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168 results on '"Ahmed Lakhssassi"'

1. Quantum Entropy and Reinforcement Learning for Distributed Denial of Service Attack Detection in Smart Grid

Author

Dhaou Said, Miloud Bagaa, Aziz Oukaira, and Ahmed Lakhssassi

Subjects
Artificial intelligence, cybersecurity, distributed denial of service, machine learning, quantum computing, quantum reinforcement learning, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

Distributed Denial of Service (DDoS) threats in Smart Grid are very challenging and considered one of the most destructive cyber-attacks. They are harmfully affecting the power sector and causing substantial financial loss. Classical Reinforcement Learning (RL) models are proposed as a promising solution to the DDoS problem as they learn optimal mitigation policies under different attack scenarios. However, as the RL environment is generally dynamic, which leads to more computation capabilities, classical RL efficiency can be limited as a result of serial processing using classical computing. In this paper, a Quantum Entropy Q-Learning (QEQ) is proposed to fight DDoS in Smart Grid. The proposed framework is compared to a classical Q-Learning (QL) model with and without the Entropy method. The convergence speed and the total rewards performed with the same conditions for QL and are Entropy Q-Learning (EQ) are analyzed to show the QEQ performance. Moreover, the accuracy, precision, recall, and F1 score are evaluated to prove the effectiveness of our QEQ in fighting DDoS attacks. Using the Canadian Institute for Cybersecurity Intrusion Detection System (CICIDS 2019) dataset, a thorough systematic simulation using MATLAB, Python, the open-source Qiskit software, and the Harrow-Hassidim-Lloyd (HHL) quantum algorithm is carried out. This proposed QEQ is better performing the DDoS detection as it is faster enough and more adaptable to dynamic environment changing and able to improve the agent’s decision-making in a changing state action space. Finally, conclusions with some open issues of the Quantum Q-Learning are presented.

Published
2024
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2. Novel Peak-Source-Scanning (NPSS) Model for Thermal Control of Systems-in-Package (SiP)

Author

Aziz Oukaira, Dhaou Said, Djallel Eddine Touati, Nader El-Zarif, Ahmad Hassan, Yvon Savaria, and Ahmed Lakhssassi

Subjects
Peak source-scanning, system-in-package, thermal control, thermal monitoring, thermal peak, finite element method, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

One of the fast-growing electronic integration technologies in the modern high-density microelectronics industry is System-in-Package (SiP). It is expected to accelerate application development when reducing implementation risks with optimized codes. However, monitoring the thermal behavior of every chip in SiPs is challenging. This paper proposes a Novel Peak Source-Scanning (NPSS) algorithm based on the Gradient Direction Sensors (GDS) method. The proposed algorithm can detect and locate thermal peaks on any SiP. Detecting such peaks is vital for thermal monitoring and stress management on high-density semiconductor devices to avoid induced thermo-mechanical stresses. Furthermore, the NPSS algorithm can manage and monitor silicon chips with Multiple Heat Sources (MHS). To assess this algorithm, we used tools from COMSOL Multiphysics® and MATLAB® for Temperature-prediction (Tp), and Temperature-estimation (Te), respectively. Our simulations use the generalized GDS methodology for MHS using the finite element method (FEM) to highlight our NPSS capabilities to predict on-chip thermal peaks with a maximum error of 1.27 K (Kelvin).

Published
2024
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3. The Applications and Challenges of Digital Twin Technology in Smart Grids: A Comprehensive Review

Author

Nabil Mchirgui, Nordine Quadar, Habib Kraiem, and Ahmed Lakhssassi

Subjects
digital twins, smart grids, artificial intelligence, Internet of Things, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999
Abstract

This comprehensive review explores the applications and challenges of Digital Twin (DT) technology in smart grids. As power grid systems rapidly evolve to meet the increasing energy demands and the new requirements of renewable source integration, DTs offer promising solutions to enhance the monitoring, control, and optimization of these systems. In this paper, we examine the concept of DTs in the context of smart grids, and their requirements, challenges, and integration with the Internet of Things (IoT) and Artificial Intelligence (AI). We also discuss different applications in asset management, system operation, and disaster response. This paper analyzes current challenges, including data management, interoperability, cost, and ethical considerations. Through case studies from various sectors in Canada, we illustrate the real-world implementation and impact of DTs. Finally, we discuss emerging trends and future directions, highlighting the potential of DTs to revolutionize smart grid networks and contribute to more efficient, reliable, and sustainable power systems.

