Your search keyword '"Secure Communication"' showing total 2,926 results

1. Attention-Enhanced Defensive Distillation Network for Channel Estimation in V2X mm-Wave Secure Communication.

Author

Qi, Xingyu, Liu, Yuanjian, and Ye, Yingchun

Subjects

*CONVOLUTIONAL neural networks, *CYBERTERRORISM, *DEEP learning, *DISTILLATION, *SECURITY systems

Abstract

Millimeter-wave (mm-wave) technology, crucial for future networks and vehicle-to-everything (V2X) communication in intelligent transportation, offers high data rates and bandwidth but is vulnerable to adversarial attacks, like interference and eavesdropping. It is crucial to protect V2X mm-wave communication from cybersecurity attacks, as traditional security measures often fail to counter sophisticated threats and complex attacks. To tackle these difficulties, the current study introduces an attention-enhanced defensive distillation network (AEDDN) to improve robustness and accuracy in V2X mm-wave communication under adversarial attacks. The AEDDN model combines the transformer algorithm with defensive distillation, leveraging the transformer's attention mechanism to focus on critical channel features and adapt to complex conditions. This helps mitigate adversarial examples by filtering misleading data. Defensive distillation further strengthens the model by smoothing decision boundaries, making it less sensitive to small perturbations. To evaluate and validate the AEDDN model, this study uses a publicly available dataset called 6g-channel-estimation and a proprietary dataset named MMMC, comparing the simulation results with the convolutional neural network (CNN) model. The findings from the experiments indicate that the AEDDN, especially in the complex V2X mm-wave environment, demonstrates enhanced performance. [ABSTRACT FROM AUTHOR]

Published

2024

2. Cryptanalyzing an Image Encryption Scheme Using Synchronization of Memristor Chaotic Systems.

Author

He, Shaoxuan, Yang, Hongjiao, Li, Chengqing, and Shen, Xianhui

Subjects

*DNA structure, *CHAOS synchronization, *IMAGE analysis, *CRYPTOGRAPHY, *CIPHERS, *IMAGE encryption

Abstract

This paper conducts a security analysis on an image encryption scheme that incorporates chaos synchronization and DNA encoding techniques. The scheme adheres to the typical Substitution–Permutation structure by introducing the DNA operation as a nonlinear component. Compared to the traditional chaotic ciphers, the designer claims that the scheme achieved better nonlinear properties through the DNA operation. However, the characteristics of the differential between some pairs of plaintexts and the corresponding ciphertexts can be exploited to break the permutation operation. Meanwhile, the substitution operation can also be cracked by checking the mapping between the intermediate variables inversely permuted from ciphertext and the corresponding plaintext. Given the weaknesses of the encryption scheme, we introduce effective strategies for the known-plaintext attack. Both rigorous theoretical analyses and detailed experimental results are provided to demonstrate the effectiveness of the attacks. [ABSTRACT FROM AUTHOR]

Published

2024

3. Synchronization for Delayed Fractional-Order Memristive Neural Networks Based on Intermittent-Hold Control with Application in Secure Communication.

Author

Yao, Xueqi, Shi, Jingxi, Zhong, Shouming, and Du, Yuanhua

Subjects

*FUZZY neural networks, *ADAPTIVE control systems, *SYNCHRONIZATION, *TELECOMMUNICATION systems

Abstract

This article investigates the dynamic behaviors of delayed fractional-order memristive fuzzy cellular neural networks via the Lyapunov method. To address the delay terms of fractional-order systems, a novel lemma is provided to make the solutions of the systems exponentially stable. Furthermore, two new intermittent-hold controllers are designed to improve the robustness of the system and reduce the cost of the controller. One intermittent-hold controller is based on the feedback control strategy, while the other one integrates an adaptive control strategy. Moreover, two crucial theorems are derived from the proposed lemma and controllers, guaranteeing the exponential synchronization between drive and response systems. Finally, the superior performance of the controllers in achieving exponential synchronization is demonstrated through simulations. [ABSTRACT FROM AUTHOR]

Published

2024

4. Trust-based co-operative routing for secure communication in mobile ad hoc networks

Author

Ankita A. Mahamune and M.M. Chandane

Subjects

Mobile Ad hoc NETwork, Secure communication, AODV, Co-operative routing, Trust metric, Information technology, T58.5-58.64

Abstract

The working of a Mobile Ad hoc NETwork (MANET) relies on the supportive cooperation among the network nodes. But due to its intrinsic features, a misbehaving node can easily lead to a routing disorder. This paper presents two trust-based routing schemes, namely Trust-based Self-Detection Routing (TSDR) and Trust-based Co-operative Routing (TCOR) designed with an Ad hoc On-demand Distance Vector (AODV) protocol. The proposed work covers a wide range of security challenges, including malicious node identification and prevention, accurate trust quantification, secure trust data sharing, and trusted route maintenance. This brings a prominent solution for mitigating misbehaving nodes and establishing efficient communication in MANET. It is empirically validated based on a performance comparison with the current Evolutionary Self-Cooperative Trust (ESCT) scheme, Generalized Trust Model (GTM), and the conventional AODV protocol. The extensive simulations are conducted against three different varying network scenarios. The results affirm the improved values of eight popular performance metrics overcoming the existing routing schemes. Among the two proposed works, TCOR is more suitable for highly scalable networks; TSDR suits, however, the MANET application better with its small size. This work thus makes a significant contribution to the research community, in contrast to many previous works focusing solely on specific security aspects, and results in a trade-off in the expected values of evaluation parameters and asserts their efficiency.

Published

2024

5. A Dual‐Polarization Programmable Metasurface for Green and Secure Wireless Communication.

Author

Wang, Zheng Xing, Wu, Jun Wei, Xu, Hui, Dai, Jun Yan, Liu, Shuo, Cheng, Qiang, and Cui, Tie Jun

Subjects

*WIRELESS communications, *OPTIMIZATION algorithms, *ELECTRICITY pricing, *MICROBIAL fuel cells

Abstract

Dual‐polarization programmable metasurfaces can flexibly manipulate electromagnetic (EM) waves while providing approximately twice the information capacity. Therefore, they hold significant applications in next‐generation communication systems. However, there are three challenges associated with the existing dual‐polarization programmable metasurfaces. This article aims to propose a novel design to address them. First, the design overcomes the challenge of element‐ and polarization‐independent controls, enabling more powerful manipulations of EM waves. Second, by using more energy‐efficient tunable components and reducing their number, the design can be nearly passive (maximum power consumption of 27.7 mW), leading to a significant decrease in the cost and power consumption of the system (at least two orders of magnitude lower than the power consumption of conventional programmable metasurfaces). Third, the design can operate in a broad bandwidth, which is attractive for practical engineering applications. Both the element and array of the metasurface are meticulously designed, and their performance has been carefully studied. The experiments demonstrate that 2D wide‐angle beam scanning can be realized. Moreover, secure communication based on directional information modulation can be implemented by exploiting the metasurface and an efficient discrete optimization algorithm, showing its programmable, multiplexing, broadband, green, and secure features. [ABSTRACT FROM AUTHOR]

Published

2024

6. Application of optimizing advanced encryption standard encryption algorithm in secure communication of vehicle controller area network bus.

Author

Chenzhe Mu

Subjects

ADVANCED Encryption Standard, ENCRYPTION protocols, OPTIMIZATION algorithms, LOCAL area networks, VEHICULAR ad hoc networks, ALGORITHMS

Abstract

Introduction: As the main means of information exchange within vehicles, the safety of the controller area network bus directly affects the safe operation of the vehicle and the safety of passengers' lives and property. Methods: To enhance its secure communication function, this study utilizes advanced encryption standard algorithms and improves the S-box of the algorithm to solve problems such as extended processing time. A secure communication system for the local area network bus of the vehicle controller is designed based on optimized advanced encryption standard algorithms. Results and Discussion: The results showed that when the file size was 200MB, the encryption and decryption time spent by the research method was 469.8 s and 528.5 s, respectively, which are significantly lower than traditional methods. In the simulation results, under both non-encrypted and encrypted transmission, the information remained intact throughout the entire transmission process. This indicated that the optimization algorithm effectively reduced encryption processing time and system resource consumption while ensuring data confidentiality and integrity. The new system meets the security requirements of the local area network bus of vehicle-mounted controllers. Conclusion: This study not only enhances the security of in-vehicle networks but also promotes the application and development of related encryption technologies in the field of vehicle networking. It provides strong technical support for the further development of vehicle networking and the safe operation of intelligent vehicles. [ABSTRACT FROM AUTHOR]

