Design of Remote Power Management and Control Solution in IoT Device Environment
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https://doi.org/10.14419/ijet.v7i3.24.22653 -
Remote power management, Power control, IoT Environment, Out bound method, WOL function. -
Abstract
Background/Objectives: The existing remote power management and control solution is controlled from the outside through the internal router. That is, if there is an internal firewall, the access path is limited due to complicated network setting. In other words, there is a problem that connection can be limited because the hub server and the public IP address are required to access from the outside.
Methods/Statistical analysis: There is a need for a way to build a remote control and power management system on the remote device itself. Thereby, the user does not need any additional setting for power management or control to the remote device. That is, there is a need for a remote power management and control solution capable of freely controlling power and control remotely in the Internet environment even if a firewall exists inside.
Findings: In this paper, we manage and control the power of the target terminal remotely from the client terminal to the target terminal via the main server and the hub server. In addition, in the internal firewall environment, a remote terminal requests power to the target terminal via the server. Finally, the remote connection of the target terminal can be wired/wireless in the hub server, and the corresponding function is installed by installing separate hardware in the target terminal.
Improvements/Applications: In this paper, we design a solution to remotely manage and control power in IoT device environment. This enables the development of a system that can reduce the energy efficiency of remote devices and eliminate standby power. It is a technology that provides a fundamental solution for remote power management in IoT environment by allowing users to turn on / off the computer or device at any time and remotely manage it.
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References
[1] Massey T, Marfia G, Stoelting A, Tomasi R, Spirito MA, Sarrafzadeh M, Pau G, Leveraging social system networks in ubiquitous high-data-rate health systems. IEEE Trans InfTechnol Biomed. 2011; 15(3):491–498.
[2] Patel M, Wang J, Applications, challenges, and prospective in emerging body area networking technologies. IEEE WirelCommun. 2010; 17(1):80–88.
[3] Hawa M, Rahhal JS, Abu-Al-Nadi DI, File size models for shared content over the BitTorrent Peer-to-Peer network. Peer-to-Peer Netw Appl. 2012; 5(3):279–291.
[4] Cherif A, Imine A, Rusinowitch M, Practical access control management for distributed collaborative editors. Pervasive Mob Comput. 2014; 15:62–86.
[5] Fernando N, Loke SW, Rahayu W, Mobile cloud computing: a survey. Future GenerComput Syst. 2013; 29(1):84–106.
[6] Wang K, Wang Y, Hu X, Sun Y, Deng D-J, Vinel A, Zhang Y, Wireless big data computing in smart grid. IEEE WirelCommun. 2017; 24:58–64.
[7] Kim JY, Kim KH, Jo SH, Moon MK, A measuring system of near surrounding fine dust concentration. Proc Korean SocComputInf Conf. 2015; 23(2):91–92.
[8] Zhao Y, Wang S, Lang L, Huang C, Ma W, & Lin H, Ambient fine and coarse particulate matter pollution and respiratory morbidity in Dongguan China. Environ Pollut. 2017; 222:126–131.
[9] Li S, Xu L, Wang X, Compressed sensing signal and data acquisition in wireless sensor networks and internet of things. IEEE Trans IndInformat. 2013; 9(4):2177–186.
[10] Zhang R, Wang M, Cai LX, Zheng Z, Shen X, LTE-Unlicensed: the future of spectrum aggregation for cellular networks. IEEE WirelCommun. 2015; 22(3):150–159.
[11] Phunchongharn P, Hossain E, Kim DI, Resource allocation for device-to-device communications underlaying LTE-advanced networks. IEEE Wireless Magazine. 2013; 20(4):91–100.
[12] Yu CH, Doppler K, Ribeiro CB, Tirkkonen O, Resource sharing optimization for device-to-device communication underlaying cellular networks. IEEE Trans WirelCommun. 2011; 10(8):2752–2763.
[13] Lin X, Andrews JG, Ghosh A, Ratasuk R, An overview of 3GPP device-to-device proximity services. IEEE Commun Mag. 2014; 52(4):40–48.
[14] Gupta BK, Patnaik S, Mallick MK, Nayak AK, Dynamic routing algorithm in wireless mesh network. International Journal of Grid and Utility Computing. 2017; 8(1):53–60.
[15] Diego Suárez Touceda, José M. Sierra Cámara, Miguel Soriano, Decentralized certification scheme for secure admission in on-the-fly peer-to-peer systems. Peer-to-Peer Netw Appl. 2012; 5(2):105-124.
[16] Nallapaneni Manoj Kumar, Pradeep Kumar Mallick,†The Internet of Things: Insights into the building blocks, component interactions, and architecture layersâ€, Elsevier Procedia Computer Science Journal , Volume 132, Pages 109-117, 2018, ISSN:1877-0509, UGC Sl No: 46138 and 48229 DOI: https://doi.org/10.1016/j.procs.2018.05.170
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How to Cite
Kim, B.-H., & ., . (2018). Design of Remote Power Management and Control Solution in IoT Device Environment. International Journal of Engineering & Technology, 7(3.24), 237-240. https://doi.org/10.14419/ijet.v7i3.24.22653Received date: 2018-12-01
Accepted date: 2018-12-01