelligence},
volume = {1},
number = {01},
pages = {1-12},
publisher = {IEEE Computer Society},
address = {Los Alamitos, CA, USA},
abstract = {In recent years, Neural Architecture Search (NAS) has marked significant advancements, yet its efficacy is marred by the dependence on substantial computational resources. To mitigate this, the development of NAS benchmarks has emerged, offering datasets that enumerate all potential network architectures and their performances within a predefined search space. Nonetheless, these benchmarks predominantly focus on convolutional architectures, which are criticized for their limited interpretability and suboptimal hardware efficiency. Recognizing the untapped potential of Spiking Neural Networks (SNNs) — often hailed as the third generation of neural networks for their biological realism and computational thrift — this study introduces SpikeNAS-Bench. As a pioneering benchmark for SNN, SpikeNAS-Bench utilizes a cell-based search space, integrating leaky integrate-and-fire (LIF) neurons with variable thresholds as candidate operations. It encompasses 15,625 candidate architectures, rigorously evaluated on CIFAR10, CIFAR100 and Tiny-ImageNet datasets. This paper delves into the architectural nuances of SpikeNAS-Bench, leveraging various criteria to underscore the benchmark’s utility and presenting insights that could steer future NAS algorithm designs. Moreover, we assess the benchmark’s consistency through three distinct proxy types: zero-cost-based, early-stop-based, and predictor-based proxies. Additionally, the paper benchmarks seven contemporary NAS algorithms to attest to SpikeNAS-Bench’s broad applicability. We commit to providing training logs, diagnostic data for all candidate architectures, and the promise to release all code and datasets post-acceptance, aiming to catalyze further exploration and innovation within the SNN domain. SpikeNAS-Bench is open source at https://github.com/XXX (hidden for double anonymous review).},
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In recent years, Neural Architecture Search (NAS) has marked significant advancements, yet its efficacy is marred by the dependence on substantial computational resources. To mitigate this, the development of NAS benchmarks has emerged, offering datasets that enumerate all potential network architectures and their performances within a predefined search space. Nonetheless, these benchmarks predominantly focus on convolutional architectures, which are criticized for their limited interpretability and suboptimal hardware efficiency. Recognizing the untapped potential of Spiking Neural Networks (SNNs) — often hailed as the third generation of neural networks for their biological realism and computational thrift — this study introduces SpikeNAS-Bench. As a pioneering benchmark for SNN, SpikeNAS-Bench utilizes a cell-based search space, integrating leaky integrate-and-fire (LIF) neurons with variable thresholds as candidate operations. It encompasses 15,625 candidate architectures, rigorously evaluated on CIFAR10, CIFAR100 and Tiny-ImageNet datasets. This paper delves into the architectural nuances of SpikeNAS-Bench, leveraging various criteria to underscore the benchmark’s utility and presenting insights that could steer future NAS algorithm designs. Moreover, we assess the benchmark’s consistency through three distinct proxy types: zero-cost-based, early-stop-based, and predictor-based proxies. Additionally, the paper benchmarks seven contemporary NAS algorithms to attest to SpikeNAS-Bench’s broad applicability. We commit to providing training logs, diagnostic data for all candidate architectures, and the promise to release all code and datasets post-acceptance, aiming to catalyze further exploration and innovation within the SNN domain. SpikeNAS-Bench is open source at https://github.com/XXX (hidden for double anonymous review).
4008.
Li, Changlin; Lin, Sihao; Tang, Tao; Wang, Guangrun; Li, Mingjie; Li, Zhihui; Chang, Xiaojun
BossNAS Family: Block-wisely Self-supervised Neural Architecture Search Journal Article
In: IEEE Transactions on Pattern Analysis & Machine Intelligence, no. 01, pp. 1-15, 5555, ISSN: 1939-3539.