Published
2024
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4. A compact meander flexible UHF tag for industrial applications

Author

Latifa El Ahmar, Ahmed Errkik, Jamal Zbitou, Aziz Oukaira, Ilham Bouzida, Larbi Talbi, and Ahmed Lakhssassi

Subjects
ACP, Loop, Meander line technique, Polyamide, Radiofrequency identification, UHF Tag, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

The objective of this paper is to introduce a novel design for a flexible Ultra-High Frequency tag (UHF tag) through the utilization of the meander line technique (MLA) and loop antenna method. The primary goal is to achieve a compact UHF tag operating at 868 MHz. The physical dimensions of the UHF tag are 110×12×0.1mm3. The proposed UHF tag is manufactured using the inkjet printing method on a polyamide substrate featuring a relative dielectric constant of 3.5, a tangent loss of 0.0027, and a height of 0.0508 mm. Through electromagnetic simulation and validation, the functionality of the proposed UHF tag covers the UHF band ranging from 854.57 to 883.89 MHz, with a bandwidth of 29.32 MHz. The reflection coefficient at 868 MHz is approximately -22.46 dB. The simulated gain measures 1.79 dBi, while the theoretical read range is estimated at 5 m. The UHF tag is produced using silver ink with a thickness of 0.05 mm and assembled using an anisotropic conductive paste (ACP). Subsequent to electromagnetic simulation, the UHF tag’s performance is confirmed through a reading test conducted with a radio frequency identification (RFID) base station. The results are consistent with the theoretical expectations, showcasing a commendable read range of 5 m. To safeguard the UHF tag from challenging environmental conditions, it is enclosed within a polyethylene film (PE). Following encapsulation, the read range decreases to 3 m, making it suitable for RFID applications requiring mid-range capabilities.

Published
2024
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5. LabPET II scanner performances improvement: Thermal stability control based on FPGA

Author

Aziz Oukaira, Dhaou Said, Jamal Zbitou, Réjean Fontaine, and Ahmed Lakhssassi

Subjects
Application-specific integrated circuit, Computational fluid dynamics (CFD), Field-programmable gate array (FPGA), Finite element method (FEM), Positron emission tomography (PET), Thermo-electric cooler (TEC), Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

The LabPET II detection module serves as the fundamental component within Positron Emission Tomography (PET) scanners designed for achieving ultra-high-resolution imaging of small to medium-sized animals as well as the human brain. To ensure peak performance, it is imperative that this module operates consistently at a stable temperature. In this paper, we present an automatic and real-time method to improve the thermal control of the scanner LabPET II by evacuating the heat to reduce the overall temperature and maintain the thermal stability of the system. Based on the Thermo-Electric Cooler (TEC) process, our method applies two numerical techniques, Computational Fluid Dynamics (CFD) and Heat Transfer Analysis (HTA). The Dirichlet Boundary Conditions (DBC) method is applied for the Application-Specific Integrated Circuit (ASIC) at 25∘ C. The real measurements confirm and validate the simulation results with the Finite Element Method (FEM) based on the software COMSOL Multiphysics™. Field-Programmable Gate Array (FPGA) implementation on the Development and Education (DE1) board is performed with comparative results study. The proposed method is both simple and practical, and ensures thermal stability at 35∘C for the duration of operation of the scanner, which has a complex structure.

Published
2023
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6. A Novel Hybrid Multikey Cryptography Technique for Video Communication

Author

Youcef Fouzar, Ahmed Lakhssassi, and M. Ramakrishna

Subjects
Asymmetric key cryptography, multi-key encryption, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

Online video streaming is becoming more widespread in people’s everyday entertainment routines. Protecting copyright and piracy has become a key concern in real-time video streaming systems. This research provides a revolutionary multi-key and hybrid cryptography approach to offer security. This work describes the software implementation of video encryption and decryption employing continuous systems based on the Elliptic Curve Cryptography approach as pseudorandom encryption key generators. This approach creates several keys to encrypt and decode small chunks of video files that are produced dynamically based on the video data. The suggested approach was implemented on the Android platform, where applications for sender and recipients had been created to enable streaming. The security and performance of the proposed system have been examined by implementing it on devices and streaming videos. The outcomes demonstrate superiority in terms of performance and security.

