An efficient privacy-aware split learning framework for satellite communications
In the rapidly evolving domain of satellite communications, integrating advanced machine learning techniques, particularly split learning, is crucial for enhancing data processing and model training efficiency across satellites, space stations, and ground stations. Traditional ML approaches often fa...
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sg-ntu-dr.10356-1810392024-11-12T02:39:17Z An efficient privacy-aware split learning framework for satellite communications Sun, Jianfei Wu, Cong Mumtaz, Shahid Tao, Junyi Cao, Mingsheng Wang, Mei Frascolla, Valerio School of Computer Science and Engineering Computer and Information Science Satellite communication Split learning, In the rapidly evolving domain of satellite communications, integrating advanced machine learning techniques, particularly split learning, is crucial for enhancing data processing and model training efficiency across satellites, space stations, and ground stations. Traditional ML approaches often face significant challenges within satellite networks due to constraints such as limited bandwidth and computational resources. To address this gap, we propose a novel framework for more efficient SL in satellite communications. Our approach, Dynamic Topology-Informed Pruning, namely DTIP, combines differential privacy with graph and model pruning to optimize graph neural networks for distributed learning. DTIP strategically applies differential privacy to raw graph data and prunes GNNs, thereby optimizing both model size and communication load across network tiers. Extensive experiments across diverse datasets demonstrate DTIP's efficacy in enhancing privacy, accuracy, and computational efficiency. Specifically, on Amazon2M dataset, DTIP maintains an accuracy of 0.82 while achieving a 50% reduction in floating-point operations per second. Similarly, on ArXiv dataset, DTIP achieves an accuracy of 0.85 under comparable conditions. Our framework not only significantly improves the operational efficiency of satellite communications but also establishes a new benchmark in privacy-aware distributed learning, potentially revolutionizing data handling in space-based networks. This work was partly supported by National Natural Science Foundation of China No. 62002047. 2024-11-12T02:39:16Z 2024-11-12T02:39:16Z 2024 Journal Article Sun, J., Wu, C., Mumtaz, S., Tao, J., Cao, M., Wang, M. & Frascolla, V. (2024). An efficient privacy-aware split learning framework for satellite communications. IEEE Journal On Selected Areas in Communications, 3459027-. https://dx.doi.org/10.1109/JSAC.2024.3459027 0733-8716 https://hdl.handle.net/10356/181039 10.1109/JSAC.2024.3459027 2-s2.0-85204444078 3459027 en IEEE Journal on Selected Areas in Communications © 2024 IEEE. All rights reserved. |
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Computer and Information Science Satellite communication Split learning, |
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Computer and Information Science Satellite communication Split learning, Sun, Jianfei Wu, Cong Mumtaz, Shahid Tao, Junyi Cao, Mingsheng Wang, Mei Frascolla, Valerio An efficient privacy-aware split learning framework for satellite communications |
| description |
In the rapidly evolving domain of satellite communications, integrating advanced machine learning techniques, particularly split learning, is crucial for enhancing data processing and model training efficiency across satellites, space stations, and ground stations. Traditional ML approaches often face significant challenges within satellite networks due to constraints such as limited bandwidth and computational resources. To address this gap, we propose a novel framework for more efficient SL in satellite communications. Our approach, Dynamic Topology-Informed Pruning, namely DTIP, combines differential privacy with graph and model pruning to optimize graph neural networks for distributed learning. DTIP strategically applies differential privacy to raw graph data and prunes GNNs, thereby optimizing both model size and communication load across network tiers. Extensive experiments across diverse datasets demonstrate DTIP's efficacy in enhancing privacy, accuracy, and computational efficiency. Specifically, on Amazon2M dataset, DTIP maintains an accuracy of 0.82 while achieving a 50% reduction in floating-point operations per second. Similarly, on ArXiv dataset, DTIP achieves an accuracy of 0.85 under comparable conditions. Our framework not only significantly improves the operational efficiency of satellite communications but also establishes a new benchmark in privacy-aware distributed learning, potentially revolutionizing data handling in space-based networks. |
| author2 |
School of Computer Science and Engineering |
| author_facet |
School of Computer Science and Engineering Sun, Jianfei Wu, Cong Mumtaz, Shahid Tao, Junyi Cao, Mingsheng Wang, Mei Frascolla, Valerio |
| format |
Article |
| author |
Sun, Jianfei Wu, Cong Mumtaz, Shahid Tao, Junyi Cao, Mingsheng Wang, Mei Frascolla, Valerio |
| author_sort |
Sun, Jianfei |
| title |
An efficient privacy-aware split learning framework for satellite communications |
| title_short |
An efficient privacy-aware split learning framework for satellite communications |
| title_full |
An efficient privacy-aware split learning framework for satellite communications |
| title_fullStr |
An efficient privacy-aware split learning framework for satellite communications |
| title_full_unstemmed |
An efficient privacy-aware split learning framework for satellite communications |
| title_sort |
efficient privacy-aware split learning framework for satellite communications |
| publishDate |
2024 |
| url |
https://hdl.handle.net/10356/181039 |
| _version_ |
1816859050427547648 |