@article{10839629,
title = { BossNAS Family: Block-wisely Self-supervised Neural Architecture Search },
author = {Changlin Li and Sihao Lin and Tao Tang and Guangrun Wang and Mingjie Li and Zhihui Li and Xiaojun Chang},
url = {https://doi.ieeecomputersociety.org/10.1109/TPAMI.2025.3529517},
doi = {10.1109/TPAMI.2025.3529517},
issn = {1939-3539},
year = {5555},
date = {5555-01-01},
urldate = {5555-01-01},
journal = {IEEE Transactions on Pattern Analysis & Machine Intelligence},
number = {01},
pages = {1-15},
publisher = {IEEE Computer Society},
address = {Los Alamitos, CA, USA},
abstract = {Recent advances in hand-crafted neural architectures for visual recognition underscore the pressing need to explore architecture designs comprising diverse building blocks. Concurrently, neural architecture search (NAS) methods have gained traction as a means to alleviate human efforts. Nevertheless, the question of whether NAS methods can efficiently and effectively manage diversified search spaces featuring disparate candidates, such as Convolutional Neural Networks (CNNs) and transformers, remains an open question. In this work, we introduce a novel unsupervised NAS approach called BossNAS (Block-wisely Self-supervised Neural Architecture Search), which aims to address the problem of inaccurate predictive architecture ranking caused by a large weight-sharing space while mitigating potential ranking issue caused by biased supervision. To achieve this, we factorize the search space into blocks and introduce a novel self-supervised training scheme called Ensemble Bootstrapping, to train each block separately in an unsupervised manner. In the search phase, we propose an unsupervised Population-Centric Search, optimizing the candidate architecture towards the population center. Additionally, we enhance our NAS method by integrating masked image modeling and present BossNAS++ to overcome the lack of dense supervision in our block-wise self-supervised NAS. In BossNAS++, we introduce the training technique named Masked Ensemble Bootstrapping for block-wise supernet, accompanied by a Masked Population-Centric Search scheme to promote fairer architecture selection. Our family of models, discovered through BossNAS and BossNAS++, delivers impressive results across various search spaces and datasets. Our transformer model discovered by BossNAS++ attains a remarkable accuracy of 83.2% on ImageNet with only 10.5B MAdds, surpassing DeiT-B by 1.4% while maintaining a lower computation cost. Moreover, our approach excels in architecture rating accuracy, achieving Spearman correlations of 0.78 and 0.76 on the canonical MBConv search space with ImageNet and the NATS-Bench size search space with CIFAR-100, respectively, outperforming state-of-the-art NAS methods.},
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Recent advances in hand-crafted neural architectures for visual recognition underscore the pressing need to explore architecture designs comprising diverse building blocks. Concurrently, neural architecture search (NAS) methods have gained traction as a means to alleviate human efforts. Nevertheless, the question of whether NAS methods can efficiently and effectively manage diversified search spaces featuring disparate candidates, such as Convolutional Neural Networks (CNNs) and transformers, remains an open question. In this work, we introduce a novel unsupervised NAS approach called BossNAS (Block-wisely Self-supervised Neural Architecture Search), which aims to address the problem of inaccurate predictive architecture ranking caused by a large weight-sharing space while mitigating potential ranking issue caused by biased supervision. To achieve this, we factorize the search space into blocks and introduce a novel self-supervised training scheme called Ensemble Bootstrapping, to train each block separately in an unsupervised manner. In the search phase, we propose an unsupervised Population-Centric Search, optimizing the candidate architecture towards the population center. Additionally, we enhance our NAS method by integrating masked image modeling and present BossNAS++ to overcome the lack of dense supervision in our block-wise self-supervised NAS. In BossNAS++, we introduce the training technique named Masked Ensemble Bootstrapping for block-wise supernet, accompanied by a Masked Population-Centric Search scheme to promote fairer architecture selection. Our family of models, discovered through BossNAS and BossNAS++, delivers impressive results across various search spaces and datasets. Our transformer model discovered by BossNAS++ attains a remarkable accuracy of 83.2% on ImageNet with only 10.5B MAdds, surpassing DeiT-B by 1.4% while maintaining a lower computation cost. Moreover, our approach excels in architecture rating accuracy, achieving Spearman correlations of 0.78 and 0.76 on the canonical MBConv search space with ImageNet and the NATS-Bench size search space with CIFAR-100, respectively, outperforming state-of-the-art NAS methods.
2025
4007.
Wang, Weiqi; Bao, Feilong; Xing, Zhecong; Lian, Zhe
A Survey: Research Progress of Feature Fusion Technology Journal Article
In: 2025.
@article{wangsurvey,
title = {A Survey: Research Progress of Feature Fusion Technology},
author = {Weiqi Wang and Feilong Bao and Zhecong Xing and Zhe Lian},
url = {http://poster-openaccess.com/files/ICIC2024/862.pdf},
year = {2025},
date = {2025-12-01},
keywords = {},
pubstate = {published},
tppubtype = {article}
}
4006.
(Ed.)
MACHINE-GENERATED NEURAL NETWORKS FOR SHORT-TERM LOAD FORECASTING Collection
2025.
@collection{nokey,
title = { MACHINE-GENERATED NEURAL NETWORKS FOR SHORT-TERM LOAD FORECASTING},
author = {Gergana Vacheva and Plamen Stanchev and Nikolay Hinov
},
url = {https://unitechsp.tugab.bg/images/2024/1-EE/s1_p143_v1.pdf},
year = {2025},
date = {2025-12-01},
urldate = {2025-12-01},
booktitle = {International Scientific Conference UNITECH`2024},
journal = {International Scientific Conference UNITECH`2024},
keywords = {},
pubstate = {published},
tppubtype = {collection}
}
4005.
Wu, Yue; Huang, Lin; Yang, Tiejun
Breast Ultrasound Image Segmentation Using Multi-branch Skip Connection Search Journal Article
In: Journal of Imaging Informatics in Medicine , 2025.
@article{wu-jiim25a,
title = {Breast Ultrasound Image Segmentation Using Multi-branch Skip Connection Search},
author = { Yue Wu and Lin Huang and Tiejun Yang
},
url = {https://link.springer.com/article/10.1007/s10278-025-01487-6},
year = {2025},
date = {2025-04-01},
urldate = {2025-04-01},
journal = {Journal of Imaging Informatics in Medicine },
keywords = {},
pubstate = {published},
tppubtype = {article}
}
4004.
CAPELLO, ALESSIO
An End-to-End Edge-Computing Framework for IoT-enabled Monitoring PhD Thesis
2025.