Published
2023
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7. Secure Video Communication Using Multi-Equation Multi-Key Hybrid Cryptography

Author

Youcef Fouzar, Ahmed Lakhssassi, and Ramakrishna Mundugar

Subjects
asymmetric key cryptography, multi-key encryption, dynamic key generation, Information technology, T58.5-58.64
Abstract

The safeguarding of intellectual property and maintaining privacy for video content are closely linked to the effectiveness of security protocols employed in internet streaming platforms. The inadequate implementation of security measures by content providers has resulted in security breaches within entertainment applications, hence causing a reduction in the client base. This research aimed to enhance the security measures employed for video content by implementing a multi-key approach for encryption and decryption processes. The aforementioned objective was successfully accomplished through the use of hybrid methodologies, the production of dynamic keys, and the implementation of user-attribute-based techniques. The main aim of the study was to improve the security measures associated with the process of generating video material. The proposed methodology integrates a system of mathematical equations and a pseudorandom key within its execution. This novel approach significantly augments the degree of security the encryption mechanism provides. The proposed methodology utilises a set of mathematical equations that are randomly employed to achieve encryption. Using a random selection procedure contributes to the overall enhancement of the system’s security. The suggested methodology entails the division of the video into smaller entities known as chunks. Following this, every segment is subjected to encryption using unique keys that are produced dynamically in real-time. The proposed methodology is executed via Android platforms. The transmitter application is tasked with the responsibility of facilitating the streaming of the video content, whereas the receiver application serves the purpose of presenting the video to the user. A careful study was conducted to compare and contrast the suggested method with other similar methods that were already in use. The results of the study strongly support the safety and dependability of the procedure that was made available.

Published
2023
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8. A new configuration of a compact printed coplanar low pass filter with high rejection

Author

Fouad Aytouna, Jamal Zbitou, Ahmed Lakhssassi, and Mohammed Benbrahim

Subjects
Wireless transmission, Microwave filters, CPW Lines, Planar filters, Microstrip lines, Electrical engineering. Electronics. Nuclear engineering, TK1-9971
Abstract

The aim of this contribution is a new study on the achievement, fabrication and the test of a new low pass filter (LPF) coplanar structure based on periodic resonators. The proposed structure can be easly integrated with microwave devices, the validated LPF circuit has a wide band pass and high band stop. The design was done by two electromagnetic (EM) solvers one is based on moment method and the other one on finite integration technique. In order to reach a final LPF structure with good characteristics concerning the insertion loss of−0.8 dB and high attenuation until 15 GHz, the cut-off frequency of this filter is equal to 6,77 GHz. Many series of optimization were conducted using multiple algorithms. The whole area of the validated LPF is16×40 mm2.

Published
2022
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9. Towards Real-Time Monitoring of Thermal Peaks in Systems-on-Chip (SoC)

Author

Aziz Oukaira, Ahmad Hassan, Mohamed Ali, Yvon Savaria, and Ahmed Lakhssassi

Subjects
Field-Programmable Gate Array (FPGA), Integrated Circuits (ICs), System on Chip (SoC), Gradient Direction Sensor (GDS), thermal camera, thermal monitoring, Chemical technology, TP1-1185
Abstract

This paper presents a method to monitor the thermal peaks that are major concerns when designing Integrated Circuits (ICs) in various advanced technologies. The method aims at detecting the thermal peak in Systems on Chip (SoC) using arrays of oscillators distributed over the area of the chip. Measured frequencies are mapped to local temperatures that are used to produce a chip thermal mapping. Then, an indication of the local temperature of a single heat source is obtained in real-time using the Gradient Direction Sensor (GDS) technique. The proposed technique does not require external sensors, and it provides a real-time monitoring of thermal peaks. This work is performed with Field-Programmable Gate Array (FPGA), which acts as a System-on-Chip, and the detected heat source is validated with a thermal camera. A maximum error of 0.3 °C is reported between thermal camera and FPGA measurements.

Published
2022
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10. A New Configuration Of Broadband Patch Antenna With Circular Polarization For Wireless Power Transmission

Author

Fatima Ouberri, Abdelali Tajmouati, Noha Chahboun, Larbi El Abdellaoui, and Ahmed Lakhssassi

Subjects
wireless power transmission, wide-band, circular polarization, patch antenna, l-shaped, Environmental sciences, GE1-350
Abstract

