Conservation of Energy in Wireless Sensor Network by Preventing Denial of Sleep Attack

Naik, Swapna; Shekokar, Narendra

doi:10.1016/j.procs.2015.03.164

Cited by 23 publications

(15 citation statements)

References 20 publications

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“…The authors of [30] [31], [32], [33], [34]. developed allows the values from all leaves to be stored outside the memory space which is regarded as a resource intensive and inefficient process [37].…”

Section: Related Workmentioning

confidence: 99%

Non-interactive zero knowledge proofs for the authentication of IoT devices in reduced connectivity environments

et al. 2019

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Section: Related Workmentioning

confidence: 99%

Non-interactive zero knowledge proofs for the authentication of IoT devices in reduced connectivity environments

et al. 2019

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“…Experimental results proved that the suggested method was optimal for defending the attacker from performing the task. Naik and Shekokar [12] addressed the denial-of-sleep attack using zero knowledge protocol and interlock protocol. Experimental results proved that the suggested protocols prevented the replay attack and man-in-the-middle attack and also minimized the resource consumption.…”

Section: Detection Of Dos Attacks In Wsnmentioning

confidence: 99%

GA-DoSLD: Genetic Algorithm Based Denial-of-Sleep Attack Detection in WSN

Gunasekaran¹,

Periakaruppan²

2017

Security and Communication Networks

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Denial-of-sleep (DoSL) attack is a special category of denial-of-service attack that prevents the battery powered sensor nodes from going into the sleep mode, thus affecting the network performance. The existing schemes used for the DoSL attack detection do not provide an optimal energy conservation and key pairing operation. Hence, in this paper, an efficient Genetic Algorithm (GA) based denial-of-sleep attack detection (GA-DoSLD) algorithm is suggested for analyzing the misbehaviors of the nodes. The suggested algorithm implements a Modified-RSA (MRSA) algorithm in the base station (BS) for generating and distributing the key pair among the sensor nodes. Before sending/receiving the packets, the sensor nodes determine the optimal route using Ad Hoc On-Demand Distance Vector Routing (AODV) protocol and then ensure the trustworthiness of the relay node using the fitness calculation. The crossover and mutation operations detect and analyze the methods that the attackers use for implementing the attack. On determining an attacker node, the BS broadcasts the blocked information to all the other sensor nodes in the network. Simulation results prove that the suggested algorithm is optimal compared to the existing algorithms such as X-MAC, ZKP, and TE2P schemes.

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“…Denial-of-Sleep (DoS) attacks consist in exhausting the batteries of the devices by increasing their duty cycle. By forcing nodes to awake at unnecessary times or by inducing additional duty (e.g., listening, retransmissions), these attacks aim at reducing the expected lifetime of the constituted IoT network [7]. Detecting abnormal uses of highly energy-consuming tasks (e.g., idle listening, overhearing, retransmissions) yet remains challenging [8].…”

Section: Introductionmentioning

confidence: 99%

Denial-of-Sleep Attacks against IoT Networks

Gallais

Hedli

Loscrì

et al. 2019

2019 6th International Conference on Control, Decision and Information Technologies (CoDIT)

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Numerous medium access control (MAC) have been proposed for Low-power Lossy Networks (LLNs) over the recent years. They aim at ensuring both energy efficiency and robustness of the communication transmissions. Nowadays, we observe deployments of LLNs for potentially critical application scenarios (e.g., plant monitoring, building automation), which require both determinism and security guarantees. They involve battery-powered devices which communicate over lossy wireless links. Radio interfaces are turned off by a node as soon as no traffic is to be sent or relayed. Denial-of-sleep attacks consist in exhausting the devices by forcing them to keep their radio on. We here focus on jamming attacks whose impact can be mitigated by approaches such as time-division and channel hopping techniques. We use the IEEE 802.15.4e standard to show that such approaches manage to be resistant to basic jamming but yet remain vulnerable to selective jamming. We discuss the potential impacts of such onslaughts, depending on the knowledge gained by the attacker, and to what extent envisioned protections may allow jamming attacks to be handled at upper layers.

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Conservation of Energy in Wireless Sensor Network by Preventing Denial of Sleep Attack

Cited by 23 publications

References 20 publications

Non-interactive zero knowledge proofs for the authentication of IoT devices in reduced connectivity environments

Non-interactive zero knowledge proofs for the authentication of IoT devices in reduced connectivity environments

GA-DoSLD: Genetic Algorithm Based Denial-of-Sleep Attack Detection in WSN

Denial-of-Sleep Attacks against IoT Networks

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