Published

2024

7. An Effective Mechanism for FOG Computing Assisted Function Based on Trustworthy Forwarding Scheme (IOT).

Author

Hameed, Fatimah Mohammed Hameed and Kurnaz, Sefer

Subjects

DATA transmission systems, DATA security, ELECTRONIC data processing, TRUST, EDGE computing

Abstract

As the Internet of Things (IoT) continues to proliferate, the demand for efficient and secure data processing at the network edge has grown exponentially. Fog computing, a paradigm that extends cloud capabilities to the edge of the network, plays a pivotal role in meeting these requirements. In this context, the reliable and trustworthy forwarding of data is of paramount importance. This paper presents an innovative mechanism designed to ensure the trustworthiness of data forwarding in the context of MQTT (Message Queuing Telemetry Transport), a widely adopted IoT communication protocol. Our proposed mechanism leverages the inherent advantages of MQTT to establish a robust and secure data-forwarding scheme. It integrates fog computing resources seamlessly into the MQTT ecosystem, enhancing data reliability and security. The mechanism employs trust models to evaluate the credibility of IoT devices and fog nodes involved in data forwarding, enabling informed decisions at each stage of the transmission process. Key components of the mechanism include secure communication protocols, authentication mechanisms, and data integrity verification. The proposed secure communication protocols (TLS/SSL, MQTTS, and PKI) and data integrity verification methods (MAC, digital signatures, checksums, and CRC) provide a robust framework for ensuring secure and trustworthy data transmission in IoT systems. These elements collectively contribute to the establishment of a reliable data forwarding pipeline within MQTT. Additionally, the mechanism prioritizes low-latency communication and efficient resource utilization, aligning with the real-time requirements of IoT applications. Through empirical evaluations and simulations, the research demonstrates the effectiveness of our proposed mechanism in improving the trustworthiness of data forwarding, while minimizing overhead, as the experiment was conducted with 15 fog nodes, and the maximum Level of Trust (LoT) score was 0.968, which is very high, with an estimated accuracy of 97.63%. The results indicate that our approach significantly enhances data security and reliability in MQTT-based IoT environments, thereby facilitating the seamless integration of fog computing resources for edge processing. [ABSTRACT FROM AUTHOR]

Published

2024

8. A Comprehensive Approach to Combat GPS Spoofing and Ensure Security Positioning in Autonomous Vehicles.

Author

Kenioua, Laid, Lejdel, Brahim, and Nedioui, Mohamed Abdelhamid

Published

2024

9. Efficient Data Management in Agricultural IoT: Compression, Security, and MQTT Protocol Analysis.

Author

Has, Mislav, Kreković, Dora, Kušek, Mario, and Podnar Žarko, Ivana

Subjects

*AGRICULTURAL technology, *COMPUTER network traffic, *HUFFMAN codes, *AGRICULTURE, *DATA management, *INTERNET of things, *DATA security

Abstract

The integration of Internet of Things (IoT) technology into agriculture has revolutionized farming practices by using connected devices and sensors to optimize processes and facilitate sustainable execution. Because most IoT devices have limited resources, the vital requirement to efficiently manage data traffic while ensuring data security in agricultural IoT solutions creates several challenges. Therefore, it is important to study the data amount that IoT protocols generate for resource-constrained devices, as it has a direct impact on the device performance and overall usability of the IoT solution. In this paper, we present a comprehensive study that focuses on optimizing data transmission in agricultural IoT solutions with the use of compression algorithms and secure technologies. Through experimentation and analysis, we evaluate different approaches to minimize data traffic while protecting sensitive agricultural data. Our results highlight the effectiveness of compression algorithms, especially Huffman coding, in reducing data size and optimizing resource usage. In addition, the integration of encryption techniques, such as AES, provides the security of the transmitted data without incurring significant overhead. By assessing different communication scenarios, we identify the most efficient approach, a combination of Huffman encoding and AES encryption, to strike a balance between data security and transmission efficiency. [ABSTRACT FROM AUTHOR]

Published

2024

10. Cooperative networking and information processing system of wireless communication UAV under the background of intelligent service.

Author

Chen, Zhiyong

Subjects

*INFORMATION storage & retrieval systems, *INFORMATION networks, *DIGITAL technology, *SEARCH algorithms, *DATA structures, *PROBLEM solving, *DRONE aircraft

Abstract

In order to solve the huge impact of the digital information age on many technical and industrial fields, a periodic fast search genetic algorithm is proposed. Based on the reconnaissance mission, this paper introduces the common allocation strategy into mission planning, and constructs the mathematical model of multi unmanned aerial vehicle (UAV) cooperative reconnaissance mission planning decision‐making. The proposed periodic fast search genetic algorithm is used to solve the problem of multi UAV cooperative reconnaissance mission planning. In 2020, the industry growth rate of global UAV technology expenditure was as high as 30.6%, and the compound growth rate of UAV in China reached 63.5%, which is enough to see the great prospect of the integrated development of UAV technology and different industries. The experiment evaluates the log verification module of UAV by comparing the two data structures of Merkle tree and linear, and the time and memory overhead of storing and verifying logs, which shows the effectiveness of the log verification scheme in this paper. [ABSTRACT FROM AUTHOR]

Published

2024

11. Secure communication in the digital age: a new paradigm with graph-based encryption algorithms

Author

Nasir Ali, Ayesha Sadiqa, Muhammad Amir Shahzad, Muhammad Imran Qureshi, Hafiz Muhammad Afzal Siddiqui, Suhad Ali Osman Abdallah, and Nashaat S. Abd El-Gawaad

Subjects

encryption algorithms, decryption, security, secure communication, data transfer, symmetric cipher, Electronic computers. Computer science, QA75.5-76.95

Abstract

In the contemporary technological landscape, ensuring confidentiality is a paramount concern addressed through various skillsets. Cryptography stands out as a scientific methodology for safeguarding communication against unauthorized access. Within the realm of cryptography, numerous encryption algorithms have been developed to enhance data security. Recognizing the imperative for nonstandard encryption algorithms to counter traditional attacks, this paper puts forth novel encryption techniques. These methods leverage special corona graphs, star graphs, and complete bipartite graphs, incorporating certain algebraic properties to bolster the secure transmission of messages. The introduction of these proposed encryption schemes aims to elevate the level of security in confidential communication, some of the applications of these schemes are given in the later section.

Published

2024

12. QoS prediction using EMD-BiLSTM for II-IoT-secure communication systems

Author

Zeng Yun and Li Xiang

Subjects

industrial intelligent internet of things, secure communication, emd, bilstm, qos prediction, Science, Electronic computers. Computer science, QA75.5-76.95

Abstract

To address the challenges of secure and reliable communication and system quality of service (QoS) prediction in intelligent production lines (IPL) in the Industrial Intelligent Internet of Things (II-IOT) environment, a redundant collaborative security model-based communication architecture is designed. First, the redundant collaborative security communication model is introduced to construct the network communication architecture of IPL, including the industrial-site mechanical floor, data awareness layer, and gateway and application layer. Then, to leverage the advantages of the empirical-mode decomposition (EMD) method and the bidirectional long short-term memory (BiLSTM) model in time-series data analysis and processing, an EMD-BiLSTM-based QoS prediction model is proposed that can synchronously achieve one-step and multi-step prediction of QoS attributes. The proposed model exhibits a prediction accuracy of up to 94.01% on the SourceForge dataset, with prediction, recall, and F1 values as high as 91.37, 90.60, and 90.99%, respectively. The proposed EMD-BiLSTM model can achieve better performance than the state-of-the-art QoS prediction models, indicating that the proposed model can be more effectively used to improve the reliable communication level of II-IoT.

Published

2024

13. Multisecret‐sharing scheme with two‐level security and its applications in blockchain

Author

Rajendra Kumar Sharma, Ritumoni Sarma, Neha Arora, and Vidya Sagar

Subjects

authentication, blockchains, contracts, cryptography, secure communication, Electronic computers. Computer science, QA75.5-76.95

Abstract

Abstract A (t,m)‐threshold secret sharing and multisecret‐sharing scheme based on Shamir's secret sharing scheme are introduced with two‐level security using a one‐way function. Besides, its application in a smart contract‐enabled consortium blockchain network is discussed. The proposed scheme is thoroughly examined in terms of security and efficiency. Privacy, security, integrity, and scalability are also analyzed while applying it to the blockchain network.

Published

2024

14. Finite-time synchronization of delayed semi-Markov reaction–diffusion systems: An asynchronous boundary control scheme.