@phdthesis{nokey,
title = {An End-to-End Edge-Computing Framework for IoT-enabled Monitoring},
author = { CAPELLO, ALESSIO },
url = {https://tesidottorato.depositolegale.it/handle/20.500.14242/199679?mode=simple},
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4003.
Tran, Thanh Hai; Nguyen, Dac Tam; Ngo, Minh Duc; Doan, Long; Luong, Ngoc Hoang; Binh, Huynh Thi Thanh
Kernelshap-nas: a shapley additive explanatory approach for characterizing operation influences Journal Article
In: Neural Computing and Applications , 2025.
@article{nokey,
title = {Kernelshap-nas: a shapley additive explanatory approach for characterizing operation influences},
author = {Thanh Hai Tran and Dac Tam Nguyen and Minh Duc Ngo and Long Doan and Ngoc Hoang Luong and Huynh Thi Thanh Binh
},
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date = {2025-03-05},
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4002.
Ju, Moran; Niu, Buniu; Li, Mulin; Mao, Tengkai; Jin, Si-nian
Toward Better Accuracy-Efficiency Trade-Offs for Oriented SAR Ship Object Detection Bachelor Thesis
2025.
@bachelorthesis{ju-jstaeors,
title = {Toward Better Accuracy-Efficiency Trade-Offs for Oriented SAR Ship Object Detection},
author = {Moran Ju and Buniu Niu and Mulin Li and Tengkai Mao and Si-nian Jin},
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4001.
Liu, Guoqing; Qian, Yuhua; Liang, Xinyan; Fu, Pinhan
Core structure-guided multi-modal classification via Monte Carlo Tree Search Journal Article
In: International Journal of Machine Learning and Cybernetics , 2025.
@article{liu-ijmlc25a,
title = {Core structure-guided multi-modal classification via Monte Carlo Tree Search},
author = { Guoqing Liu and Yuhua Qian and Xinyan Liang and Pinhan Fu
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4000.
HERNANDEZ, ESAU ALAIN HERVERT; CAO, YAN; KEHTARNAVAZ, NASSER
Computationally Efficient Neural Architecture Search for Image Denoising Bachelor Thesis
2025.
@bachelorthesis{nokey,
title = {Computationally Efficient Neural Architecture Search for Image Denoising},
author = {ESAU ALAIN HERVERT HERNANDEZ and YAN CAO and NASSER KEHTARNAVAZ},
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3999.
Naayini, Prudhvi; Kamatala, Srikanth; Myakala, Praveen Kumar
Transforming Performance Engineering with Generative AI Journal Article
In: Journal of Computer and Communications , vol. 13, no. 3, 2025.
@article{Naayini-jcc25a,
title = { Transforming Performance Engineering with Generative AI },
author = { Prudhvi Naayini and Srikanth Kamatala and Praveen Kumar Myakala},
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3998.
Xu, Dikai; Cao, Bin
Adaptive Multiobjective Evolutionary Generative Adversarial Network for Metaverse Network Intrusion Detection Journal Article
In: Science Partner Journals, 2025.
@article{nokey,
title = {Adaptive Multiobjective Evolutionary Generative Adversarial Network for Metaverse Network Intrusion Detection},
author = {Dikai Xu and Bin Cao},
url = {https://spj.science.org/doi/pdf/10.34133/research.0665},
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3997.
Li, Yuangang; Ma, Rui; Zhang, Qian; Wang, Zeyu; Zong, Linlin; Liu, Xinyue
Neural architecture search using attention enhanced precise path evaluation and efficient forward evolution Journal Article
In: scientific reports , 2025.
@article{nokey,
title = {Neural architecture search using attention enhanced precise path evaluation and efficient forward evolution},
author = {Yuangang Li and Rui Ma and Qian Zhang and Zeyu Wang and Linlin Zong and Xinyue Liu
},
url = {https://www.nature.com/articles/s41598-025-94187-8},
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3996.
(Ed.)
HPE-DARTS: Hybrid Pruning and Proxy Evaluation in Differentiable Architecture Search Collection
2025.
@collection{lin-,
title = {HPE-DARTS: Hybrid Pruning and Proxy Evaluation in Differentiable Architecture Search},
author = {Hung-I Lin and Lin-Jing Kuo and Sheng-De Wang},
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year = {2025},
date = {2025-03-01},
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booktitle = {Proceedings of the 17th International Conference on Agents and Artificial Intelligence (ICAART 2025)},
journal = {Proceedings of the 17th International Conference on Agents and Artificial Intelligence (ICAART 2025)},
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}
3995.
(Ed.)
2025.
@collection{Friderikos-dte25a,
title = {OPTIMIZED LSTM NEURAL NETWORKS VIA NEURAL ARCHITECTURE SEARCH FOR PREDICTING DAMAGE EVOLUTION IN COMPOSITE LAMINATES},
author = {O. Friderikos and A. Mendoza and Emmanuel Baranger and D. Sagris and C. David},
url = {https://congressarchive.cimne.com/dte_aicomas_2025/abstracts/b8d1d10a96b711efba01000c29ddfc0c.pdf},
year = {2025},
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booktitle = {Digital Twins in Engineering & Artificial Intelligence and Computational Methods in Applied Science, DTE - AICOMAS 2025},
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3994.
