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Aghabagherloo, Alireza, Mohajeri, Javad, Salmasizadeh, Mahmoud, Feghhi, Mahmood Mohassel.  2020.  An Efficient Anonymous Authentication Scheme Using Registration List in VANETs. 2020 28th Iranian Conference on Electrical Engineering (ICEE). :1—5.

Nowadays, Vehicular Ad hoc Networks (VANETs) are popularly known as they can reduce traffic and road accidents. These networks need several security requirements, such as anonymity, data authentication, confidentiality, traceability and cancellation of offending users, unlinkability, integrity, undeniability and access control. Authentication of the data and sender are most important security requirements in these networks. So many authentication schemes have been proposed up to now. One of the well-known techniques to provide users authentication in these networks is the authentication based on the smartcard (ASC). In this paper, we propose an ASC scheme that not only provides necessary security requirements such as anonymity, traceability and unlinkability in the VANETs but also is more efficient than the other schemes in the literatures.

Ahmad, Jawad, Tahir, Ahsen, Khan, Jan Sher, Khan, Muazzam A, Khan, Fadia Ali, Arshad, Habib, Zeeshan.  2019.  A Partial Ligt-weight Image Encryption Scheme. 2019 UK/ China Emerging Technologies (UCET). :1—3.

Due to greater network capacity and faster data speed, fifth generation (5G) technology is expected to provide a huge improvement in Internet of Things (IoTs) applications, Augmented & Virtual Reality (AR/VR) technologies, and Machine Type Communications (MTC). Consumer will be able to send/receive high quality multimedia data. For the protection of sensitive multimedia data, a large number of encryption algorithms are available, however, these encryption schemes does not provide light-weight encryption solution for real-time application requirements. This paper proposes a new multi-chaos computational efficient encryption for digital images. In the proposed scheme, plaintext image is transformed using Lifting Wavelet Transform (LWT) and only one-fourth part of the transformed image is encrypted using light-weight Chebyshev and Intertwining maps. Both chaotic maps were chaotically coupled for the confusion and diffusion processes which further enhances the image security. Encryption/decryption speed and other security measures such as correlation coefficient, entropy, Number of Pixels Change Rate (NPCR), contrast, energy, homogeneity confirm the superiority of the proposed light-weight encryption scheme.

B
Beheshti-Atashgah, Mohammad, Aref, Mohammd Reza, Bayat, Majid, Barari, Morteza.  2019.  ID-based Strong Designated Verifier Signature Scheme and its Applications in Internet of Things. 2019 27th Iranian Conference on Electrical Engineering (ICEE). :1486–1491.
Strong designated verifier signature scheme is a concept in which a user (signer) can issue a digital signature for a special receiver; i.e. signature is produced in such way that only intended verifier can check the validity of produced signature. Of course, this type of signature scheme should be such that no third party is able to validate the signature. In other words, the related designated verifier cannot assign the issued signature to another third party. This article proposes a new ID-based strong designated verifier signature scheme which has provable security in the ROM (Random Oracle Model) and BDH assumption. The proposed scheme satisfies the all security requirements of an ID-based strong designated verifier signature scheme. In addition, we propose some usage scenarios for the proposed schemes in different applications in the Internet of Things and Cloud Computing era.
C
Chheng, Kimhok, Priyadi, Ardyono, Pujiantara, Margo, Mahindara, Vincentius Raki.  2020.  The Coordination of Dual Setting DOCR for Ring System Using Adaptive Modified Firefly Algorithm. 2020 International Seminar on Intelligent Technology and Its Applications (ISITIA). :44—50.
Directional Overcurrent Relays (DOCRs) play an essential role in the power system protection to guarantee the reliability, speed of relay operation and avoiding mal-trip in the primary and backup relays when unintentional fault conditions occur in the system. Moreover, the dual setting protection scheme is more efficient protection schemes for offering fast response protection and providing flexibility in the coordination of relay. In this paper, the Adaptive Modified Firefly Algorithm (AMFA) is used to determine the optimal coordination of dual setting DOCRs in the ring distribution system. The AMFA is completed by choosing the minimum value of pickup current (\textbackslashtextbackslashpmbI\textbackslashtextbackslashpmbP) and time dial setting (TDS). On the other hand, dual setting DOCRs protection scheme also proposed for operating in both forward and reverse directions that consisted of individual time current characteristics (TCC) curve for each direction. The previous method is applied to the ring distribution system network of PT. Pupuk Sriwidjaja by considering the fault on each bus. The result illustration that the AMFA within dual setting protection scheme is significantly reaching the optimized coordination and the relay coordination is certain for all simulation scenarios with the minimum operation. The AMFA has been successfully implemented in MATLAB software programming.
F
F. Hassan, J. L. Magalini, V. de Campos Pentea, R. A. Santos.  2015.  "A project-based multi-disciplinary elective on digital data processing techniques". 2015 IEEE Frontiers in Education Conference (FIE). :1-7.