An innovative design of a circular polarization antenna for wireless power transmission is described. The suggested antenna is simply constructed, which consists of a square radiating patch having a slotted center with feeding via a probe and an L-shaped ground plane. The application of this L-shaped ground allows a short connection of the probe power supply to the square patch while retaining a certain elevation from the ground plane to the square patch while using an air layer substrate, thereby allows a proper adaptation of the impedance and an improvement of the bandwidth. The purpose of utilizing the slot in the center of the square patch is to create a circular polarization with an axial ratio value of under 3dB. By means of a through-hole through the vertical L-shaped ground plane, the patch radiating can be readily excited with a probe feed pointing into the same plane as the patch. This approach allows to further improve the bandwidth of the circular polarization. In this way, the CP bandwidth of the proposed antenna is significantly extended by about 10% and a good impedance matching over a wide bandwidth is obtained. The features of the proposed design are investigated and optimized using a 3D electromagnetic (EM) solver. It was found that the proposed antenna covers a broad band of 425MHz, has a 3 dB axial ratio CP bandwidth of approx. 85% of the resonant band, and a gain level of 7.4 dBi or more in the bandwidth of the resonant band. Besides the low cost of the proposed antenna arising from its simplest structure, the resulting performance leads the antenna to be a strong candidate among circularly polarized, single element, and single feed patch antennas.

Published
2022
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11. FPGA-Embedded Smart Monitoring System for Irrigation Decisions Based on Soil Moisture and Temperature Sensors

Author

Aziz Oukaira, Amrou Zyad Benelhaouare, Emmanuel Kengne, and Ahmed Lakhssassi

Subjects
smart monitoring system, irrigation, CMOS, FPGA, embedded system, Agriculture
Abstract

The basic need common to all living beings is water. Less than 1% of the water on earth is fresh water and water use is increasing daily. Agricultural practices alone require huge amounts of water. The drip technique improved the efficiency of water use in irrigation and initiated the introduction and development of fertigation, the integrated distribution of water and fertilizer. The past few decades have seen extensive research being carried out in the area of development and evaluation of different technologies available to estimate/measure soil moisture to aid in various applications and to facilitate the use of drip irrigation for users and farmers. In this technology, plant moisture and temperature are accurately monitored and controlled in real time over roots in the form of droplets, by developing smart monitoring system to save water and avoid water waste using drip irrigation technology. Water is delivered to the roots drop by drop, which saves water as well as prevents plants from being flooded and decaying due to excess water released by irrigation methods such as flood irrigation, border irrigation, furrow irrigation, and control basin irrigation. Drip irrigation with an embedded intelligent monitoring system is one of the most valuable techniques used to save water and farmers’ time and energy. In this paper, we design an embedded monitoring system based in the integrated 65 nm CMOS technology in agricultural practices which would facilitate agriculture and enable farmers to monitor crops. Hence, to demonstrate the feasibility, a prototype was constructed and simulated with modelsim and validated with nclaunch the both tools from Cadence, as well as implementation on the FPGA board, was be performed.

Published
2021
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12. A Real-Time Thermal Monitoring System Intended for Embedded Sensors Interfaces

Author

Ouafaa Ettahri, Aziz Oukaira, Mohamed Ali, Ahmad Hassan, Morteza Nabavi, Yvon Savaria, and Ahmed Lakhssassi

Subjects
thermal monitoring, industrial embedded applications, sensor interface, heat sources, FRDM-KL26Z, IC, Chemical technology, TP1-1185
Abstract

This paper proposes a real-time thermal monitoring method using embedded integrated sensor interfaces dedicated to industrial integrated system applications. Industrial sensor interfaces are complex systems that involve analog and mixed signals, where several parameters can influence their performance. These include the presence of heat sources near sensitive integrated circuits, and various heat transfer phenomena need to be considered. This creates a need for real-time thermal monitoring and management. Indeed, the control of transient temperature gradients or temperature differential variations as well as the prediction of possible induced thermal shocks and stress at early design phases of advanced integrated circuits and systems are essential. This paper addresses the growing requirements of microelectronics applications in several areas that experience fast variations in high-power density and thermal gradient differences caused by the implementation of different systems on the same chip, such as the new-generation 5G circuits. To mitigate adverse thermal effects, a real-time prediction algorithm is proposed and validated using the MCUXpresso tool applied to a Freescale embedded sensor board to monitor and predict its temperature profile in real time by programming the embedded sensor into the FRDM-KL26Z board. Based on discrete temperature measurements, the embedded system is used to predict, in advance, overheating situations in the embedded integrated circuit (IC). These results confirm the peak detection capability of the proposed algorithm that satisfactorily predicts thermal peaks in the FRDM-KL26Z board as modeled with a finite element thermal analysis tool (the Numerical Integrated elements for System Analysis (NISA) tool), to gauge the level of local thermomechanical stresses that may be induced. In this paper, the FPGA implementation and comparison measurements are also presented. This work provides a solution to the thermal stresses and local system overheating that have been a major concern for integrated sensor interface designers when designing integrated circuits in various high-performance technologies or harsh environments.