Fang, Xuwei; Xie, Weisheng; Li, Hui; Zhou, Wenbin; Hang, Chen; Gao, Xiangxiang
DARTS-EAST: an edge-adaptive selection with topology first differentiable architecture selection method Journal Article
In: Applied Intelligence , 2025.
@article{fang-ai25a,
title = {DARTS-EAST: an edge-adaptive selection with topology first differentiable architecture selection method},
author = {Xuwei Fang and Weisheng Xie and Hui Li and Wenbin Zhou and Chen Hang and Xiangxiang Gao
},
url = {https://link.springer.com/article/10.1007/s10489-025-06353-0},
year = {2025},
date = {2025-03-01},
urldate = {2025-03-01},
journal = {Applied Intelligence },
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3993.
(Ed.)
Neural Architecture Search: Tradeoff Between Performance and Efficiency Collection
2025.
@collection{nokey,
title = {Neural Architecture Search: Tradeoff Between Performance and Efficiency},
author = {Tien Dung Nguyen and Nassim Mokhtari and Alexis Nédélec},
url = {https://www.scitepress.org/Papers/2025/132969/132969.pdf},
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date = {2025-03-01},
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3992.
(Ed.)
PQNAS: Mixed-precision Quantization-aware Neural Architecture Search with Pseudo Quantizer Collection
2025.
@collection{gao-icassp25a,
title = {PQNAS: Mixed-precision Quantization-aware Neural Architecture Search with Pseudo Quantizer},
author = {Tianxiao Gao and Li Guo and Shihao Wang and Shiai Zhu and Dajiang Zhou},
url = {https://ieeexplore.ieee.org/stamp/stamp.jsp?arnumber=10888233},
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booktitle = {2025 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP)},
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3991.
He, Zhimin; Chen, Hongxiang; Zhou, Yan; Situ, Haozhen; Li, Yongyao; Li, Lvzhou
Self-supervised representation learning for Bayesian quantum architecture search Journal Article
In: Phys. Rev. A, vol. 111, iss. 3, pp. 032403, 2025.
@article{PhysRevA.111.032403,
title = {Self-supervised representation learning for Bayesian quantum architecture search},
author = {Zhimin He and Hongxiang Chen and Yan Zhou and Haozhen Situ and Yongyao Li and Lvzhou Li},
url = {https://link.aps.org/doi/10.1103/PhysRevA.111.032403},
doi = {10.1103/PhysRevA.111.032403},
year = {2025},
date = {2025-03-01},
urldate = {2025-03-01},
journal = {Phys. Rev. A},
volume = {111},
issue = {3},
pages = {032403},
publisher = {American Physical Society},
keywords = {},
pubstate = {published},
tppubtype = {article}
}
3990.
Feng, Shiyang; Li, Zhaowei; Zhang, Bo; Chen, Tao
DSF2-NAS: Dual-Stage Feature Fusion via Network Architecture Search for Classification of Multimodal Remote Sensing Images Journal Article
In: IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing. , 2025.
@article{feng-ieeejstoaeors25a,
title = {DSF2-NAS: Dual-Stage Feature Fusion via Network Architecture Search for Classification of Multimodal Remote Sensing Images},
author = {Shiyang Feng and Zhaowei Li and Bo Zhang and Tao Chen},
url = {https://ieeexplore.ieee.org/stamp/stamp.jsp?arnumber=10904332},
year = {2025},
date = {2025-03-01},
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journal = { IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing. },
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}
3989.
(Ed.)
TinyDevID: TinyML-Driven IoT Devices IDentification Using Network Flow Data Collection
2025.
@collection{Rushikesh-csp25a,
title = {TinyDevID: TinyML-Driven IoT Devices IDentification Using Network Flow Data},
author = {Priyanka Rushikesh Chaudhary and Anand Agrawal and Rajib Ranjan Maiti},
url = {https://ieeexplore.ieee.org/stamp/stamp.jsp?arnumber=10885715},
year = {2025},
date = {2025-02-01},
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booktitle = {COMSNETS 2025 - Cybersecurity & Privacy Workshop (CSP)},
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3988.
Yu, Sixing
2025.
@phdthesis{yu-phd25a,
title = {Scalable and resource-efcient federated learning: Techniques for resource-constrained heterogeneous systems},
author = {Sixing Yu},
url = {https://www.proquest.com/docview/3165602177?pq-origsite=gscholar&fromopenview=true&sourcetype=Dissertations%20&%20Theses},
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date = {2025-02-01},
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}
3987.
Fu, Jintao; Cong, Peng; Xu, Shuo; Chang, Jiahao; Liu, Ximing; Sun, Yuewen
Neural architecture search with Deep Radon Prior for sparse-view CT image reconstruction Journal Article
In: Med Phys , 2025.
@article{Fu-medphs25a,
title = { Neural architecture search with Deep Radon Prior for sparse-view CT image reconstruction },
author = {Jintao Fu and Peng Cong and Shuo Xu and Jiahao Chang and Ximing Liu and Yuewen Sun
},
url = {https://pubmed.ncbi.nlm.nih.gov/39930320/},
year = {2025},
date = {2025-02-01},
urldate = {2025-02-01},
journal = { Med Phys },
keywords = {},
pubstate = {published},
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}
3986.