Todays' era of internet-of-things, cloud computing and big data centers calls for more fresh graduates with expertise in digital data processing techniques such as compression, encryption and error correcting codes. This paper describes a project-based elective that covers these three main digital data processing techniques and can be offered to three different undergraduate majors electrical and computer engineering and computer science. The course has been offered successfully for three years. Registration statistics show equal interest from the three different majors. Assessment data show that students have successfully completed the different course outcomes. Students' feedback show that students appreciate the knowledge they attain from this elective and suggest that the workload for this course in relation to other courses of equal credit is as expected.

Fathi, Z., Rafsanjani, A. J., Habibi, F..  2020.  Anon-ISAC: Anonymity-preserving cyber threat information sharing platform based on permissioned Blockchain. 2020 28th Iranian Conference on Electrical Engineering (ICEE). :1—5.

In cyber threat information sharing, secure transfer and protecting privacy are very important. In this paper we solve these issues by suggesting a platform based on private permissioned Blockchain, which provides us with access control as well. The platform is called Anon-ISAC and is built on the Enhanced Privacy ID (EPID) zero-knowledge proof scheme. It makes use of permissioned Blockchain as a way to keep identity anonymous. Organizations can share their information on incidents or other artifacts among trusted parties, while they keep their identity hidden. This will save them from unwanted consequences of exposure of sensitive security information.

H
Huang, Rui, Wang, Panbao, Zaery, Mohamed, Wei, Wang, Xu, Dianguo.  2019.  A Distributed Fixed-Time Secondary Controller for DC Microgrids. 2019 22nd International Conference on Electrical Machines and Systems (ICEMS). :1–6.

This paper proposes a distributed fixed-time based secondary controller for the DC microgrids (MGs) to overcome the drawbacks of conventional droop control. The controller, based on a distributed fixed-time control approach, can remove the DC voltage deviation and provide proportional current sharing simultaneously within a fixed-time. Comparing with the conventional centralized secondary controller, the controller, using the dynamic consensus, on each converter communicates only with its neighbors on a communication graph which increases the convergence speed and gets an improved performance. The proposed control strategy is simulated in PLECS to test the controller performance, link-failure resiliency, plug and play capability and the feasibility under different time delays.

J
Jin, H., Wang, T., Zhang, M., Li, M., Wang, Y., Snoussi, H..  2020.  Neural Style Transfer for Picture with Gradient Gram Matrix Description. 2020 39th Chinese Control Conference (CCC). :7026–7030.
Despite the high performance of neural style transfer on stylized pictures, we found that Gatys et al [1] algorithm cannot perfectly reconstruct texture style. Output stylized picture could emerge unsatisfied unexpected textures such like muddiness in local area and insufficient grain expression. Our method bases on original algorithm, adding the Gradient Gram description on style loss, aiming to strengthen texture expression and eliminate muddiness. To some extent our method lengthens the runtime, however, its output stylized pictures get higher performance on texture details, especially in the elimination of muddiness.
K
Kazemi, M., Delavar, M., Mohajeri, J., Salmasizadeh, M..  2018.  On the Security of an Efficient Anonymous Authentication with Conditional Privacy-Preserving Scheme for Vehicular Ad Hoc Networks. Iranian Conference on Electrical Engineering (ICEE). :510–514.

