Securing First-Hop Data Provenance for Bodyworn Devices Using Wireless Link Fingerprints

Ali, Syed Taha; Sivaraman, Vijay; Ostry, Diethelm; Tsudik, Gene; Jha, Sanjay

doi:10.1109/tifs.2014.2357998

Cited by 29 publications

(19 citation statements)

References 42 publications

(46 reference statements)

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“…The projected solution has mitigated time complexity contrasted with other best resolutions. The power computations are exhibited too demonstrating alluring outcomes when contrasted with the previously existed work in [7].…”

Section: Introductionmentioning

confidence: 77%

“…Besides, the power benchmarks of MICAz bits utilized in the literature are connected to the displayed protocols. The energy utilization for AES-128 encryption (128 bits), SHA-1 Hash (64 bits), ECDSA-160 Sign and Transmit 1 part are 1.83 J, 154 J, 52 J and 0.6 J individually [7]. As the decrypting is completed at the server, the power figurings are not accomplished for the server.…”

Section: Results Analysis A) Adversarial Node Detectionmentioning

confidence: 99%

“…2) IoT nodes provide few bytes as headers to the payload which comprises of encrypted link -fingerprints. Table 4 and 5 discloses the power exploitation at each node level when the packet is transmitted from IoT node 1 to IoT node 3 through IoT node 1 according to the hash data and session identifiers as part of protocols used conventionally in [7]. Table 4: Energy consumption at IoT node level for link fingerprints transmission to the server Table 5: Energy consumption at IoT node level for data provenance protocol…”

Section: Results Analysis A) Adversarial Node Detectionmentioning

confidence: 99%

“…Both the physical and social layer data are consolidated for acknowledging fast content spread in gadget to-gadget vehicle-to-vehicle (D2D-V2V)-based IoV systems. In [7] paper, verifying the data provenance is accomplished by utilizing the RSSI values gotten by a static base station and a versatile body-worn gadget. Performed investigations demonstrate that exceptionally associated fingerprints are obtained.…”

Section: Related Workmentioning

confidence: 99%

See 3 more Smart Citations

Implementation of Link Fingerprint Verification and Data Provenance using RSSI

Venkateswarlu*,

Maheswari

2019

IJITEE

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Due to constrained assets and adaptability, security protocol for Internet of Things (IoT) should be light-weighted. The cryptographic solutions are not possible to apply on little and low-power devices of IoT in view of their power and space impediments. In this paper, a light-weight protocol to verify the information and accomplishing information provenance is introduced for multi-hop IoT arrange. The Received Signal Strength Indicator (RSSI) of conveying IoT nodes are utilized to produce the connection fingerprints. The connection fingerprints are coordinated at the server to process the relationship coefficient. Higher the estimation of connection coefficient, higher the rates of verified information move. Lower worth gives the recognition of ill-disposed node in the middle of a particular connection. Information provenance has additionally been accomplished by examination of pocket header with all the accessible connection fingerprints at the server. The time unpredictability is processed at the node and server level, which is O(1). The power scattering is determined for IoT nodes and overall network. The outcomes demonstrate that the power utilization of the framework and time complexity. Exploratory outcomes show that up to 97% connection is accomplished when no attacker node is available in the IoT network.

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Section: Introductionmentioning

confidence: 77%

Section: Results Analysis A) Adversarial Node Detectionmentioning

confidence: 99%

Section: Results Analysis A) Adversarial Node Detectionmentioning

confidence: 99%

Section: Related Workmentioning

confidence: 99%

See 2 more Smart Citations

Implementation of Link Fingerprint Verification and Data Provenance using RSSI

Venkateswarlu*,

Maheswari

2019

IJITEE

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“…Thanks to a relatively high stationarity of on-body channels, a reasonable probability of radio-frequency fingerprinting identification can be reached. 13 The authentication scheme based on radio-frequency fingerprints can be understood as a special case of the scene analysis. During the calibration phase, fingerprints of electromagnetic scene are collected.…”

Section: Introductionmentioning

confidence: 99%

Physical layer authentication of off‐body channels by probabilistic neural networks

Raida

2019

Int J Numerical Modelling

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A probabilistic neural network (PNN) for the authentication of an off‐body channel of a wireless body area network is discussed in this paper. The off‐body channel is authenticated by radio‐frequency fingerprints of on‐body channels. Thanks to a relatively high stationarity of on‐body channels, a reasonable probability of radio‐frequency fingerprinting identification is reached. Radio‐frequency fingerprints are used to train a probabilistic neural network playing the role of an authentication key. The authentication process can be efficiently controlled by setting tolerance zones of the network. Functionality of the concept was proven by computer simulations.

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A comprehensive survey of physical layer security over fading channels: Classifications, applications, and challenges

Yadav

Kumar²,

Kumar

2021

Trans Emerging Tel Tech

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Due to the open nature of wireless communication systems, the data transmission over these networks are vulnerable to malicious attack. To safeguard the transmitted data, physical layer security (PLS) has been emerged as a promising technique because of its unique feature of utilizing randomness of the wireless channel to secure the information. The preeminent idea of utilizing the channel imperfections such as fading and noise into the security providing resource is the basic approach behind PLS. For exploiting the randomness of the propagation medium, the analysis of the secrecy performance over the fading channel is of utmost importance. With the explanation of basic theory and technology, this paper presents an elaborated survey on the PLS research over the fading channels. To exploit the performance gains, we discuss the optimization approaches in different network design problems, for example, secrecy rate maximization, power minimization, and secure energy efficiency problems. We present a comparative study of the expressions of various performance metrics of the PLS along with classification depending upon the channel state information of the eavesdropper. The application and challenges of the PLS in the emerging wireless technologies are also reviewed and discussed. This paper incorporates almost all the aspects of PLS implemented over the fading channels. Furthermore, the paper is concluded with open research directions for the PLS system in various fields that can be explored to design a flexible and robust security system to satisfy the security requirements of the next‐generation networks.

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Securing First-Hop Data Provenance for Bodyworn Devices Using Wireless Link Fingerprints

Cited by 29 publications

References 42 publications

Implementation of Link Fingerprint Verification and Data Provenance using RSSI

Implementation of Link Fingerprint Verification and Data Provenance using RSSI

Physical layer authentication of off‐body channels by probabilistic neural networks

A comprehensive survey of physical layer security over fading channels: Classifications, applications, and challenges

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