Zhao, Yi-Heng; Pang, Shen-Wen; Huang, Heng-Zhi; Wu, Shao-Wen; Sun, Shao-Hua; Liu, Zhen-Bing; Pan, Zhi-Chao
Automatic clustering of single-molecule break junction data through task-oriented representation learning Journal Article
In: Rare Metals , 2025.
@article{zhao-rarem25a,
title = {Automatic clustering of single-molecule break junction data through task-oriented representation learning},
author = {
Yi-Heng Zhao and Shen-Wen Pang and Heng-Zhi Huang and Shao-Wen Wu and Shao-Hua Sun and Zhen-Bing Liu and Zhi-Chao Pan
},
url = {https://link.springer.com/article/10.1007/s12598-024-03089-7},
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date = {2025-02-01},
urldate = {2025-02-01},
journal = { Rare Metals },
keywords = {},
pubstate = {published},
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}
3985.
Huang, Tao
Efficient Deep Neural Architecture Design and Training PhD Thesis
2025.
@phdthesis{nokey,
title = {Efficient Deep Neural Architecture Design and Training},
author = { Huang, Tao },
url = {https://ses.library.usyd.edu.au/handle/2123/33598},
year = {2025},
date = {2025-02-01},
urldate = {2025-02-01},
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}
3984.
Herterich, Nils; Liu, Kai; Stein, Anthony
Multi-objective neural architecture search for real-time weed detection on embedded system Miscellaneous
2025.
@misc{Herterich,
title = {Multi-objective neural architecture search for real-time weed detection on embedded system},
author = {Nils Herterich and Kai Liu and Anthony Stein},
url = {https://dl.gi.de/server/api/core/bitstreams/29a49f8d-304e-4073-8a92-4bef6483c087/content},
year = {2025},
date = {2025-02-01},
keywords = {},
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tppubtype = {misc}
}
3983.
Tabak, Gabriel Couto; Molenaar, Dylan; Curi, Mariana
An evolutionary neural architecture search for item response theory autoencoders Journal Article
In: Behaviormetrika , 2025.
@article{nokey,
title = {An evolutionary neural architecture search for item response theory autoencoders},
author = {Gabriel Couto Tabak and Dylan Molenaar and Mariana Curi
},
url = {https://link.springer.com/article/10.1007/s41237-024-00250-5},
year = {2025},
date = {2025-01-27},
urldate = {2025-01-27},
journal = {Behaviormetrika },
keywords = {},
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tppubtype = {article}
}
3982.
Hao, Debei; Pei, Songwei
MIG-DARTS: towards effective differentiable architecture search by gradually mitigating the initial-channel gap between search and evaluation Journal Article
In: Neural Computing and Applications, 2025.
@article{nokey,
title = {MIG-DARTS: towards effective differentiable architecture search by gradually mitigating the initial-channel gap between search and evaluation},
author = {
Debei Hao and Songwei Pei
},
url = {https://link.springer.com/article/10.1007/s00521-024-10681-6},
year = {2025},
date = {2025-01-09},
urldate = {2025-01-09},
journal = {Neural Computing and Applications},
keywords = {},
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}
3981.
(Ed.)
2025.
@collection{nokey,
title = {H4H: Hybrid Convolution-Transformer Architecture Search for NPU-CIM Heterogeneous Systems for AR/VR Applications},
author = {Yiwei Zhao and Jinhui Chen and Sai Qian Zhang and Syed Shakib Sarwar and Kleber Hugo Stangherlin and Jorge Tomas Gomez and Jae-Sun Seo and Barbara De Salvo and Chiao Liu and Phillip B. Gibbons and Ziyun Li},
url = {https://www.pdl.cmu.edu/PDL-FTP/associated/ASP-DAC2025-1073-12.pdf},
year = {2025},
date = {2025-01-02},
urldate = {2025-01-02},
booktitle = {ASPDAC ’25},
keywords = {},
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tppubtype = {collection}
}
3980.
WAKAYAMA, Keigo; KANAMORI, Takafumi
Ultra-fast NAS based on Normalized Generalization Error with Random NTK Journal Article
In: IEICE Transactions on Information and Systems, vol. advpub, pp. 2024EDP7245, 2025.
@article{KeigoWAKAYAMA20252024EDP7245,
title = {Ultra-fast NAS based on Normalized Generalization Error with Random NTK},
author = {Keigo WAKAYAMA and Takafumi KANAMORI},
url = {https://www.jstage.jst.go.jp/article/transinf/advpub/0/advpub_2024EDP7245/_article},
doi = {10.1587/transinf.2024EDP7245},
year = {2025},
date = {2025-01-01},
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journal = {IEICE Transactions on Information and Systems},
volume = {advpub},
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keywords = {},
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}
3979.
Yan, Li; Du, Yi; Liang, Jing; Qu, Boyang; Li, Chao; Yu, Kunjie
A Weight Inheritance and Guidance Strategy based Evolutionary Network Architecture Search Journal Article
In: IEEE Transactions on Evolutionary Computation, pp. 1-1, 2025.