Author

Wei, Angang, Yao, Zhongyuan, Zhang, Yu, and Wang, Kaiming

Subjects

SYNCHRONIZATION, MARKOVIAN jump linear systems, HOPFIELD networks

Abstract

This paper tries to study the problem of finite-time synchronization for delayed semi-Markov reaction–diffusion systems. Based on the spatial and parametric characteristics of the considered systems, a new asynchronous boundary control scheme is proposed to ensure the finite-time synchronization of the drive and response systems. In the asynchronous boundary control scheme, only an actuator should be placed at the spatial boundary, which is more easier to implement and economical than the other non-boundary control strategies. Besides, the system parameters and controller follow two asynchronous semi-Markov chains for jumping, which is more practical than obeying one semi-Markov chain. Moreover, for the considered systems, we proposes a new lemma of finite-time stability, and by employing the inequality methods and variable substitution, we derive the criterion of finite-time synchronization and a correlative corollary. Finally, a numerical example and an application example on secure communication are carried out to support the developed approach. • Our study enriches the related research of semi-Markov RDSs. The obtained results guarantee the finite-time synchronization of semi-Markov RDSs, which is more effective and practical than asymptotic synchronization. • This paper proposes a novel asynchronous boundary control scheme, for the synchronization of semi-Markov RDSs. Compared with existing ones, our control scheme has obvious advantages in realizability and economy. • Based on the existing papers, in the designed controller, a constant is introduced, such that the intense chatter of controller could be reduced. • For the considered systems and designed controller, a new finite-time stability lemma is proposed, which enables the derivation of a finite-time synchronization criterion and a related corollary of this paper. [ABSTRACT FROM AUTHOR]

Published

2024

15. Realization of Authenticated One-Pass Key Establishment on RISC-V Micro-Controller for IoT Applications.

Author

Dang, Tuan-Kiet, Nguyen, Khai-Duy, Kieu-Do-Nguyen, Binh, Hoang, Trong-Thuc, and Pham, Cong-Kha

Subjects

MICROCONTROLLERS, ELLIPTIC curve cryptography, INTERNET of things, COMPUTER systems, SECURITY systems, DATA integrity

Abstract

Internet-of-things networks consist of multiple sensor devices spread over a wide area. In order to protect the data from unauthorized access and tampering, it is essential to ensure secure communication between the sensor devices and the central server. This security measure aims to guarantee authenticity, confidentiality, and data integrity. Unlike traditional computing systems, sensor node devices are often limited regarding memory and computing power. Lightweight communication protocols, such as LoRaWAN, were introduced to overcome these limitations. However, despite the lightweight feature, the protocol is vulnerable to different types of attacks. This proposal presents a highly secure key establishment protocol that combines two cryptography schemes: Elliptic Curve Qu–Vanstone and signcryption key encapsulation. The protocol provides a method to establish a secure channel that inherits the security properties of the two schemes. Also, it allows for fast rekeying with only one exchange message, significantly reducing the handshake complexity in low-bandwidth communication. In addition, the selected schemes complement each other and share the same mathematical operations in elliptic curve cryptography. Moreover, with the rise of a community-friendly platform like RISC-V, we implemented the protocol on a RISC-V system to evaluate its overheads regarding the cycle count and execution time. [ABSTRACT FROM AUTHOR]

Published

2024

16. Harnessing optical advantages in computing: a review of current and future trends.

Author

Kibebe, Caxton Griffith, Liu, Yue, Tang, Jiaxi, Sharma, Abhishek, and Kumari, Meet

Subjects

OPTICAL computing, LITERATURE reviews, SIGNAL processing, QUANTUM computing, PARALLEL processing, IMAGE processing, ELECTRONIC journals

Abstract

At the intersection of technological evolution and escalating computational demand, the role of optics is reemerging as a transformative force in the field of computing. This article examines the evolving landscape surrounding optical advantages in computing, focusing on current trends and prospects. Optical computing finds applications across various domains, such as parallel processing, high-speed signal processing, energy efficiency, quantum computing, machine learning, secure communication, and signal/image processing. This review synthesizes insights from scholarly articles, peer-reviewed journals, and academic papers to analyze the potential and challenges of leveraging optics for computational tasks. The literature review also critically examines the challenges of adopting optical computing solutions. The recommended multidimensional approach to overcoming adoption challenges involves holistically addressing integration challenges, manufacturing complexities, and infrastructure needs where collaboration will catapult optical computing into an era of computational power. Through a multidimensional exploration, this article provides a comprehensive understanding of the opportunities and challenges in harnessing optical advantages in computing, positioning optical computing as a revolutionary force with far-reaching consequences. Consequently, this review offers insight and guides researchers, industry professionals, and policymakers toward a computational future that maximizes the advantages of optical computing in specific and pivotal application areas, transcending existing boundaries. [ABSTRACT FROM AUTHOR]

Published

2024

17. An n -Dimensional Chaotic Map with Application in Reversible Data Hiding for Medical Images.

Author

Yang, Yuli, Chang, Ruiyun, Feng, Xiufang, Li, Peizhen, Chen, Yongle, and Zhang, Hao

Subjects

*REVERSIBLE data hiding (Computer science), *IMAGE encryption, *DIAGNOSTIC imaging

Abstract

The drawbacks of a one-dimensional chaotic map are its straightforward structure, abrupt intervals, and ease of signal prediction. Richer performance and a more complicated structure are required for multidimensional chaotic mapping. To address the shortcomings of current chaotic systems, an n-dimensional cosine-transform-based chaotic system (nD-CTBCS) with a chaotic coupling model is suggested in this study. To create chaotic maps of any desired dimension, nD-CTBCS can take advantage of already-existing 1D chaotic maps as seed chaotic maps. Three two-dimensional chaotic maps are provided as examples to illustrate the impact. The findings of the evaluation and experiments demonstrate that the newly created chaotic maps function better, have broader chaotic intervals, and display hyperchaotic behavior. To further demonstrate the practicability of nD-CTBCS, a reversible data hiding scheme is proposed for the secure communication of medical images. The experimental results show that the proposed method has higher security than the existing methods. [ABSTRACT FROM AUTHOR]

Published

2024

18. SECURING AND ADVANCING ROAD SAFETY IN INTELLIGENT VEHICULAR NETWORKS FOR SEAMLESS AND SECURE COMMUNICATION.

Author

Saranya, R., Tamizhselvi, A., Charan, Piyush, and Ahmed, Syed Arfath

Subjects

INTELLIGENT networks, RSA algorithm, INTELLIGENT transportation systems, ROAD safety measures, TELECOMMUNICATION, TRAFFIC signs & signals, COMMUNICATION infrastructure

Abstract

Intelligent vehicular networks leverage communication technologies to enable vehicles to interact with each other and with infrastructure elements, such as roadside units and traffic signals, to enhance road safety and efficiency. However, the open nature of these networks exposes them to various security threats, including data interception, tampering, and unauthorized access. Traditional encryption methods may not suffice to address these challenges, necessitating the adoption of advanced cryptographic techniques like ECC and RSA. Prior research in the field has primarily focused on either enhancing communication protocols or improving security measures independently. However, there is a notable gap in research that comprehensively addresses both aspects simultaneously. This study aims to fill this void by proposing an integrated approach that ensures both seamless communication and robust security in intelligent vehicular networks. The proposed methodology involves the design and implementation of a hybrid cryptographic scheme combining ECC and RSA algorithms. This scheme will be integrated into the existing communication infrastructure of intelligent vehicular networks. The performance of the system will be evaluated through simulations and real-world experiments to assess its effectiveness in securing communication channels while minimizing overhead. The results show the effectiveness of the proposed ECC-RSA hybrid encryption scheme in securing communication channels within intelligent vehicular networks. The integration of ECC and RSA protocols not only enhances the security of data transmission but also ensures seamless communication, thereby advancing road safety in intelligent vehicular environments [ABSTRACT FROM AUTHOR]

Published

2024

19. An Enhanced Location-Aided Ant Colony Routing for Secure Communication in Vehicular Ad Hoc Networks.

Author

Ramamoorthy, Raghu

Subjects

ANT algorithms, VEHICULAR ad hoc networks, WIRELESS communications, DATA transmission systems, COMPUTER simulation

Abstract

The dynamic characteristics of vehicular ad hoc networks (VANETs) demand reliable and secure communication over wireless media. However, there are significant contradictions in autonomous vehicular systems related to security and privacy. Furthermore, VANETs require seamless data transmission to exchange time-critical data about accidents and traffic. Therefore, VANETs require secure seamless data transmission mechanisms to provide secure reliable communication without communication interruption to exchange time-critical data between vehicles. This paper proposes an Enhanced Location-Aided Ant colony Routing (ELAACR) for VANETs to achieve seamless secure data transmission. The proposed ELAACR is a two-fold scheme in which Phase 1 implements Location-Aided Key Management (LAKM) and Phase 2 implements Ant Colony Routing (ACR). An ACR combined with an LAKM pattern for offering secure and reliable communication. The LAKM scheme works based on the group signature concept to construct a secure network, and an ACR is used to find an efficient secure shortest path for seamless data transmission. The proposed work is simulated in Network Simulator (NS 2.35). By using an efficient and secure shortest path with secure seamless data transmission, the proposed ELAACR achieves an average throughput (T) of 640 Kbps, packet loss rate (PLR) of 0.018%, packet delivery ratio (PDR) of 98.5%, overhead (OH) of 0.157%, and 0.16 s end-to-end delay (EED) compared to Enhanced Hybrid Ant Colony Optimization Routing Protocol (EHACORP) and Fuzzy Based Ant Colony Optimization (F-ANT). The simulation results show that the proposed ELAACR registers better performance in all aspects compared to the existing EHACORP and F-ANT. [ABSTRACT FROM AUTHOR]

Published

2024

20. Secure Device-to-Device Communication in IoT: Fuzzy Identity from Wireless Channel State Information for Identity-Based Encryption.

