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| Main Authors: | , , , , , , , , |
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| Format: | Preprint |
| Published: |
2024
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| Subjects: | |
| Online Access: | https://arxiv.org/abs/2501.06194 |
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| _version_ | 1866912184038064128 |
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| author | Yousefi, Davoud Yari, Hassan Osouli, Farzad Ebrahimi, Mohammad Esmalifalak, Somayeh Johari, Morteza Azarnezhad, Abbas Sadeghi, Fatemeh Mirzapour, Rogayeh |
| author_facet | Yousefi, Davoud Yari, Hassan Osouli, Farzad Ebrahimi, Mohammad Esmalifalak, Somayeh Johari, Morteza Azarnezhad, Abbas Sadeghi, Fatemeh Mirzapour, Rogayeh |
| contents | Nowadays, the use of soft computational techniques in power systems under the umbrella of machine learning is increasing with good reception. In this paper, we first present a deep learning approach to find the optimal configuration for HetNet systems. We used a very large number of radial configurations of a test system for training purposes. We also studied the issue of joint carrier/power allocation in multilayer hierarchical networks, in addition to ensuring the quality of experience for all subscribers, to achieve optimal power efficiency. The proposed method uses an adaptive load equilibrium model that aims to achieve "almost optimal" equity among all servers from the standpoint of the key performance indicator. Unlike current model-based energy efficiency methods, we propose a joint resource allocation, energy efficiency, and flow control algorithm to solve common nonconvex and hierarchical optimization problems. Also, by referring to the allocation of continuous resources based on SLA, we extended the proposed algorithm to common flow/power control and operational power optimization algorithm to achieve optimal energy efficiency along with ensuring user's throughput limitations. Also, simulation results show that the proposed controlled power/flow optimization approach can significantly increase energy efficiency compared to conventional designs using network topology adjustment capability. |
| format | Preprint |
| id |
arxiv_https___arxiv_org_abs_2501_06194 |
| institution | arXiv |
| publishDate | 2024 |
| record_format | arxiv |
| spellingShingle | Energy Efficient Computation Offloading and Virtual Connection Control in Uplink Small Cell Networks Yousefi, Davoud Yari, Hassan Osouli, Farzad Ebrahimi, Mohammad Esmalifalak, Somayeh Johari, Morteza Azarnezhad, Abbas Sadeghi, Fatemeh Mirzapour, Rogayeh Networking and Internet Architecture Nowadays, the use of soft computational techniques in power systems under the umbrella of machine learning is increasing with good reception. In this paper, we first present a deep learning approach to find the optimal configuration for HetNet systems. We used a very large number of radial configurations of a test system for training purposes. We also studied the issue of joint carrier/power allocation in multilayer hierarchical networks, in addition to ensuring the quality of experience for all subscribers, to achieve optimal power efficiency. The proposed method uses an adaptive load equilibrium model that aims to achieve "almost optimal" equity among all servers from the standpoint of the key performance indicator. Unlike current model-based energy efficiency methods, we propose a joint resource allocation, energy efficiency, and flow control algorithm to solve common nonconvex and hierarchical optimization problems. Also, by referring to the allocation of continuous resources based on SLA, we extended the proposed algorithm to common flow/power control and operational power optimization algorithm to achieve optimal energy efficiency along with ensuring user's throughput limitations. Also, simulation results show that the proposed controlled power/flow optimization approach can significantly increase energy efficiency compared to conventional designs using network topology adjustment capability. |
| title | Energy Efficient Computation Offloading and Virtual Connection Control in Uplink Small Cell Networks |
| topic | Networking and Internet Architecture |
| url | https://arxiv.org/abs/2501.06194 |