@article{10950438,
title = {A Weight Inheritance and Guidance Strategy based Evolutionary Network Architecture Search},
author = {Li Yan and Yi Du and Jing Liang and Boyang Qu and Chao Li and Kunjie Yu},
url = {https://ieeexplore.ieee.org/abstract/document/10950438},
doi = {10.1109/TEVC.2025.3558334},
year = {2025},
date = {2025-01-01},
urldate = {2025-01-01},
journal = {IEEE Transactions on Evolutionary Computation},
pages = {1-1},
keywords = {},
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tppubtype = {article}
}
3978.
Chehade, Adel; Ragusa, Edoardo; Gastaldo, Paolo; Zunino, Rodolfo
Tiny Neural Networks for Session-Level Traffic Classification Technical Report
2025.
@techreport{chehade2025tinyneuralnetworkssessionlevel,
title = {Tiny Neural Networks for Session-Level Traffic Classification},
author = {Adel Chehade and Edoardo Ragusa and Paolo Gastaldo and Rodolfo Zunino},
url = {https://arxiv.org/abs/2504.04008},
year = {2025},
date = {2025-01-01},
urldate = {2025-01-01},
keywords = {},
pubstate = {published},
tppubtype = {techreport}
}
3977.
Kang, Siyuan; Sun, Yinghao; Li, Shuguang; Xu, Yaozong; Li, Yuke; Chen, Guangjie; Xue, Fei
A lightweight neural network search algorithm based on in-place distillation and performance prediction for hardware-aware optimization Journal Article
In: Engineering Applications of Artificial Intelligence, vol. 151, pp. 110775, 2025, ISSN: 0952-1976.
@article{KANG2025110775,
title = {A lightweight neural network search algorithm based on in-place distillation and performance prediction for hardware-aware optimization},
author = {Siyuan Kang and Yinghao Sun and Shuguang Li and Yaozong Xu and Yuke Li and Guangjie Chen and Fei Xue},
url = {https://www.sciencedirect.com/science/article/pii/S0952197625007754},
doi = {https://doi.org/10.1016/j.engappai.2025.110775},
issn = {0952-1976},
year = {2025},
date = {2025-01-01},
urldate = {2025-01-01},
journal = {Engineering Applications of Artificial Intelligence},
volume = {151},
pages = {110775},
abstract = {Due to the limited computing resources of edge devices, traditional object detection algorithms struggle to meet the efficiency and accuracy requirements of autonomous driving. Consequently, designing a neural network model that balances hardware resource requirements, operating speed, and accuracy is crucial. To address this, by integrating algorithm with hardware characteristics, we propose a lightweight neural network architecture search algorithm based on in-place distillation and performance predictor (LNIP). Initially, we focus on optimizing the operators of the you only look once version 8 nano (YOLOv8n) and dynamically adjust its network structure. Then, we trained a super-network using a progressive shrinking strategy, the sandwich rule, and in-place distillation. Subsequently, we employed a Gaussian process to model the relationship between network architecture and accuracy, utilizing encoding methods and custom kernel function to develop high-performance predictor. Finally, during the search process, we introduce a reward function based on Pareto optimality to balance the performance of the model with hardware constraints. Building upon this foundation, we design an efficient search algorithm based on the performance predictor to progressively explore the optimal network structure tailored to hardware characteristics. We compared our lightweight network with state-of-the-art methods on the BDD100K, COCO, and PASCAL VOC datasets and deployed it on the Black Sesame A1000 and NVIDIA Xavier for comprehensive evaluation. On the NVIDIA Xavier, the lightweight network achieves a latency of 11.81 ms and an edge precision of 46.1 %. These experimental results demonstrate that our method outperforms existing methods in balancing hardware constraints and model performance.},
keywords = {},
pubstate = {published},
tppubtype = {article}
}
Due to the limited computing resources of edge devices, traditional object detection algorithms struggle to meet the efficiency and accuracy requirements of autonomous driving. Consequently, designing a neural network model that balances hardware resource requirements, operating speed, and accuracy is crucial. To address this, by integrating algorithm with hardware characteristics, we propose a lightweight neural network architecture search algorithm based on in-place distillation and performance predictor (LNIP). Initially, we focus on optimizing the operators of the you only look once version 8 nano (YOLOv8n) and dynamically adjust its network structure. Then, we trained a super-network using a progressive shrinking strategy, the sandwich rule, and in-place distillation. Subsequently, we employed a Gaussian process to model the relationship between network architecture and accuracy, utilizing encoding methods and custom kernel function to develop high-performance predictor. Finally, during the search process, we introduce a reward function based on Pareto optimality to balance the performance of the model with hardware constraints. Building upon this foundation, we design an efficient search algorithm based on the performance predictor to progressively explore the optimal network structure tailored to hardware characteristics. We compared our lightweight network with state-of-the-art methods on the BDD100K, COCO, and PASCAL VOC datasets and deployed it on the Black Sesame A1000 and NVIDIA Xavier for comprehensive evaluation. On the NVIDIA Xavier, the lightweight network achieves a latency of 11.81 ms and an edge precision of 46.1 %. These experimental results demonstrate that our method outperforms existing methods in balancing hardware constraints and model performance.