Author

Zhang, Bo, Zhang, Tao, Xi, Zesheng, Chen, Ping, Wei, Jin, and Liu, Yu

Subjects

WIRELESS channels, INTERNET of things, CONFIDENTIAL communications, ALGORITHMS

Abstract

With the rapid development of the Internet of Things (IoT), ensuring secure communication between devices has become a crucial challenge. This paper proposes a novel secure communication solution by extracting wireless channel state information (CSI) features from IoT devices to generate a device identity. Due to the instability of the wireless channel, the CSI features are fuzzy and time-varying; thus, we a employ locally sensitive hashing (LSH) algorithm to ensure the stability of the generated identity in a dynamically changing wireless channel environment. Furthermore, zero-knowledge proofs are utilized to guarantee the authenticity and effectiveness of the generated identity. Finally, the identity generated using the aforementioned approach is integrated into an IBE communication scheme, which involves the fuzzy extraction of channel state information from IoT devices, stable identity extraction for fuzzy IoT devices using LSH, and the use of zero-knowledge proofs to ensure the authenticity of the generated identity. This identity is then employed as the identity information in identity-based encryption (IBE), constructing the device's public key for achieving confidential communication between devices. [ABSTRACT FROM AUTHOR]

Published

2024

21. A Dual‐Polarization Programmable Metasurface for Green and Secure Wireless Communication

Author

Zheng Xing Wang, Jun Wei Wu, Hui Xu, Jun Yan Dai, Shuo Liu, Qiang Cheng, and Tie Jun Cui

Subjects

dual‐polarization, green, low cost, programmable metasurface, secure communication, Science

Abstract

Abstract Dual‐polarization programmable metasurfaces can flexibly manipulate electromagnetic (EM) waves while providing approximately twice the information capacity. Therefore, they hold significant applications in next‐generation communication systems. However, there are three challenges associated with the existing dual‐polarization programmable metasurfaces. This article aims to propose a novel design to address them. First, the design overcomes the challenge of element‐ and polarization‐independent controls, enabling more powerful manipulations of EM waves. Second, by using more energy‐efficient tunable components and reducing their number, the design can be nearly passive (maximum power consumption of 27.7 mW), leading to a significant decrease in the cost and power consumption of the system (at least two orders of magnitude lower than the power consumption of conventional programmable metasurfaces). Third, the design can operate in a broad bandwidth, which is attractive for practical engineering applications. Both the element and array of the metasurface are meticulously designed, and their performance has been carefully studied. The experiments demonstrate that 2D wide‐angle beam scanning can be realized. Moreover, secure communication based on directional information modulation can be implemented by exploiting the metasurface and an efficient discrete optimization algorithm, showing its programmable, multiplexing, broadband, green, and secure features.

Published

2024

22. Integrating Energy Harvesting, Anti-Eavesdropping, and Communication in a Hybrid Beamforming System

Author

Haoming He and Xin He

Subjects

Hybrid beamforming, energy harvesting, secure communication, quality of service, unit modulus constraints, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

This paper proposes a scheme to integrate data communication, wireless energy harvesting and anti-eavesdropping functions into a hybrid beamforming downlink system to satisfy the demand for expanded functionalities in a communication system. To solve this difficult nonconvex problem, the Semidefinite Relaxation (SDR) method is employed to obtain the digital transmitter, the SDR method and penalty convex-concave procedure (CCP) method are employed to obtain the analog transmitter. Simulation results shows four conclusions about the system. Firstly, the larger the SINR target or the energy harvest target, the more transmit power is required. Secondly, the lower the data rate obtained by the eavesdropper, the more transmit power is required. Thirdly, the SDR method and the penalty CCP method complement each other. Finally, the transmit power can be reduced by increasing the number of RF chains or transmit antennas.

Published

2024

23. An Enhanced Location-Aided Ant Colony Routing for Secure Communication in Vehicular Ad Hoc Networks

Author

Raghu Ramamoorthy

Subjects

Routing, Shortest path, Ant colony routing, Efficient path, Secure communication, Information technology, T58.5-58.64, Electronic computers. Computer science, QA75.5-76.95

Abstract

Abstract The dynamic characteristics of vehicular ad hoc networks (VANETs) demand reliable and secure communication over wireless media. However, there are significant contradictions in autonomous vehicular systems related to security and privacy. Furthermore, VANETs require seamless data transmission to exchange time-critical data about accidents and traffic. Therefore, VANETs require secure seamless data transmission mechanisms to provide secure reliable communication without communication interruption to exchange time-critical data between vehicles. This paper proposes an Enhanced Location-Aided Ant colony Routing (ELAACR) for VANETs to achieve seamless secure data transmission. The proposed ELAACR is a two-fold scheme in which Phase 1 implements Location-Aided Key Management (LAKM) and Phase 2 implements Ant Colony Routing (ACR). An ACR combined with an LAKM pattern for offering secure and reliable communication. The LAKM scheme works based on the group signature concept to construct a secure network, and an ACR is used to find an efficient secure shortest path for seamless data transmission. The proposed work is simulated in Network Simulator (NS 2.35). By using an efficient and secure shortest path with secure seamless data transmission, the proposed ELAACR achieves an average throughput (T) of 640 Kbps, packet loss rate (PLR) of 0.018%, packet delivery ratio (PDR) of 98.5%, overhead (OH) of 0.157%, and 0.16 s end-to-end delay (EED) compared to Enhanced Hybrid Ant Colony Optimization Routing Protocol (EHACORP) and Fuzzy Based Ant Colony Optimization (F-ANT). The simulation results show that the proposed ELAACR registers better performance in all aspects compared to the existing EHACORP and F-ANT.

Published

2024

24. Attention-Enhanced Defensive Distillation Network for Channel Estimation in V2X mm-Wave Secure Communication

Author

Xingyu Qi, Yuanjian Liu, and Yingchun Ye

Subjects

mm-wave, V2X, deep learning defensive distillation, attention, secure communication, adversarial attack, Chemical technology, TP1-1185

Abstract

Millimeter-wave (mm-wave) technology, crucial for future networks and vehicle-to-everything (V2X) communication in intelligent transportation, offers high data rates and bandwidth but is vulnerable to adversarial attacks, like interference and eavesdropping. It is crucial to protect V2X mm-wave communication from cybersecurity attacks, as traditional security measures often fail to counter sophisticated threats and complex attacks. To tackle these difficulties, the current study introduces an attention-enhanced defensive distillation network (AEDDN) to improve robustness and accuracy in V2X mm-wave communication under adversarial attacks. The AEDDN model combines the transformer algorithm with defensive distillation, leveraging the transformer’s attention mechanism to focus on critical channel features and adapt to complex conditions. This helps mitigate adversarial examples by filtering misleading data. Defensive distillation further strengthens the model by smoothing decision boundaries, making it less sensitive to small perturbations. To evaluate and validate the AEDDN model, this study uses a publicly available dataset called 6g-channel-estimation and a proprietary dataset named MMMC, comparing the simulation results with the convolutional neural network (CNN) model. The findings from the experiments indicate that the AEDDN, especially in the complex V2X mm-wave environment, demonstrates enhanced performance.

Published

2024

25. Real-Time Synchronisation of Multiple Fractional-Order Chaotic Systems: An Application Study in Secure Communication.

