A provably secure sharding based blockchain smart contract centric hierarchical group key agreement for large wireless ad‐hoc networks

Naresh, Vankamamidi S.; Allavarpu, V. V. L. Divakar; Reddi, Sivaranjani; Murty, Pilla Sita Rama; Raju, N.V.S. Lakshmipathi; Mohan, R.

doi:10.1002/cpe.6553

Cited by 9 publications

(5 citation statements)

References 31 publications

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“…For intelligent Internet of Things (IoT) systems, Zhang et al [19] created the GKA protocol, which enabled a rational terminal to form a group key with a threshold requirement. Sharding and blockchain technologies were integrated into GKA by Naresh et al [20] to reduce the computational and communication costs of the group controller. The group has been distributed into the r subgroup, which was used to generate the hierarchical group keys.…”

Section: Related Work On Group Shared Keymentioning

confidence: 99%

“…The previous literature studies [10][11][12][13][14][15][16][17][18][19][20][21][22][23][24][25][26] had several limitations, which can be specified in three facts: Firstly, the group key agreements that were reviewed in the related works were required to broadcast and exchange many messages between the controller and the group members, which might have exposed the group shared key (GSK) and increased the communication and computation costs. Second, some protocols did not consider the group member authentication and message integrity, thereby facilitating the MITM attack.…”

Section: Related Work On Group Shared Keymentioning

confidence: 99%

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An Authenticated Group Shared Key Mechanism Based on a Combiner for Hash Functions over the Industrial Internet of Things

Ali

Ahmed

2023

Processes

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The Industrial Internet of Things (IIoT) provides internet connectivity for instruments, digital machines, and any other manufactured object to enable intelligent industrial operations to achieve high productivity. Securing communications between IIoT devices remains a critical and challenging issue due to the resource-constrained and processing capabilities of sensing devices. Moreover, the traditional group shared key might implement complex mathematical operations that are not suitable for the limited recourse capability of the IIoT device. Furthermore, the standard Diffie–Hellman (DH) and elliptic curve Diffie–Hellman (ECDH), which are the most suited for tiny devices, only work between a pair of IIoT devices, while they are not designed to work among a group of IIoT devices. This paper proposes an authenticated group shared key (AGSK) mechanism that allows a set of industrial objects to establish a common session key over the IIoT. The proposed AGSK utilizes the combiner for the hash function and digital signature, which is implemented in IIoT devices. Additionally, the random oracle model has been used to prove the security of AGSK, while the IIoT adversary model has been used to analyze the AGSK countermeasures against cyberattacks. The results of the performance evaluation showed that the efficiency of the AGSK was reduced by 41.3% for CPU computation time, 45.7% for storage cost, and 40% less power consumption compared to the baseline group key management algorithms.

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Section: Related Work On Group Shared Keymentioning

confidence: 99%

Section: Related Work On Group Shared Keymentioning

confidence: 99%

An Authenticated Group Shared Key Mechanism Based on a Combiner for Hash Functions over the Industrial Internet of Things

Ali

Ahmed

2023

Processes

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“…Additionally, the utilized DSs represent ID pointers to miners, which raises concerns regarding linkage attacks possibility in public BCs. Yes q ≤ 1/4 Yes Randomized Ostraka [86] Yes N/A No Randomized SBSCH-GKA [89] Yes N/A Yes N/A Cycledger [90] Yes f ≤ N/3 Yes Randomized RepChain [91] Yes f ≤ N/3 Yes Randomized SSHC [92] Yes q ≤ 1/3 Yes Randomized RapidChain [93] No…”

