PDF(1244 KB)
PDF(1244 KB)
PDF(1244 KB)
基于PCN的水下认知网络动态频谱接入算法
Dynamic Spectrum Access Algorithm Based on PCN in Underwater Cognitive Network
水下网络可用频谱范围比较窄,且部分被水下生物占用,导致了水下传感器网络可用的频谱资源更为稀缺.针对上述问题,提出一种基于累积干扰预测(Predicted Cumulative Noise,PCN)的水下认知网络动态频谱接入算法.该算法把水下生物作为认知网络的主节点,水下传感器节点作为次节点;通过建立水下生物业务行为的马尔科夫模型预测累积干扰,次节点根据预测结果,采用合作的方式动态地接入授权频谱.仿真结果表明,该算法能够保护水下生物正常通信的同时,实现最优化的频谱共享,网络容量增益达到6.3dB.
The range of available spectrum in underwater sensor network is narrow;part of it is occupied by underwater creatures.Therefore,the available spectrum resources become scarcer.In view of this,the algorithm based on predicting cumulative noise in underwater cognitive networks to achieve dynamic spectrum accessing is proposed.The primary node is underwater biology;the secondary node is sensor node.The Markov model is established to predict noise in spectrum.The secondary nodes dynamically access the spectrum by cooperative method under the predicted states.The experiments verify that the algorithm realizes the optimization of spectrum sharing under protecting underwater creatures and improves the capacity gain 6.3dB.
马尔科夫模型 / 水下认知网络 / 频谱共享 / 水下生物 {{custom_keyword}} /
Markov model / underwater cognitive / spectrum sharing / underwater creatures {{custom_keyword}} /
[1] Yu Luo,Lina Pu,Michael Zaba.Challenges and opportunities of underwater cognitive acoustic networks[J]. IEEE Transactions on Emerging Topics in Computing,2014,2(2):1-13.
[2] 刘淞左,尹艳玲.一种利用海豚叫声的仿生水声通信方法[J]. 物理学报,2013,1(14):144303.1-144303.8.
[3] 高志伟,姚尧,等.基于漏洞严重程度分类的漏洞预测模型[[J]. 电子学报,2013,41(9):1784-1788. GAO Zhi-wei,YAO Yao,et al.Predicting model of vulnerabilities based on the type of vulnerability Severity[J]. Acta Electronica Sinica,2013,41(9):1784-1788.(in Chinese)
[4] Yiping Xing.Dynamic spectrum access in open spectrum wireless networks[J]. IEEE Journal on Selected Areas in Communications,2006,15(3):626-638.
[5] Xiangyun Zhou,Matthew R McKay,Behrouz Maham,Are Hjorungnes.Rethinking the secrecy outage formulation:A secure transmission design perspective[J]. IEEE Communications Letters,2011,24(3):302-304.
[6] M Kountouris,J G.Andrews.Downlink SDMA with limited feedback in interference-limited wireless networks[J]. Wireless Communications,IEEE Transactions on,2011,11(8):2730-2741.
[7] D Stoyan,W Kendall,J Mecke,WS Kendall,J Mecke.Stochastic Geometry and its Applications[M]. United Kingdom:John Wiley & Sons,2013.
[8] Zhong Zhou,Zheng Peng,Jun-hong Cui.Exploring random access and handshaking techniques in underwater wireless acoustic networks[J]. EURASIP Journal on Wireless Communications and Networking,2013,4(2):1-15.
[9] Dharma Agrawal,Qing-an Zeng.Introduction to Wireless and Mobile Systems[M]. United States:Cengage Learning,2011.
[10] B Chenand,D Pompili.A testbed for performance evaluation of underwater vehicle team formation and steering algorithms[A]. Sensor Mesh and Ad Hoc Communications and Networks (SECON)[C]. Boston,MA:IEEE,2010.1-3.
[11] Steven Weber,Andrews,J.G.The effect of fading,channel inversion and threshold scheduling on ad hoc networks[J]. IEEE Transactions on Information Theory,2007,53(11):4127-4149.
[12] M Franceschetti,P Minero.The capacity of wireless networks:information-theoretic and physical limits[J] IEEE Transactions on Information Theory,2009,55(8):4127-4149.
[13] Hesham ElSawy,Ekram Hossain,Sergio Camorlinga.Spectrum-efficient multi-channel design for coexisting IEEE 802.15.4 networks:A stochastic geometry approach[J]. IEEE Trans on Wireless Commun,2013,13(7):1611-1624.
[14] Songhai Li,Ding Wang,Kexiong Wang.Possible age-related hearing loss (presbycusis) and corresponding change in echolocation parameters in a stranded Indo-Pacific humpback dolphin[J]. The Journal of Experimental Biology,2013,216(22):4144-4153.
[15] Xiao Han,Jingwei Yin.Experimental demonstration of underwater acoustic communication using bionic signals[J]. Applied Acoustics,2014,78(4):7-10.
国家自然科学基金 (No.61162003); 青海省科技计划项目 (No.2012-ZR-2989); 海南省应用技术研究与开发专项项目 (No.ZDXM2014086); 广西高校科学技术研究项目 (No.ZD2014146)
/
| 〈 |
|
〉 |