Author

Nail, Bachir, Atoussi, Mahedi Abdelghani, Saadi, Slami, Tibermacine, Imad Eddine, and Napoli, Christian

Subjects

*ARDUINO (Microcontroller), *ELECTRONIC equipment

Abstract

In this paper, we use two Fractional-Order Chaotic Systems (FOCS)—one for the sender and one for the receiver—to determine the optimal synchronisation for a secure communication technique. With the help of the Step-By-Step Sliding-Mode Observer (SBS-SMO), this synchronisation is accomplished. An innovative optimisation method, known as the artificial Harris hawks optimisation (HHO), was employed to enhance the observer's performance. This method eliminates the random parameter selection process and instead selects the optimal values for the observer. In a short amount of time, the secret message that could have been in the receiver portion (signal, voice, etc.) was successfully recovered using the proposed scheme. The experimental validation of the numerical results was carried out with the assistance of an Arduino microcontroller and several electronic components. In addition, the findings of the experiments were compared with the theoretical calculations, revealing a satisfactory level of agreement. [ABSTRACT FROM AUTHOR]

Published

2024

26. Multifaceted Coding of Messages Using the Concepts of Graph Theory.

Author

H. R., Medini, D'Souza, Sabitha, C., Devadas Nayak, and Bhat, Pradeep G.

Subjects

GRAPH theory, DATA security failures, FUZZY graphs, GRAPH labelings, DIGITAL communications, SUBGRAPHS

Abstract

The modern world has brought everyone closer through digital communications. People are highly dependent on digital services. The quest for a more complex coding algorithm to prevent data from breaching is never-ending. The more intricate the algorithm is, the safer the communication will be. So, the vogue is to find the most convoluted algorithm to provide secure communication. In this paper, a unique algorithm is developed using graph labeling, a complement of a graph and generalized complement. The algorithm generates two labeled graphs satisfying vertex even mean and vertex odd mean labelings. Encryption involves the process of complementation and combining both graphs by k-complementation of graphs to obtain a cipher graph. The reverse process is applied for decryption which involves splitting the cipher graph into two subgraphs by applying k-complement for the specified partition of the vertex set, taking the complement of the obtained graph/s and getting the values of the plaintext using the graph labeling method. The proposed algorithm is designed in such a way that it should be useful for all kinds of plaintexts even with special characters. To illustrate this, an app is developed in the Android platform for communication of messages using endto-end encryption. [ABSTRACT FROM AUTHOR]

Published

2024

27. Synchronization and Application of a Novel Hyperchaotic System Based on Adaptive Observers.

Author

Ozpolat, Erman and Gulten, Arif

Subjects

SYNCHRONIZATION, LYAPUNOV exponents, CHAOTIC communication, TELECOMMUNICATION systems, PHASE space

Abstract

This paper explores the synchronization and implementation of a novel hyperchaotic system using an adaptive observer. Hyperchaotic systems, known for possessing a greater number of positive Lyapunov exponents compared to chaotic systems, present unique challenges and opportunities in control and synchronization. In this study, we introduce a novel hyperchaotic system, thoroughly examining its dynamic properties and conducting a comprehensive phase space analysis. The proposed hyperchaotic system undergoes validation through circuit simulation to confirm its behavior. Introducing an adaptive observer synchronization technique, we successfully synchronize the dynamics of the novel hyperchaotic system with an identical counterpart. Importantly, we extend the application of this synchronization method to the domain of secure communication, showcasing its practical usage. Simulation outcomes validate the effectiveness of our methodology, demonstrating favorable results in the realm of adaptive observer-based synchronization. This research contributes significantly to the understanding and application of hyperchaotic systems, offering insights into both the theoretical aspects and practical implementation. Our findings suggest potential advancements in the field of chaotic systems, particularly in their applications within secure communication systems. By presenting motivations, methods, results, conclusions and the significance of our work in a more appealing manner, we aim to engage readers and highlight the innovative contributions of this study. [ABSTRACT FROM AUTHOR]

Published

2024

28. A New Memristive System with Extreme Multistability and Hidden Chaotic Attractors and with Application to Image Encryption.

Author

Zhao, Guangzhe, Zhao, He, Zhang, Yunzhen, and An, Xinlei

Subjects

*IMAGE encryption, *CHAOS theory, *DNA, *ANALOG circuits, *HYSTERESIS loop, *TIME series analysis

Abstract

Chaotic systems have proven highly beneficial in engineering applications. Pseudo-random numbers produced by chaotic systems have been used for secure communication, notably image encryption. Specific characteristics can increase the chaotic behavior of the system by adding complexity and nonlinearity. The three most well-known characteristics are memristive properties, multistability (coexisting attractors), and hidden attractors. These characteristics strengthen the produced time series' unpredictability and randomness, strengthening an encryption algorithm's resistance to many attacks. This study introduces a unique four-dimensional chaotic system with extreme multistability with respect to three initial conditions (including the memristor initial condition) and all previously known properties. It is rare to find an extreme multistable system like this. This system is coupled with a quadratic flux-controlled memristor based on the well-known Sprott J system. This system has a line of unstable equilibrium points with hidden attractors. The memristor displays the characteristic pinched hysteresis loops, where the area inside a loop and the voltage frequency are inversely related. A comprehensive dynamical analysis thoroughly examines all system characteristics and initial conditions. The numerical findings are carefully verified, and an analog circuit is successfully built and simulated. The chaotic sequences generated by this system are combined with deoxyribonucleic acid (DNA) operations and the global bit scrambling (GBS) technique to create an image encryption algorithm that has strong resistance to a variety of potential attacks, including noise, statistical, exhaustive, differential, and cropping attacks. [ABSTRACT FROM AUTHOR]

Published

2024

29. Secure User Pairing and Power Allocation for Downlink Non-Orthogonal Multiple Access against External Eavesdropping.

Author

Li, Yuxuan, Chen, Yanqiu, and Ji, Xiaopeng

Subjects

*EAVESDROPPING, *NONLINEAR programming, *INTEGER programming, *DATA transmission systems, *COMPUTER simulation

Abstract

We propose a secure user pairing (UP) and power allocation (PA) strategy for a downlink Non-Orthogonal Multiple Access (NOMA) system when there exists an external eavesdropper. The secure transmission of data through the downlink is constructed to optimize both UP and PA. This optimization aims to maximize the achievable sum secrecy rate (ASSR) while adhering to a limit on the rate for each user. However, this poses a challenge as it involves a mixed integer nonlinear programming (MINLP) problem, which cannot be efficiently solved through direct search methods due to its complexity. To handle this gracefully, we first divide the original problem into two smaller issues, i.e., an optimal PA problem for two paired users and an optimal UP problem. Next, we obtain the closed-form optimal solution for PA between two users and UP in a simplified NOMA system involving four users. Finally, the result is extended to a general 2 K -user NOMA system. The proposed UP and PA method satisfies the minimum rate constraints with an optimal ASSR as shown theoretically and as validated by numerical simulations. According to the results, the proposed method outperforms random UP and that in a standard OMA system in terms of the ASSR and the average ASSR. It is also interesting to find that increasing the number of user pairs will bring more performance gain in terms of the average ASSR. [ABSTRACT FROM AUTHOR]

Published

2024

30. Watchdog malicious node detection and isolation using deep learning for secured communication in MANET.

Author

A. S., Narmadha, S., Maheswari, and S. N., Deepa

Subjects

MULTICASTING (Computer networks), AD hoc computer networks, DEEP learning, DATA packeting

Abstract

Mobile Ad-hoc Networks (MANETs) are wireless networks formed dynamically by connecting or leaving nodes to and from the network without any fixed infrastructure. These categories of wireless networks are susceptible to different attacks based on their dynamic topological structure. Due to this, security is a primary constraint in MANETs to preserve communication between mobile nodes. A Deep Neural Learned Projective Pursuit Regression-based Watchdog Malicious Node Detection and Isolation (DNLPPR-WMNDI) technique is proposed and modelled in this paper to improve the security feature of MANETs. The newly proposed DNLPPR-WMNDI technique initially selects the neighbouring nodes by applying the projection pursuit regression function. In multicasting, the route paths are established through the intermediate node with the help of control commands named RREQ and RREP. After then, Watchdog Malicious Node Detection and Isolation (WMNDI) technique is applied to detect malicious nodes based on the data packet forwarding time. Basically, a malicious node is affected by a node isolation attack. For better communication, a malicious node is isolated from the network and multicast routing is carried out by selecting the next neighbouring node and this improves the communication security. Simulation is done for the developed technique based on different performance metrics. [ABSTRACT FROM AUTHOR]

Published

2023

31. Harnessing optical advantages in computing: a review of current and future trends

Author

Caxton Griffith Kibebe, Yue Liu, and Jiaxi Tang

Subjects

optical computing, parallel processing, high-speed signal processing, quantum computing, machine learning, secure communication, Physics, QC1-999

Abstract

At the intersection of technological evolution and escalating computational demand, the role of optics is reemerging as a transformative force in the field of computing. This article examines the evolving landscape surrounding optical advantages in computing, focusing on current trends and prospects. Optical computing finds applications across various domains, such as parallel processing, high-speed signal processing, energy efficiency, quantum computing, machine learning, secure communication, and signal/image processing. This review synthesizes insights from scholarly articles, peer-reviewed journals, and academic papers to analyze the potential and challenges of leveraging optics for computational tasks. The literature review also critically examines the challenges of adopting optical computing solutions. The recommended multidimensional approach to overcoming adoption challenges involves holistically addressing integration challenges, manufacturing complexities, and infrastructure needs where collaboration will catapult optical computing into an era of computational power. Through a multidimensional exploration, this article provides a comprehensive understanding of the opportunities and challenges in harnessing optical advantages in computing, positioning optical computing as a revolutionary force with far-reaching consequences. Consequently, this review offers insight and guides researchers, industry professionals, and policymakers toward a computational future that maximizes the advantages of optical computing in specific and pivotal application areas, transcending existing boundaries.