Section: ) Security and Privacymentioning

confidence: 99%

Approaches to Overpower Proof-of-Work Blockchains Despite Minority

Baniata

Kertész

2023

IEEE Access

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Blockchain (BC) technology has been established in 2009 by S. Nakamoto, using the Proofof-Work (PoW) to reach consensus in public permissionless networks [1]. Since then, several consensus algorithms were proposed to provide equal (or higher) levels of security, democracy, and scalability, yet with lower levels of energy consumption. However, Nakamoto's model (a.k.a. Bitcoin) still dominates as the most trusted model in the described sittings since alternative solutions might provide lower energy consumption and higher scalability, but they would always require deviating the system towards unrecommended centralization or lower levels of security. That is, Nakamoto's model claims to tolerate (up to) < 50% of the network being controlled by a dishonest party (minority), which cannot be realized in alternative solutions without sacrificing the full decentralization property. In this paper, we investigate this tolerance claim, and we review several approaches that can be used to undermine/overpower PoW-based BCs, even with minority. We discuss those BCs taking Bitcoin as a representative application, where needed. However, the presented approaches can be applied in any PoW-based BC. Specifically, we technically discuss how a dishonest miner in minority, can take over the network using improved Brute-forcing, AI-assisted mining, Quantum Computing, Sharding, Partial Pre-imaging, Selfish mining, among other approaches. Our review serves as a needed collective technical reference (concluding more than 100 references), for practitioners and researchers, who either seek a reliable security implementation of PoW-based BC applications, or seek a comparison of PoW-based, against other BCs, in terms of adversary tolerance.

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“…When variations occur, the adjacent node begins the rekeying action hence decreasing the load on the cluster head. The group head selects a random key to be used for encrypting the swapped among the cluster heads and the network head sends the key to the group head that is used for communication among the cluster head 18,19 …”

Section: Introductionmentioning

confidence: 99%

“…The group head selects a random key to be used for encrypting the swapped among the cluster heads and the network head sends the key to the group head that is used for communication among the cluster head. 18,19 Group key agreement is better than key distribution for secure communication: Key distribution: Peer group communication is better suited for distributed group key management, particularly unreliable networks. It entails choosing a group member dynamically who serves as a key distribution server.…”

Section: Introductionmentioning

confidence: 99%

Enabling security in MANETs using an efficient cluster based group key management with elliptical curve cryptography in consort with sail fish optimization algorithm

Shanmuganathan

Boopalan²,

Elangovan

et al. 2022

Trans Emerging Tel Tech

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In MANET, group key management is a vital part of multicast security. But distribution of keys in an authenticated manner is a difficult task in group key management. The existing methods provide low security with high processing time during group key management resulting does not provide sufficient results. Therefore, enabling security in MANETs using an efficient cluster based group key management with elliptical curve cryptography in consort with sail fish optimization algorithm is proposed in this article for two‐level security with reduced computational overhead. At first, all the nodes in the cluster are structured in hierarchy method. The key server creates public key utilizing private key of the group node. Here, elliptical curve cryptography based meta‐heuristic sail fish optimization algorithm is used to select the optimal private key for better secure communication. After selecting this optimum private key, the key server creates the public key, and a common group key is created using this generated public keys. If the nodes joint or exit from the subgroup, the reset process is executed in group key management process. Finally, this process reduces the computational overhead of rekeying method. The proposed method is simulated by Python programming and network simulator‐3. The proposed elliptical curve cryptography based sail fish optimization algorithm attains 10.9%, 22.21%, and 11.43% low computational overhead, 19.34%, 13.45%, and 42.13% low latency, 43.45%, 22.21%, and 12.22% high packet delivery rate, 11.23%, 13.41%, and 21.11% high network life time than the existing methods.

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A provably secure sharding based blockchain smart contract centric hierarchical group key agreement for large wireless ad‐hoc networks

Cited by 9 publications

References 31 publications

An Authenticated Group Shared Key Mechanism Based on a Combiner for Hash Functions over the Industrial Internet of Things

An Authenticated Group Shared Key Mechanism Based on a Combiner for Hash Functions over the Industrial Internet of Things

Approaches to Overpower Proof-of-Work Blockchains Despite Minority

Enabling security in MANETs using an efficient cluster based group key management with elliptical curve cryptography in consort with sail fish optimization algorithm

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