Design of anonymous authentication scheme is one of the most important challenges in Vehicular Ad hoc Networks (VANET). Most of the existing schemes have high computational and communication overhead and they do not meet security requirements. Recently, Azees et al. have introduced an Efficient Anonymous Authentication with Conditional Privacy-Preserving (EAAP) scheme for VANET and claimed that it is secure. In this paper, we show that this protocol is vulnerable against replay attack, impersonation attack and message modification attack. Also, we show that the messages sent by a vehicle are linkable. Therefore, an adversary can easily track the vehicles. In addition, it is shown that vehicles face with some problems when they enter in a new Trusted Authority (TA) range. As a solution, we propose a new authentication protocol which is more secure than EAAP protocol without increasing its computational and communication overhead.

M
Madanchi, Mehdi, Abolhassani, Bahman.  2020.  Authentication and Key Agreement Based Binary Tree for D2D Group Communication. 2020 28th Iranian Conference on Electrical Engineering (ICEE). :1—5.

Emerging device-to-device (D2D) communication in 5th generation (5G) mobile communication networks and internet of things (loTs) provides many benefits in improving network capabilities such as energy consumption, communication delay and spectrum efficiency. D2D group communication has the potential for improving group-based services including group games and group discussions. Providing security in D2D group communication is the main challenge to make their wide usage possible. Nevertheless, the issue of security and privacy of D2D group communication has been less addressed in recent research work. In this paper, we propose an authentication and key agreement tree group-based (AKATGB) protocol to realize a secure and anonymous D2D group communication. In our protocol, a group of D2D users are first organized in a tree structure, authenticating each other without disclosing their identities and without any privacy violation. Then, D2D users negotiate to set a common group key for establishing a secure communication among themselves. Security analysis and performance evaluation of the proposed protocol show that it is effective and secure.

S
Sagisi, J., Tront, J., Bradley, R. M..  2017.  Platform agnostic, scalable, and unobtrusive FPGA network processor design of moving target defense over IPv6 (MT6D) over IEEE 802.3 Ethernet. 2017 IEEE International Symposium on Hardware Oriented Security and Trust (HOST). :165–165.

This work presents the proof of concept implementation for the first hardware-based design of Moving Target Defense over IPv6 (MT6D) in full Register Transfer Level (RTL) logic, with future sights on an embedded Application-Specified Integrated Circuit (ASIC) implementation. Contributions are an IEEE 802.3 Ethernet stream-based in-line network packet processor with a specialized Complex Instruction Set Computer (CISC) instruction set architecture, RTL-based Network Time Protocol v4 synchronization, and a modular crypto engine. Traditional static network addressing allows attackers the incredible advantage of taking time to plan and execute attacks against a network. To counter, MT6D provides a network host obfuscation technique that offers network-based keyed access to specific hosts without altering existing network infrastructure and is an excellent technique for protecting the Internet of Things, IPv6 over Low Power Wireless Personal Area Networks, and high value globally routable IPv6 interfaces. This is done by crypto-graphically altering IPv6 network addresses every few seconds in a synchronous manner at all endpoints. A border gateway device can be used to intercept select packets to unobtrusively perform this action. Software driven implementations have posed many challenges, namely, constant code maintenance to remain compliant with all library and kernel dependencies, the need for a host computing platform, and less than optimal throughput. This work seeks to overcome these challenges in a lightweight system to be developed for practical wide deployment.

Shwartz, O., Birk, Y..  2016.  SDSM: Fast and scalable security support for directory-based distributed shared memory. 2016 IEEE International Conference on the Science of Electrical Engineering (ICSEE). :1–5.

Secure computation is increasingly required, most notably when using public clouds. Many secure CPU architectures have been proposed, mostly focusing on single-threaded applications running on a single node. However, security for parallel and distributed computation is also needed, requiring the sharing of secret data among mutually trusting threads running in different compute nodes in an untrusted environment. We propose SDSM, a novel hardware approach for providing a security layer for directory-based distributed shared memory systems. Unlike previously proposed schemes that cannot maintain reasonable performance beyond 32 cores, our approach allows secure parallel applications to scale efficiently to thousands of cores.