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Adaptive Packet Transmission in Smart Grid to Minimize the Message Delay

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Smart grid is a digital physical framework that incorporates power foundations with data innovations. To encourage proficient data trade, remote systems have been proposed to be broadly utilized as a part of the shrewd framework. In any case, the sticking assault that always telecasts radio obstruction is an essential security risk to keep the sending of remote systems in the keen network. Consequently, spread range frameworks, which give sticking versatility by means of numerous recurrence and code channels, must be adjusted to the keen network for secure remote correspondences, while in the meantime giving idleness surety to control messages. An open inquiry is the manner by which to minimize message delay for convenient savvy lattice correspondence under any potential sticking assault. To address this issue, we give a standard transformation from the case-by-case philosophy, which is generally utilized as a part of existing attempts to examine all around received assault models, to the most pessimistic scenario approach, which offers delay execution ensure for keen framework applications under any assault. At that point, we demonstrate that in all methodologies under the non specific process, the most pessimistic scenario message postponement is a U-formed capacity of system activity load. This demonstrates that, interestingly, expanding a decent measure of movement can truth be told enhance the worstcase delay execution. Accordingly, we show a lightweight yet encouraging framework, transmitting versatile disguise movement , to battle sticking assaults. Judgment minimizes the message delay by creating additional movement called cover to adjust the system load at the ideal. Trials demonstrate that TACT can diminish the likelihood that a message is not conveyed on time all together of extent.
Keywords:Smart Grid, Message Delay, Worstcase Delay, TACT.


  1. Zhuo Lu, Wenye Wang, Cliff Wang,” Camouflage Traffic: Minimizing Message Delay for Smart Grid Applications under Jamming ,”in proc. IEEE transactions on dependable and secure computing, vol. 12, no. 1, January/February 2015.
  2. Akyol .B, Kirkham .H, Clements .S, and Hadley .M, “A survey of wireless communications for the electric power system,” in Tech. Rep., Richland, WA, USA, Pacific Northwest Nat. Laboratory,PNNL-19084, Jan. 2010.
  3. Bayraktaroglu .E, King .C, Liu .X, Noubir .G, Rajaraman .R, and Thapa .B, “On the performance of IEEE 802.11 under jamming,” in Proc. IEEE IEEE Conf. Comput. Commun., pp. 1265–1273, Apr. 2008.
  4. Brinkmeier .M, Schafer .G, and Strufe .T, “Optimally DoS resistant P2P topologies for live multimedia streaming,” IEEE Trans. Parallel Distrib. Syst., vol. 20, no. 6, pp. 831–844, Jun. 2009.
  5. Cleveland .F, “Uses of wireless communications to enhance power system reliability,” in Proc. IEEE Power Eng. Soc. Gen. Meeting, p. 1, Jun. 2007.
  6. El-Khattam .W, Sidhu .T .S, and Seethapathy .R, “Evaluation of two anti-islanding schemes for a radial distribution system equipped with self-excited induction generator wind turbines,”
  7. Guidelines for Smart Grid Cyber Security, NIST IR-7628, NIST Smart Grid Cyber Security Working Group, vol. 1-3, Aug. 2010.
  8. Li .H, Lai .L, and Qiu .R .C, “A denial-of-service jamming game for remote state monitoring in smart grid,” in Proc. 45th Annu. Conf. Inf. Sci. Syst., pp. 1–6, Mar. 2011.
  9. Liu .Y, Ning .P, Dai .H, and Liu .A, “Randomized differential DSSS: Jamming-resistant wireless broadcast communication,” in Proc. IEEE IEEE Conf. Comput. Commun., pp. 1–9. Mar. 2010.