3976.
Roshtkhari, Mehraveh Javan; Toews, Matthew; Pedersoli, Marco
Neural Architecture Search by Learning a Hierarchical Search Space Technical Report
2025.
@techreport{roshtkhari2025neuralarchitecturesearchlearning,
title = {Neural Architecture Search by Learning a Hierarchical Search Space},
author = {Mehraveh Javan Roshtkhari and Matthew Toews and Marco Pedersoli},
url = {https://arxiv.org/abs/2503.21061},
year = {2025},
date = {2025-01-01},
urldate = {2025-01-01},
keywords = {},
pubstate = {published},
tppubtype = {techreport}
}
3975.
Yu, YiMing; Zutty, Jason
LLM-Guided Evolution: An Autonomous Model Optimization for Object Detection Technical Report
2025.
@techreport{yu2025llmguidedevolutionautonomousmodel,
title = {LLM-Guided Evolution: An Autonomous Model Optimization for Object Detection},
author = {YiMing Yu and Jason Zutty},
url = {https://arxiv.org/abs/2504.02280},
year = {2025},
date = {2025-01-01},
urldate = {2025-01-01},
keywords = {},
pubstate = {published},
tppubtype = {techreport}
}
3974.
Capuano, Francesco; Tiboni, Gabriele; Cavagnero, Niccolò; Averta, Giuseppe
Sim-is-More: Randomizing HW-NAS with Synthetic Devices Technical Report
2025.
@techreport{capuano2025simismorerandomizinghwnassynthetic,
title = {Sim-is-More: Randomizing HW-NAS with Synthetic Devices},
author = {Francesco Capuano and Gabriele Tiboni and Niccolò Cavagnero and Giuseppe Averta},
url = {https://arxiv.org/abs/2504.00663},
year = {2025},
date = {2025-01-01},
urldate = {2025-01-01},
keywords = {},
pubstate = {published},
tppubtype = {techreport}
}
3973.
Peri, Gianluca; Giambagli, Lorenzo; Chicchi, Lorenzo; Fanelli, Duccio
Spectral Architecture Search for Neural Networks Technical Report
2025.
@techreport{peri2025spectralarchitecturesearchneural,
title = {Spectral Architecture Search for Neural Networks},
author = {Gianluca Peri and Lorenzo Giambagli and Lorenzo Chicchi and Duccio Fanelli},
url = {https://arxiv.org/abs/2504.00885},
year = {2025},
date = {2025-01-01},
urldate = {2025-01-01},
keywords = {},
pubstate = {published},
tppubtype = {techreport}
}
3972.
Yamasaki, Tomomasa; Wang, Zhehui; Luo, Tao; Chen, Niangjun; Wang, Bo
RBFleX-NAS: Training-Free Neural Architecture Search Using Radial Basis Function Kernel and Hyperparameter Detection Technical Report
2025.
@techreport{yamasaki2025rbflexnastrainingfreeneuralarchitecture,
title = {RBFleX-NAS: Training-Free Neural Architecture Search Using Radial Basis Function Kernel and Hyperparameter Detection},
author = {Tomomasa Yamasaki and Zhehui Wang and Tao Luo and Niangjun Chen and Bo Wang},
url = {https://arxiv.org/abs/2503.22733},
year = {2025},
date = {2025-01-01},
urldate = {2025-01-01},
keywords = {},
pubstate = {published},
tppubtype = {techreport}
}
3971.
Zhang, TingJie; Liu, HaiLin
Multi-Task Neural Architecture Search Using Architecture Embedding and Transfer Rank Technical Report
2025.
@techreport{zhang2025multitaskneuralarchitecturesearch,
title = {Multi-Task Neural Architecture Search Using Architecture Embedding and Transfer Rank},
author = {TingJie Zhang and HaiLin Liu},
url = {https://arxiv.org/abs/2504.00772},
year = {2025},
date = {2025-01-01},
urldate = {2025-01-01},
keywords = {},
pubstate = {published},
tppubtype = {techreport}
}
3970.
Zhu, Qingling; Yang, Yeming; Liu, Songbai; Lin, Qiuzhen; Tan, Kay Chen
SCGAN: Sampling and Clustering-Based Neural Architecture Search for GANs Journal Article
In: IEEE Transactions on Emerging Topics in Computational Intelligence, pp. 1-12, 2025.
@article{10944782,
title = {SCGAN: Sampling and Clustering-Based Neural Architecture Search for GANs},
author = {Qingling Zhu and Yeming Yang and Songbai Liu and Qiuzhen Lin and Kay Chen Tan},
url = {https://ieeexplore.ieee.org/abstract/document/10944782},
doi = {10.1109/TETCI.2025.3547611},
year = {2025},
date = {2025-01-01},
urldate = {2025-01-01},
journal = {IEEE Transactions on Emerging Topics in Computational Intelligence},
pages = {1-12},
keywords = {},
pubstate = {published},
tppubtype = {article}
}
3969.
Mbamba, Christian Kazadi; Keymer, Philip; Alvi, Maira; Topalian, Sebastian O. N.; Din, Fareed Ud; Batstone, Damien J.
