| 1 |
李冲, 杜秀娟, 王丽娟, 等. 基于异常检测和AUV辅助的水下传感器网络可靠节能路由协议[J]. 通信学报, 2025, 46 (1): 222- 238.
|
|
LI C, DU X J, WANG L J, et al. Reliable energy-efficient routing protocol based on anomalous detection and AUV-aid for underwater sensor networks[J]. Journal of Communications, 2025, 46 (1): 222- 238.
|
| 2 |
MEI H D, WANG H Y, SHEN X H, et al. An adaptive routing protocol for underwater acoustic sensor networks with ocean current[J]. IEEE Sensors Journal, 2023, 23 (22): 28220- 28243.
doi: 10.1109/JSEN.2023.3318974
|
| 3 |
JIANG S M. On securing underwater acoustic networks: a survey[J]. IEEE Communications Surveys and Tutorials, 2019, 21 (1): 729- 752.
doi: 10.1109/COMST.2018.2864127
|
| 4 |
赵珍. 高质量发展下舟山海洋资源环境承载力评价与提升[J]. 浙江海洋大学学报 (人文科学版), 2022, 39, 29- 38.
|
|
ZHAO Z. Evaluation and enhancement of the marine resource and environmental carrying capacity in Zhoushan under high-quality development[J]. Journal of Zhejiang Ocean University (Humanities Edition), 2022, 39, 29- 38.
|
| 5 |
WEI X H, GUO H, WANG X W, et al. Reliable data collection techniques in underwater wireless sensor networks: a survey[J]. IEEE Communications Surveys & Tutorials, 2022, 24 (1): 404- 431.
|
| 6 |
COUTINHO R W L, BOUKERCHE A, VIEIRA L F M, et al. Underwater sensor networks for smart disaster management[J]. IEEE Consumer Electronics Magazine, 2020, 9 (2): 107- 114.
doi: 10.1109/MCE.2019.2953686
|
| 7 |
金志刚, 冀智华, 苏毅珊. 基于深度可调节节点的水声网络部署优化算法[J]. 系统工程与电子技术, 2019, 41 (1): 203- 207.
|
|
JIN Z G, JI Z H, SU Y S. Deployment optimization algorithm for underwater acoustic networks based on depth-adjustable nodes[J]. Systems Engineering and Electronics, 2019, 41 (1): 203- 207.
|
| 8 |
SUDHIR A C H, RAM G S P, RAGHAVA A S, et al. Efficient topology control and depth adjustment technique for connectivity in UWSN[C]//Proc. of the 4th International Conference on Pervasive Computing and Social Networking, 2024: 592–596.
|
| 9 |
HAYDER I A, KHAN S N, ALTHOBIANI F, et al. Towards controlled transmission: a novel power-based sparsity- aware and energy-efficient clustering for underwater sensor networks in marine transport safety[J]. Electronics, 2021, 10 (7): 854.
doi: 10.3390/electronics10070854
|
| 10 |
SHOVON I I, SHIN S. Survey on multi-path routing protocols of underwater wireless sensor networks: advancement and applications[J]. Electronics, 2022, 11 (21): 3467- 3506.
doi: 10.3390/electronics11213467
|
| 11 |
DEMIM F, BOUGUESSA R, ROUIGUEB A, et al. A systematic overview of underwater wireless sensor networks: applications, challenge and research perspectives[J]. Journal of Computer Science Research, 2023, 5 (2): 52- 77.
doi: 10.30564/jcsr.v5i2.5478
|
| 12 |
PACHOURI V, KATHURIA S, GEHLOT A, et al. UWSN with technological intervention: benefits and challenges [C]//Proc. of the International Conference on Sustainable Computing and Data Communication Systems , 2023: 1514−1519.
|
| 13 |
HAO L J, AO J, MA C B. Survey on underwater wireless communication technology [C]//Proc. of the Cross Strait Radio Science and Wireless Technology Conference, 2023.
|
| 14 |
AHMED M, SALLEH M, CHANNA M I. Routing protocols based on node mobility for underwater wireless sensor network (UWSN): a survey[J]. Journal of Network and Computer Applications, 2017, 78, 242- 252.
doi: 10.1016/j.jnca.2016.10.022
|
| 15 |
ALQAHTANI G J, BOUABDALLAH F. Routing protocols based on node selection for freely floating underwater wireless sensor networks: a survey[J]. EURASIP Journal on Wireless Communications and Networking, 2023, 2023, 117.
doi: 10.1186/s13638-023-02324-6
|
| 16 |
XIE P, CUI J H, LAO L. VBF: vector-based forwarding protocol for underwater sensor networks[C]//Proc. of the Networking Technologies, Services, and Protocols; Performance of Computer and Communication Networks; Mobile and Wireless Communications Systems, 2006.
