EncodeORE: Reducing Leakage and Preserving Practicality in Order-Revealing Encryption

Zeng

et al. 2021

Cryptographic primitive of timed-release encryption (TRE) enables the sender to encrypt a message which only allows the designated receiver to decrypt after a designated time. Combined with other encryption technologies, TRE technology is applied to a variety of scenarios, including regularly posting on the social network and online sealed bidding. Nowadays, in order to control the decryption time while maintaining anonymity of user identities, most TRE solutions adopt a noninteractive time server mode to periodically broadcast time trapdoors, but because these time trapdoors are generated with fixed time server’s private key, many “ciphertexts” related to the time server’s private key that can be cryptanalyzed are generated, which poses a big challenge to the confidentiality of the time server’s private key. To work this out, we propose a concrete scheme and a generic scheme of security-enhanced TRE (SETRE) in the random oracle model. In our SETRE schemes, we use fixed and variable random numbers together as the time server’s private key to generate the time trapdoors. We formalize the definition of SETRE and give a provably secure concrete construction of SETRE. According to our experiment, the concrete scheme we proposed reduces the computational cost by about 10.8% compared to the most efficient solution in the random oracle model but only increases the almost negligible storage space. Meanwhile, it realizes one-time pad for the time trapdoor. To a large extent, this increases the security of the time server’s private key. Therefore, our work enhances the security and efficiency of the TRE.

Section: Discussionmentioning

confidence: 99%

Provably Secure Security-Enhanced Timed-Release Encryption in the Random Oracle Model

Yuan

Zeng

et al. 2021

“…In this study, three different simulation scenarios were set up and were compared with the betweenness-based algorithm (referred to as the VC model) [35]. e FIR-based model proposed in this study and the VC model were used for identifying the Input: node set G Output: structural hole constraint coefficient, L ni , of all nodes in G (1) for i ∈ G: //G is the node set of the opportunistic network (2) Calculate k (i) (3) for i ∈ G: (4) Calculate Q (i) (5) for i ∈ G: (6) for j ∈ r(i): //r(i) is the set of all neighboring nodes of node i (7) Calculate P ij (8) for q ∈ (r(i) ∩ r(j)): (9) Calculate P iq and P qj (10) Calculate RC i (11) for i ∈ G: (12) Calculate L i (13) for i ∈ G: (14) Calculate L ni (15) return Ln ALGORITHM 1: Algorithm for calculating the importance of structural holes.…”

Section: Methodsmentioning

confidence: 99%

“…Ferry nodes moving between different regions connect to different areas. At present, research studies on ferry nodes mainly include routing algorithms based on ferry nodes [3][4][5][6][7][8][9][10][11][12], ferry node motion path planning [13][14][15][16][17][18][19], and ferry node network signal coverage [20][21][22][23].…”

Section: Introductionmentioning

confidence: 99%

Ferry Node Identification Model for the Security of Mobile Ad Hoc Network

Zhang

et al. 2021

An opportunistic network is a special type of wireless mobile ad hoc network that does not require any infrastructure, does not have stable links between nodes, and relies on node encounters to complete data forwarding. The unbalanced energy consumption of ferry nodes in an opportunistic network leads to a sharp decline in network performance. Therefore, identifying the ferry node group plays an important role in improving the performance of the opportunistic network and extending its life. Existing research studies have been unable to accurately identify ferry node clusters in opportunistic networks. In order to solve this problem, the concepts of k-core and structural holes have been combined, and a new evaluation indicator, namely, ferry importance rank, has been proposed in this study for analyzing the dynamic importance of nodes in a network. Based on this, a ferry cluster identification model has been designed for accurately identifying the ferry node clusters. The results of the simulations conducted for verifying the performance of the proposed model show that the accuracy of the model to identify the ferry node clusters is 100%.

“…e IoT devices that are attacked by the network may have the management rights of the database stolen. To ensure the privacy and security of the database, the authors of [5,6] proposed encryption algorithms to prevent the leakage of important information. However, in the face of a large number of complex network attacks, it is necessary to ensure network information security from a more comprehensive perspective.…”

Section: Introductionmentioning

confidence: 99%

An Unsupervised Learning-Based Network Threat Situation Assessment Model for Internet of Things

Yang

Zeng

et al. 2020

With the wide application of network technology, the Internet of Things (IoT) systems are facing the increasingly serious situation of network threats; the network threat situation assessment becomes an important approach to solve these problems. Aiming at the traditional methods based on data category tag that has high modeling cost and low efficiency in the network threat situation assessment, this paper proposes a network threat situation assessment model based on unsupervised learning for IoT. Firstly, we combine the encoder of variational autoencoder (VAE) and the discriminator of generative adversarial networks (GAN) to form the V-G network. Then, we obtain the reconstruction error of each layer network by training the network collection layer of the V-G network with normal network traffic. Besides, we conduct the reconstruction error learning by the 3-layer variational autoencoder of the output layer and calculate the abnormal threshold of the training. Moreover, we carry out the group threat testing with the test dataset containing abnormal network traffic and calculate the threat probability of each test group. Finally, we obtain the threat situation value (TSV) according to the threat probability and the threat impact. The simulation results show that, compared with the other methods, this proposed method can evaluate the overall situation of network security threat more intuitively and has a stronger characterization ability for network threats.