Published

2024

32. Watchdog malicious node detection and isolation using deep learning for secured communication in MANET

Author

Narmadha A. S., Maheswari S., and Deepa S. N.

Subjects

MANET, secure communication, deep neural network learning, projection pursuit regression function, watchdog malicious node detection, isolation, Control engineering systems. Automatic machinery (General), TJ212-225, Automation, T59.5

Abstract

Mobile Ad-hoc Networks (MANETs) are wireless networks formed dynamically by connecting or leaving nodes to and from the network without any fixed infrastructure. These categories of wireless networks are susceptible to different attacks based on their dynamic topological structure. Due to this, security is a primary constraint in MANETs to preserve communication between mobile nodes. A Deep Neural Learned Projective Pursuit Regression-based Watchdog Malicious Node Detection and Isolation (DNLPPR-WMNDI) technique is proposed and modelled in this paper to improve the security feature of MANETs. The newly proposed DNLPPR-WMNDI technique initially selects the neighbouring nodes by applying the projection pursuit regression function. In multicasting, the route paths are established through the intermediate node with the help of control commands named RREQ and RREP. After then, Watchdog Malicious Node Detection and Isolation (WMNDI) technique is applied to detect malicious nodes based on the data packet forwarding time. Basically, a malicious node is affected by a node isolation attack. For better communication, a malicious node is isolated from the network and multicast routing is carried out by selecting the next neighbouring node and this improves the communication security. Simulation is done for the developed technique based on different performance metrics.

Published

2023

33. Synchronization for Delayed Fractional-Order Memristive Neural Networks Based on Intermittent-Hold Control with Application in Secure Communication

Author

Xueqi Yao, Jingxi Shi, Shouming Zhong, and Yuanhua Du

Subjects

exponential synchronization, memristive neural networks, fractional-order system, intermittent-hold control, secure communication, Thermodynamics, QC310.15-319, Mathematics, QA1-939, Analysis, QA299.6-433

Abstract

This article investigates the dynamic behaviors of delayed fractional-order memristive fuzzy cellular neural networks via the Lyapunov method. To address the delay terms of fractional-order systems, a novel lemma is provided to make the solutions of the systems exponentially stable. Furthermore, two new intermittent-hold controllers are designed to improve the robustness of the system and reduce the cost of the controller. One intermittent-hold controller is based on the feedback control strategy, while the other one integrates an adaptive control strategy. Moreover, two crucial theorems are derived from the proposed lemma and controllers, guaranteeing the exponential synchronization between drive and response systems. Finally, the superior performance of the controllers in achieving exponential synchronization is demonstrated through simulations.

Published

2024

34. Secure data collection via UAV-carried IRS

Author

Christantus O. Nnamani, Muhammad R.A. Khandaker, and Mathini Sellathurai

Subjects

Secure communication, IRS, UAV, Optimization, Physical layer security, Information technology, T58.5-58.64

Abstract

This paper considers unmanned aerial vehicle (UAV)-carried intelligent reflecting surface (IRS) for secure data collection from wireless sensor networks. An eavesdropper (Eve) lurks within the vicinity of the main receiver (Bob). Several distributed sensors beamform collaboratively to the UAV-carried IRS reflecting the signal to the main receiver (Bob). The design objective is to maximize the achievable secrecy rate in noisy communication channel by optimizing the collaborative beamforming weights of the sensors, trajectory of the UAV and reflection coefficients of the IRS elements. We proposed novel method to obtain the parameters using non-iterative approach by mitigating the IRS reflection coefficients dependencies.

Published

2023

35. Realization of chaotic oscillator and use in secure communication

Author

Amrita Rai, Manoj Joshi, Kamal Kishor Upadhyay, Vaibhav Khare, Jyoti, Harshit Shastri, and Shreya Goyal

Subjects

Chua circuit, Current feedback amplifier, Secure communication, Chaotic oscillators, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

This scientific study reports on the practical as well as modelling of active hybrid inductor based chaotic oscillators using Current Feedback Amplifier (CFOA) and Op-Amp. Furthermore, a workable design strategy for the chaotic oscillator and its application to secure communication are provided. Here, the transient analysis of chaos waveforms is verified by using MATLAB, Multi-SIM, and LT-Spice tools. The numerical outcomes based on LT-Spice and MATLAB are closely matched. Additionally, results from the multi-SIM platform show how a secure communication network was implemented utilising the master-slave technique of synchronisation. Finally, a comparison analysis is conducted to demonstrate the originality of the suggested work.

Published

2023

36. Securing Healthcare Data in IoMT Network Using Enhanced Chaos Based Substitution and Diffusion.

Author

Ahmad, Musheer, Alkanhel, Reem Ibrahim, Soliman, Naglaa F., Algarni, Abeer D., El-Samie, Fathi E. Abd, and El-Shafai, Walid

Subjects

MEDICAL care, PATIENTS' attitudes, INTERNET of things, DATA encryption, DATA protection

Abstract

Patient privacy and data protection have been crucial concerns in Ehealthcare systems for many years. In modern-day applications, patient data usually holds clinical imagery, records, and other medical details. Lately, the Internet of Medical Things (IoMT), equipped with cloud computing, has come out to be a beneficial paradigm in the healthcare field. However, the openness of networks and systems leads to security threats and illegal access. Therefore, reliable, fast, and robust security methods need to be developed to ensure the safe exchange of healthcare data generated from various image sensing and other IoMT-driven devices in the IoMT network. This paper presents an image protection scheme for healthcare applications to protect patients' medical image data exchanged in IoMT networks. The proposed security scheme depends on an enhanced 2D discrete chaotic map and allows dynamic substitution based on an optimized highly-nonlinear S-box and diffusion to gain an excellent security performance. The optimized S-box has an excellent nonlinearity score of 112. The new image protection scheme is efficient enough to exhibit correlation values less than 0.0022, entropy values higher than 7.999, and NPCR values around 99.6%. To reveal the efficacy of the scheme, several comparison studies are presented. These comparison studies reveal that the novel protection scheme is robust, efficient, and capable of securing healthcare imagery in IoMT systems. [ABSTRACT FROM AUTHOR]

Published

2023

37. Intelligent Reflecting Surface Aided Secure Communication with Federated Learning.

Author

Bowen Lu, Shiwei Lai, Yajuan Tang, Tao Cui, Chengyuan Fan, Jianghong Ou, and Dahua Fan

Subjects

FEDERATED learning, LITERATURE reviews, WIRELESS channels, TEACHING aids

Abstract

Applying federated learning into the covert communication can not only ensure the communication reliability, but also reduce the probability of enemy detection. The use of airspace resources is an effective way to achieve covert communication. However, most of the existing works on the airspace covert communication represented by MIMO need to adapt to the channel state and cannot improve the channel, resulting in the performance bottleneck of covert communication. The intelligent reflective surface (IRS) provides a new perspective for the covert communication by flexibly adjusting the reflection phase shift of the incident signal and intelligently configuring the wireless channel. However, the potential of IRS in the covert communication is far from being fully exploited. To solve this issue, this paper firstly performs a comprehensive literature review on the secure communication with the aid of federated learning, and then gives some challenges on the secure communication in poor channel state. In further, this paper provides some solutions to the challenges on the secure communication, where some results are provided to show the advantages. The research results have important theoretical and practical significance for forming a new research paradigm of airspace intelligent and controllable covert communication and promoting the application and popularization of covert communication in various fields of security. [ABSTRACT FROM AUTHOR]

Published

2023

38. Designing a Secure Mechanism for Image Transferring System Based on Uncertain Fractional Order Chaotic Systems and NLFPID Sliding Mode Controller.