|
| 17 |
金志刚, 洪叶, 苏毅珊, 等. 软件定义云边协同架构下的水下监测新机制[J]. 系统工程与电子技术, 2024, 46 (3): 1101- 1108.
|
|
JIN Z G, HONG Y, SU Y S, et al. New mechanism for underwater monitoring in a software-defined cloud-edge collaborative architecture[J]. Systems Engineering and Electronics, 2024, 46 (3): 1101- 1108.
|
| 18 |
NICOLAOU N, SEE A, XIE P, et al. Improving the robustness of location-based routing for underwater sensor Networks[C]// Proc. of the OCEANS Europe Conference, 2007.
|
| 19 |
YAN H, SHI Z J, CUI J H. DBR: depth-based routing for underwater sensor networks [C]// Proc. of the Ad Hoc and Sensor Networks, Wireless Networks, Next Generation Internet, 2008: 72−86.
|
| 20 |
NOH Y, LEE U, WANG P, et al. VAPR: void-aware pressure routing for underwater sensor networks[J]. IEEE Trans. on Mobile Computing, 2012, 12 (5): 895- 908.
|
| 21 |
HU T S, FEI Y S. QELAR: a machine-learning-based adaptive routing protocol for energy-efficient and lifetime-extended underwater sensor networks[J]. IEEE Trans. on Mobile Computing, 2010, 9 (6): 796- 809.
doi: 10.1109/TMC.2010.28
|
| 22 |
SHEN Z W, YIN H X, JING L Y, et al. A cooperative routing protocol based on q-learning for underwater optical-acoustic hybrid wireless sensor networks[J]. IEEE Sensors Journal, 2021, 22 (1): 1041- 1050.
|
| 23 |
BASAGNI S, DI VALERIO V, GJANCI P, et al. Harnessing hydro: harvesting-aware data routing for underwater wireless sensor networks [C]//Proc. of the 18th ACM International Symposium on Mobile Ad Hoc Networking and Computing, 2018: 271−279.
|
| 24 |
ZHU R X, JIANG Q H, HUANG X D, et al. A reinforcement-learning-based opportunistic routing protocol for energy-efficient and void-avoided UASNs[J]. IEEE Sensors Journal, 2022, 22 (13): 13589- 13601.
doi: 10.1109/JSEN.2022.3175994
|
| 25 |
SREERAJ A, VIJAYALAKSHMI P, RAJENDRAN V. A deep learning enabled software-defined radio based routing protocol for underwater acoustic sensor networks[C]//Proc. of the International Conference on Sustainable Computing and Data Communication Systems, 2022: 28−32.
|
| 26 |
GAO J, WANG J J, GU J L, et al. Q-learning-based routing optimization algorithm for underwater sensor networks[J]. IEEE Internet of Things Journal, 2024, 11 (22): 36350- 36357.
doi: 10.1109/JIOT.2024.3398797
|
| 27 |
WANG C, SHEN X H, WANG H Y, et al. Reinforcement learning-based opportunistic routing protocol using depth information for energy-efficient underwater wireless sensor networks[J]. IEEE Sensors Journal, 2023, 23 (15): 17771- 17783.
doi: 10.1109/JSEN.2023.3285751
|
| 28 |
THORP W H. Analytic description of the low-frequency attenuation coefficient[J]. The Journal of the Acoustical Society of America, 1967, 42 (1): 270- 270.
|
| 29 |
KHAN S U, KHAN Z U, ALKHOWAITER M, et al. Energy-efficient routing protocols for UWSNs: a comprehensive review of taxonomy, challenges, opportunities, future research directions, and machine learning perspectives[J]. Journal of King Saud University-Computer and Information Sciences, 2024, 36 (7): 102128.
|
| 30 |
CHEN D Z, VARSHNEY P K. A survey of void handling techniques for geographic routing in wireless networks[J]. IEEE Communications Surveys & Tutorials, 2007, 9 (1): 50- 67.
|
| 31 |
GUPTA S, SINGH N P. Underwater wireless sensor networks: a review of routing protocols, taxonomy, and future directions[J]. The Journal of Supercomputing, 2024, 80 (4): 5163- 5196.
doi: 10.1007/s11227-023-05646-w
|
| 32 |
韦正现, 宋敏, 印桂生, 等. 水下无线传感器网络能力分析与评估方法[J]. 哈尔滨工程大学学报, 2017, 38 (10): 1531- 1538.
|
|
WEI Z X, SONG M, YIN G S, et al. Capability analysis and evaluation methods of underwater wireless sensor network[J]. Journal of Harbin Engineering University, 2017, 38 (10): 1531- 1538.
|