Published
2020
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31. Accurate On-Chip Thermal Peak Detection Based on Heuristic Algorithms and Embedded Temperature Sensors

Author

Savaria, Djallel Eddine Touati, Aziz Oukaira, Ahmad Hassan, Mohamed Ali, Ahmed Lakhssassi, and Yvon

Subjects
finite element analysis (FEA), finite element method (FEM), GDS, heat transfer
Abstract

The reliability and lifetime of systems-on-chip (SoCs) are being seriously threatened by thermal issues. In modern SoCs, dynamic thermal management (DTM) uses the thermal data captured by thermal sensors to constantly track the hot spots and thermal peak locations in real time. Estimating peak temperatures and the location of these peaks can play a crucial role for DTM systems, as temperature underestimation can cause SoCs to fail and have shortened lifetime. In this paper, a novel sensor allocation algorithm (called thermal gradient tracker, TGT), based on the recursive elimination of regions that likely do not contain any thermal peaks, is proposed for determining regions that potentially contain thermal peaks. Then, based on an empirical source temperature detection technique called GDS (gradient direction sensor), a hybrid algorithm for detecting the position and temperature of thermal peaks is also proposed to increase the accuracy of temperature sensing while trying to keep the number of thermal sensors to a minimum. The essential parameters, H and R, of the GDS technique are determined using an automated search algorithm based on simulated annealing. The proposed algorithm has been applied in a system-on-chip (SoC) in which four heat sources are present, and for temperatures ranging between 45 °C and 115 °C, in a chip area equal to 25 mm2. The simulation results show that our proposed sensor allocation scheme can detect on-chip peaks with a maximum error of 1.48 °C and an average maximum error of 0.49 °C by using 15 thermal sensors.

Published
2023
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35. An Advanced Array Configuration Antenna Based on Mutual Coupling Reduction

Author

Salaheddine Aourik, Ahmed Errkik, Aziz Oukaira, Dhaou Said, Jamal Zbitou, and Ahmed Lakhssassi

Subjects
Computer Networks and Communications, Hardware and Architecture, Control and Systems Engineering, Signal Processing, microstrip antenna array, artificial magnetic conductor, 28 GHz, mutual coupling, Electrical and Electronic Engineering
Abstract

In this work, a microstrip antenna array that consists of 16 elements is designed at a frequency of 28 GHz, with a dimension of 35 mm × 33.5 mm and an operational bandwidth of 27.7–28.3 GHz. The idea is putting two antenna arrays next to each other on the same substrate and ground plane, as well as minimizing the overall size. This work presents a mutual coupling reduction for two arrays and studies the performance of the antennas through the suppression of surface wave propagation in a given frequency range. It proposed a new configuration for an artificial magnetic conductor (AMC) created by microstrip technology placed at a closed distance (0.3λ0) between the two antenna arrays. The improvement in the isolation between the two adjacent antenna arrays was studied according to the H-plane with a periodic unit cell of the AMC. The mutual coupling reduces to −40.0 dB at the operation frequency and isolation of 17 dB. The antenna array is also characterized by a good envelope correlation coefficient (ECC). The CST Microwave Studio electromagnetic solver was used to design, improve, and miniaturize the proposed configuration.

Published
2023
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45. Millimeter Wave Microstrip Antennas for Radar Applications in the Ka-Band

Author

Salaheddine Aourik, Ahmed Errkik, Jamal Zbitou, Rachid Mandry, and Ahmed Lakhssassi

Abstract

This chapiter starts with a general definition of the antennas. The next parts will talk about a microstrip antenna from the side of the double band in order to get an antenna that can do both reception and emission as well as developing the azimuth and angular resolution. This chapter has also introduced an antenna that separates the feeding part from the rayonnant one in an effective way that can enable us to develop the abilities of the radar antenna. Besides, it would also cope with the mechanic relation of the antenna. Another work has been presented to make electronic scanning more effective and faster. This would allow us to get rid of mechanic circulation by using butler matrix. Developing the antenna from the angular resolution has also been presented through widening the bandwidth by DGS technique and widening the reach via using the antenna array. Among the biggest problems are the surface waves and mutual coupling that present significant challenges to the designer because of their graduation of the antenna performance especially in the radar system.

Published
2023
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