Author

Rasouli, Mohammad, Zare, Assef, Yaghoubi, Hassan, and Alizadehsani, Roohallah

Subjects

*UNCERTAIN systems, *ADAPTIVE fuzzy control, *IMAGING systems, *TIME delay systems, *ADAPTIVE control systems, *CHAOS synchronization, *ENTROPY (Information theory), *SLIDING wear

Abstract

A control method for the robust synchronization of a class of chaotic systems with unknown time delay, unknown uncertainty, and unknown disturbance is presented. The robust controller was designed using a nonlinear fractional order PID sliding surface. The Lyapunov method was used to determine the update laws, prove the stability of the proposed mechanism, and guarantee the convergence of the synchronization errors to zero. The simulation was performed using MATLAB software to evaluate the performance of the proposed mechanism, and the results showed that it was efficient. Finally, the proposed method was combined with a secure communication application to encrypt images, and the results obtained were favorable regarding the standard criteria of correlation, NPCR, PSNR, and information entropy. [ABSTRACT FROM AUTHOR]

Published

2023

39. Relay Selection and Power Control to Maximize Energy Efficiency in Two-Way Relay Network with Network Coding and Non-Orthogonal Multiple Access

Author

Akbar Asgharzadeh-Bonab and Hashem Kalbkhani

Subjects

secure communication, relay selection, energy efficiency, two-way relay network, power control, Military Science

Abstract

Non-othogonal multiple access (NOMA), as a promising technology, increases spectral efficiency and system capacity by allocating a resource block to multiple users. Network coding (NC) has the advantages of data compression and high spectral efficiency and plays an important role in two-way relay networks. However, conventional two-way relay networks suffer from transmission power limitations due to the use of mrthogonal multiple access (OMA). The performance of this type of network depends on the selected relay and the transmission power. In this paper, considering the need for secure communications and also the energy limitation in military communications, a method is proposed for relay selection and transmission power control to maximize energy efficiency in two-way relay networks with network coding and power control taking into account the limits of the maximum transmission power and the minimum acceptable spectral efficiency. To solve this problem, it is converted into two sub-problems and first, for each candidate relay, the transmission power is calculated to maximize the energy efficiency. Finally, the relay candidate with the maximum energy efficiency is selected as the final relay. The performance of the proposed model is evaluated in terms of spectral efficiency, energy efficiency, and the possibility of disconnection in different transmitted signal-to-noise ratios (SNR). Also, the effect of the number of candidate relays and the minimum acceptable spectral efficiency on the system efficiency has been investigated. The results show that network coding in NOMA communications increases the spectral efficiency and energy efficiency and reduces the outage possibility.

Published

2023

40. SCIM: Incorporating secure communication and interference management in one operation

Author

Zhao Li, Pintian Lyu, Jun Li, Zhixian Chang, Jia Liu, and Zheng Yan

Subjects

Physical-layer security, Secure communication, Anti-eavesdropping, Interference management, Secrecy rate, Information technology, T58.5-58.64

Abstract

Due to the broadcast nature of wireless communications, users’ data transmitted wirelessly is susceptible to security/privacy threats. Meanwhile, as a result of the limitation of spectrum resources, massive wireless connections will incur serious interference, which may damage the efficiency of data transmission. Therefore, improving both efficiency and secrecy of data transmission is of research significance. In this paper, we propose a wireless transmission scheme by taking both Secure Communication (SC) and Interference Management (IM) into account, namely SCIM. With this scheme, an SCIM signal is generated by the legitimate transmitter (Tx) and sent along with the desired signal, so that the SCIM signal can interact with and suppress the environmental interference at the legitimate receiver (Rx). Meanwhile, the SCIM signal may interfere with the eavesdropper in the coverage of legitimate transmission so as to deteriorate the eavesdropping performance. Therefore, the secrecy of desired transmission is improved. In this way, both the transmission efficiency and privacy are enhanced. Then, by taking various transmission preferences into account, we develop different implementations of SCIM, including Interference Suppression First SCIM (ISF-SCIM), Data Transmission First SCIM (DTF-SCIM), Anti-Eavesdropping First SCIM (AEF-SCIM), and Secrecy Rate Maximization SCIM (SRM-SCIM). Our in-depth simulation results have shown the proposed methods to effectively improve the efficiency and secrecy of the legitimate transmission.

Published

2023

41. A high efficient next generation reservoir computing to predict and generate chaos with application for secure communication

Author

Leisheng Jin, Zhuo Liu, Ai Guan, Zhen Wang, Rui Xue, and Lijie Li

Subjects

chaos synchronisation, data‐driven, next generation reservoir computing, secure communication, time series prediction, Telecommunication, TK5101-6720

Abstract

Abstract In this work, a high efficient next generation reservoir computing (HENG‐RC) paradigm that adopts the principle of local states correlation and attention mechanism is proposed, which is able to process dynamical information generated by both the low dimensional and very large spatiotemporal chaotic systems (VLSCS). From a dynamical system perspective, the dynamical characteristics such as density distribution, Poincaré plots and max Lyapunov exponents of the proposed HENG‐RC are studied. It is revealed that the trained model can be seen as a data‐driven chaotic system. Furthermore, a novel scheme of secure communication based on chaotic synchronization of two HENG‐RC systems is designed, of which the security is enhanced as the intruder needs to know simultaneously the training signal and details of the parameter setting in the HENG‐RC. The digital implementation using field programmable gate array is experimentally realised, proving the feasibility of the secure communication scheme.

Published

2023

42. Efficient Data Management in Agricultural IoT: Compression, Security, and MQTT Protocol Analysis

Author

Mislav Has, Dora Kreković, Mario Kušek, and Ivana Podnar Žarko

Subjects

internet of things, precision agriculture, data compression, secure communication, resource optimization, Chemical technology, TP1-1185

Abstract

The integration of Internet of Things (IoT) technology into agriculture has revolutionized farming practices by using connected devices and sensors to optimize processes and facilitate sustainable execution. Because most IoT devices have limited resources, the vital requirement to efficiently manage data traffic while ensuring data security in agricultural IoT solutions creates several challenges. Therefore, it is important to study the data amount that IoT protocols generate for resource-constrained devices, as it has a direct impact on the device performance and overall usability of the IoT solution. In this paper, we present a comprehensive study that focuses on optimizing data transmission in agricultural IoT solutions with the use of compression algorithms and secure technologies. Through experimentation and analysis, we evaluate different approaches to minimize data traffic while protecting sensitive agricultural data. Our results highlight the effectiveness of compression algorithms, especially Huffman coding, in reducing data size and optimizing resource usage. In addition, the integration of encryption techniques, such as AES, provides the security of the transmitted data without incurring significant overhead. By assessing different communication scenarios, we identify the most efficient approach, a combination of Huffman encoding and AES encryption, to strike a balance between data security and transmission efficiency.

Published

2024

43. Realization of Authenticated One-Pass Key Establishment on RISC-V Micro-Controller for IoT Applications

Author

Tuan-Kiet Dang, Khai-Duy Nguyen, Binh Kieu-Do-Nguyen, Trong-Thuc Hoang, and Cong-Kha Pham

Subjects

IoT, secure communication, key establishment, signcryption, ECQV, RISC-V, Information technology, T58.5-58.64

Abstract

Internet-of-things networks consist of multiple sensor devices spread over a wide area. In order to protect the data from unauthorized access and tampering, it is essential to ensure secure communication between the sensor devices and the central server. This security measure aims to guarantee authenticity, confidentiality, and data integrity. Unlike traditional computing systems, sensor node devices are often limited regarding memory and computing power. Lightweight communication protocols, such as LoRaWAN, were introduced to overcome these limitations. However, despite the lightweight feature, the protocol is vulnerable to different types of attacks. This proposal presents a highly secure key establishment protocol that combines two cryptography schemes: Elliptic Curve Qu–Vanstone and signcryption key encapsulation. The protocol provides a method to establish a secure channel that inherits the security properties of the two schemes. Also, it allows for fast rekeying with only one exchange message, significantly reducing the handshake complexity in low-bandwidth communication. In addition, the selected schemes complement each other and share the same mathematical operations in elliptic curve cryptography. Moreover, with the rise of a community-friendly platform like RISC-V, we implemented the protocol on a RISC-V system to evaluate its overheads regarding the cycle count and execution time.