Enhancing data quality in wastewater processes: Missing data imputation with deep Variational Autoencoders and genetic algorithms Journal Article
In: Computers & Chemical Engineering, vol. 199, pp. 109123, 2025, ISSN: 0098-1354.
@article{KAZADIMBAMBA2025109123,
title = {Enhancing data quality in wastewater processes: Missing data imputation with deep Variational Autoencoders and genetic algorithms},
author = {Christian Kazadi Mbamba and Philip Keymer and Maira Alvi and Sebastian O. N. Topalian and Fareed Ud Din and Damien J. Batstone},
url = {https://www.sciencedirect.com/science/article/pii/S0098135425001279},
doi = {https://doi.org/10.1016/j.compchemeng.2025.109123},
issn = {0098-1354},
year = {2025},
date = {2025-01-01},
urldate = {2025-01-01},
journal = {Computers & Chemical Engineering},
volume = {199},
pages = {109123},
abstract = {Missing data is a persistent challenge in wastewater analysis, often leading to biased results and reduced accuracy. This study introduces an innovative Automated Machine Learning (AutoML) framework that combines deep learning-based variational autoencoders (VAEs) and genetic algorithms (GAs) to address this issue. VAEs are employed to impute missing values by learning latent data representations, while GAs optimize the VAE architecture and hyperparameters, including the size of the latent space. The framework is specifically designed to handle the complex and nonlinear relationships in wastewater datasets. The framework was trained and validated using data from a full-scale water resource recovery facility. The imputed data from the optimized VAE, developed using the GA-based AutoML framework, is then used to train predictive models. Experimental evaluations demonstrate the effectiveness of the proposed approach over traditional imputation methods. The results reveal that the models can accurately predict key variables such as ammonia nitrogen (NH4-N), nitrate nitrogen (NO3-N), pH, and biogas flow rate, using imputed data. The scalability and adaptability of this framework make it valuable for real-time wastewater monitoring and predictive analytics.},
keywords = {},
pubstate = {published},
tppubtype = {article}
}
Missing data is a persistent challenge in wastewater analysis, often leading to biased results and reduced accuracy. This study introduces an innovative Automated Machine Learning (AutoML) framework that combines deep learning-based variational autoencoders (VAEs) and genetic algorithms (GAs) to address this issue. VAEs are employed to impute missing values by learning latent data representations, while GAs optimize the VAE architecture and hyperparameters, including the size of the latent space. The framework is specifically designed to handle the complex and nonlinear relationships in wastewater datasets. The framework was trained and validated using data from a full-scale water resource recovery facility. The imputed data from the optimized VAE, developed using the GA-based AutoML framework, is then used to train predictive models. Experimental evaluations demonstrate the effectiveness of the proposed approach over traditional imputation methods. The results reveal that the models can accurately predict key variables such as ammonia nitrogen (NH4-N), nitrate nitrogen (NO3-N), pH, and biogas flow rate, using imputed data. The scalability and adaptability of this framework make it valuable for real-time wastewater monitoring and predictive analytics.
3968.
Tran, Tony; Hu, Bin
FACETS: Efficient Once-for-all Object Detection via Constrained Iterative Search Technical Report
2025.
@techreport{tran2025facetsefficientonceforallobject,
title = {FACETS: Efficient Once-for-all Object Detection via Constrained Iterative Search},
author = {Tony Tran and Bin Hu},
url = {https://arxiv.org/abs/2503.21999},
year = {2025},
date = {2025-01-01},
urldate = {2025-01-01},
keywords = {},
pubstate = {published},
tppubtype = {techreport}
}
3967.
Abdennadher, Yesmine; Perin, Giovanni; Mazzieri, Riccardo; Pegoraro, Jacopo; Rossi, Michele
LightSNN: Lightweight Architecture Search for Sparse and Accurate Spiking Neural Networks Technical Report
2025.
@techreport{abdennadher2025lightsnnlightweightarchitecturesearch,
title = {LightSNN: Lightweight Architecture Search for Sparse and Accurate Spiking Neural Networks},
author = {Yesmine Abdennadher and Giovanni Perin and Riccardo Mazzieri and Jacopo Pegoraro and Michele Rossi},
url = {https://arxiv.org/abs/2503.21846},
year = {2025},
date = {2025-01-01},
urldate = {2025-01-01},
keywords = {},
pubstate = {published},
tppubtype = {techreport}
}
3966.
Poddenige, Deshani Geethika; Seneviratne, Sachith; Senanayake, Damith; Niranjan, Mahesan; Suganthan, PN; Halgamuge, Saman
Arch-LLM: Taming LLMs for Neural Architecture Generation via Unsupervised Discrete Representation Learning Technical Report
2025.
@techreport{poddenige2025archllmtamingllmsneural,
title = {Arch-LLM: Taming LLMs for Neural Architecture Generation via Unsupervised Discrete Representation Learning},
author = {Deshani Geethika Poddenige and Sachith Seneviratne and Damith Senanayake and Mahesan Niranjan and PN Suganthan and Saman Halgamuge},
url = {https://arxiv.org/abs/2503.22063},
year = {2025},
date = {2025-01-01},
urldate = {2025-01-01},
keywords = {},
pubstate = {published},
tppubtype = {techreport}
}