Published

2024

44. An n-Dimensional Chaotic Map with Application in Reversible Data Hiding for Medical Images

Author

Yuli Yang, Ruiyun Chang, Xiufang Feng, Peizhen Li, Yongle Chen, and Hao Zhang

Subjects

chaotic map, reversible data hiding, privacy protection, secure communication, Science, Astrophysics, QB460-466, Physics, QC1-999

Abstract

The drawbacks of a one-dimensional chaotic map are its straightforward structure, abrupt intervals, and ease of signal prediction. Richer performance and a more complicated structure are required for multidimensional chaotic mapping. To address the shortcomings of current chaotic systems, an n-dimensional cosine-transform-based chaotic system (nD-CTBCS) with a chaotic coupling model is suggested in this study. To create chaotic maps of any desired dimension, nD-CTBCS can take advantage of already-existing 1D chaotic maps as seed chaotic maps. Three two-dimensional chaotic maps are provided as examples to illustrate the impact. The findings of the evaluation and experiments demonstrate that the newly created chaotic maps function better, have broader chaotic intervals, and display hyperchaotic behavior. To further demonstrate the practicability of nD-CTBCS, a reversible data hiding scheme is proposed for the secure communication of medical images. The experimental results show that the proposed method has higher security than the existing methods.

Published

2024

45. Novel Integer Shmaliy Transform and New Multiparametric Piecewise Linear Chaotic Map for Joint Lossless Compression and Encryption of Medical Images in IoMTs.

Author

Daoui, Achraf, Mao, Haokun, Yamni, Mohamed, Li, Qiong, Alfarraj, Osama, and Abd El-Latif, Ahmed A.

Subjects

*IMAGE encryption, *LINEAR operators, *DIAGNOSTIC imaging, *LOSSLESS data compression, *IMAGE reconstruction, *INTEGERS, *IMAGE processing

Abstract

The discrete Shmaliy moment transform (DST) is a type of discrete orthogonal moment transform that is widely used in signal and image processing. However, DST is not suitable for lossless image applications due to its non-integer reversible nature. To overcome this limitation, we introduce the integer discrete Shmaliy transform (IDST) that performs integer-to-integer encoding, leading to a perfect and unique reconstruction of the input image. Next, a new 1D chaotic system model, the 1D multiparametric piecewise linear chaotic map (M-PWLCM), is presented as an extension of the existing 1D PWLCM. The M-PWLCM includes eight control parameters defined over an unlimited interval. To demonstrate the relevance of IDST and M-PWLCM in reversible image processing applications, they are used in a new scheme for lossless compression and encryption of medical images in the internet of medical things (IoMTs). On the one hand, the simulation results show that our scheme offers a good compression ratio and a higher level of security to resist differential attacks, brute force attacks and statistical attacks. On the other hand, the comparative analysis carried out shows the overall superiority of our scheme over similar state-of-the-art ones, both in achieving a higher compression ratio and better security when communicating medical images over unsecured IoMTs. [ABSTRACT FROM AUTHOR]

Published

2023

46. Projective Synchronization of Delayed Uncertain Coupled Memristive Neural Networks and Their Application.

Author

Han, Zhen, Chen, Naipeng, Wei, Xiaofeng, Yuan, Manman, and Li, Huijia

Subjects

*SYNCHRONIZATION, *NEURAL circuitry, *COMPUTER simulation

Abstract

In this article, the authors analyzed the nonlinear effects of projective synchronization between coupled memristive neural networks (MNNs) and their applications. Since the complete signal transmission is difficult under parameter mismatch and different projective factors, the delays, which are time-varying, and uncertainties have been taken to realize the projective synchronization of MNNs with multi-links under the nonlinear control method. Through the extended comparison principle and a new approach to dealing with the mismatched parameters, sufficient criteria have been determined under different types of projective factors and the framework of the Lyapunov–Krasovskii functional (LKF) for projective convergence of the coupled MNNs. Instead of the classical treatment for secure communication, the concept of error of synchronization between the drive and response systems has been applied to solve the signal encryption/decryption problem. Finally, the simulations in numerical form have been demonstrated graphically to confirm the adaptability of the theoretical results. [ABSTRACT FROM AUTHOR]

Published

2023

47. New approaches to the development of information security systems for unmanned vehicles.

Author

Ermukhambetova, Bayana B., Mun, Grigoriy A., Kabdushev, Sherniyaz B., Kadyrzhan, Aruzhan Bulatovna, Kadyrzhan, Kaisarali K., Vitulyova, Yelizaveta S., and Suleimenov, Ibragim E.

Subjects

INFORMATION technology security, SECURITY systems, AUTONOMOUS vehicles, INFORMATION storage & retrieval systems, OPTICAL elements, REMOTELY piloted vehicles

Abstract

A new approach to ensuring information security is proposed for using in the zone of direct radio visibility. The approach is based on a direct analogy between radio and optical radiation. In the latter case, information protection can be ensured by identifying the point or direction from which the signal comes; all other light sources are cut off by the observer. It is shown that a similar method of information protection can also be implemented in the radio range, which corresponds to modern trends in the development of radio holography. The simplest scheme for detecting the direction to a transmitter, identified as "friend" is presented. Its operability is demonstrated by means of simulation modeling. Ways for the further development of this approach are determined, based on the fact that modern technologies make it possible to implement distributed reception of a radio signal (to use a relatively large number of receivers), which makes it possible to implement direct analogues of such optical elements as a lens, holograms. [ABSTRACT FROM AUTHOR]

Published

2023

48. Blockchain-Enabled Communication Framework for Secure and Trustworthy Internet of Vehicles.

Author

Biswas, Manju, Das, Debashis, Banerjee, Sourav, Mukherjee, Amrit, AL-Numay, Waleed, Biswas, Utpal, and Zhang, Yudong

Abstract

The emerging field of the Internet of Vehicles (IoV) has garnered significant attention due to its potential to revolutionize transportation and mobility. IoV enables the development of innovative services and applications that can enhance the efficiency, safety, and sustainability of transportation systems. However, ensuring secure and reliable communication among different components of an IoV system poses a critical challenge. This study proposes a blockchain-based communication framework for secure and trustworthy IoV applications. The framework utilizes blockchain technology's decentralization and security features to create secure communication channels between IoV system components, including vehicles, infrastructure, and service providers. An identity management system is also integrated into the framework to authenticate and authorize users and devices, thereby preventing unauthorized access and data breaches. To assess the proposed framework's effectiveness, real-world IoV scenarios were used to conduct experiments, and the results demonstrate that the framework can provide secure and trustworthy communication for IoV applications. The proposed blockchain-enabled communication framework provides a promising solution for addressing security and trust challenges in IoV communication systems. [ABSTRACT FROM AUTHOR]

Published

2023

49. Adaptive nonsingular integral-type dynamic terminal sliding mode synchronizer for disturbed nonlinear systems and its application to secure communication systems.

Author

Vaseghi, Behrouz, Mobayen, Saleh, Din, Sami ud, Hashemi, Seyedeh Somayeh, and Vu, Mai The

Subjects

*TELECOMMUNICATION systems, *NONLINEAR systems, *SLIDING mode control, *DATA transmission systems, *CHAOTIC communication, *ADAPTIVE fuzzy control, *DIGITAL communications

Abstract

This study proposes an adaptive nonsingular integral dynamic terminal sliding mode tracker/synchronizer for disturbed nonlinear systems along with its usage in safe communication systems. The convergence of the closed-loop structure under unknown uncertainty and disturbances is guaranteed via Lyapunov analysis. Furthermore, a parameter-tuning method is planned to approximate the upper bound of uncertainty and disturbance terms, since this latter is typically unknown in practice. The proposed approach is used to design a digital secure transmission scheme according to the chaotic systems. The effectiveness of the suggested approach is validated using computer simulations on a benchmark example of chaotic system. The obtained outcomes clearly confirm the ability of the planned control approach enables to attain the desired tracking/synchronizing performance despite the disturbances. Additionally, when implemented to the data encryption of a communication system, the proposed control and secure communication techniques enabled the complete and secure retrieval of the original digital sequences. [ABSTRACT FROM AUTHOR]

Published

2023

50. A NOVEL EFFICIENT SECURITY VERIFICATION TECHNIQUE BASED ON SERVICE PACKAGE IDENTIFIER IN WIRELESS MOBILE AD-HOC NETWORKS.

Author

Kantharaju, H. C., Apurva, V. V., Gopinathan, B., and Nallathambi, A.

Subjects

AD hoc computer networks

Abstract

This paper presents a novel and efficient security verification technique for Wireless Mobile Ad-Hoc Networks (MANETs) using The Service Package Identifier (SPI). The dynamic and self-organizing nature of MANETs makes them susceptible to a variety of security threats. Using the SPI, the proposed technique authenticates and verifies the integrity of service bundles exchanged between network nodes. By employing the SPI as a unique identifier for each service packet, the technique protects against unauthorized access and data tampering and ensures secure communication. The experimental results demonstrate the efficacy and efficiency of the proposed technique, which offers improved MANET security and resiliency. [ABSTRACT FROM AUTHOR]

Published

2023