Publications

2016
Boudoukha C, Bouriche H, Ortega E, Senator A. Immunomodulatory effects of Santolina chamaecyparissus leaf extracts on human neutrophil functions. Pharmaceutical BiologyPharmaceutical Biology. 2016;54 :667-673.
Boudoukha C, Bouriche H, Ortega E, Senator A. Immunomodulatory effects of Santolina chamaecyparissus leaf extracts on human neutrophil functions. Pharmaceutical BiologyPharmaceutical Biology. 2016;54 :667-673.
Boudoukha C, Bouriche H, Ortega E, Senator A. Immunomodulatory effects of Santolina chamaecyparissus leaf extracts on human neutrophil functions. Pharmaceutical BiologyPharmaceutical Biology. 2016;54 :667-673.
Boudoukha C, Bouriche H, Ortega E, Senator A. Immunomodulatory effects of Santolina chamaecyparissus leaf extracts on human neutrophil functions. Pharmaceutical BiologyPharmaceutical Biology. 2016;54 :667-673.
Mahdjoub H. Immunophenotypage des leucemies aigues. Xeme congres de la SATH . 2016.
SEDRATI M, Taleb H. Impact of routing protocols on the quality of transmission for video streaming. International Conference on Internet of things and Cloud Computing [Internet]. 2016. Publisher's VersionAbstract
Mobile ad hoc networks are characterized by infrastructure less, dynamic topology, without any centralized administration, and limited resources witch make more difficult the stream of multimedia applications over wireless networks. Providing Quality of Service for video streaming is an important challenge. In this paper, firstly, we have reviewed many issues and different coding techniques for video streaming over MANET and secondly we propose to study two routing protocols (AODV and DSDV) to evaluate witch of them can improve QoS for real-time multimedia applications. Results show that AODV protocol performs better than DSDV in terms of throughput and network load with high mobility, but roles are reversed in terms of bit rate, loss rate and network load for large-scale networks.
SEDRATI M, Taleb H. Impact of routing protocols on the quality of transmission for video streaming. International Conference on Internet of things and Cloud Computing [Internet]. 2016. Publisher's VersionAbstract
Mobile ad hoc networks are characterized by infrastructure less, dynamic topology, without any centralized administration, and limited resources witch make more difficult the stream of multimedia applications over wireless networks. Providing Quality of Service for video streaming is an important challenge. In this paper, firstly, we have reviewed many issues and different coding techniques for video streaming over MANET and secondly we propose to study two routing protocols (AODV and DSDV) to evaluate witch of them can improve QoS for real-time multimedia applications. Results show that AODV protocol performs better than DSDV in terms of throughput and network load with high mobility, but roles are reversed in terms of bit rate, loss rate and network load for large-scale networks.
Bougouffa L, Chaghi A. The Impact of TCSC on IDMT Relays in SLG Fault in Distribution Networks. Med. J. Modeling . SimulationMed. J. Modeling . Simulation. 2016.
Bougouffa L, Chaghi A. The Impact of TCSC on IDMT Relays in SLG Fault in Distribution Networks. Med. J. Modeling . SimulationMed. J. Modeling . Simulation. 2016.
Toufik B, Fayçal DJEFFAL, Elasaad C, Djemai A. Impact of the drain and source extensions on nanoscale Double-Gate Junctionless MOSFET analog and RF performances, ISSN / e-ISSN 1369-8001 / 1873-4081. Materials Science in Semiconductor ProcessingMaterials Science in Semiconductor Processing. 2016;Volume 42 :pp. 264-267.Abstract
Multi-Gate Junctionless MOSFETs are promising devices to overcome the undesired short channel effects for low cost nanoelectronic applications. However, the high series resistance associated to the source and drain extensions can arise as a serious problem when dealing with uniformly doped channel, which leads to the degradation of the device performance. Therefore, in order to obtain a global view of Double-Gate Junctionless (DGJ) MOSFET performance under critical conditions, new designs and models of nanoscale DGJ MOSFET including analog performance are important for the comprehension of the fundamentals of such device characteristics. In the present paper, a numerical investigation for the drain current and small signal characteristics is conducted for the DGJ MOSFET by including highly doped extension regions. The proposed approach, which is from a practical viewpoint a feasible technique by introducing only one ion implantation step, provides a good solution to improve the drain current, small signal parameters, analog/RF behavior and linearity of DGJ MOSFET for high performance analog applications. In this context, I–V and analog characteristics of the proposed design are investigated by 2-D numerical modeling and compared with conventional DGJ MOSFET characteristics.
Toufik B, Fayçal DJEFFAL, Elasaad C, Djemai A. Impact of the drain and source extensions on nanoscale Double-Gate Junctionless MOSFET analog and RF performances, ISSN / e-ISSN 1369-8001 / 1873-4081. Materials Science in Semiconductor ProcessingMaterials Science in Semiconductor Processing. 2016;Volume 42 :pp. 264-267.Abstract
Multi-Gate Junctionless MOSFETs are promising devices to overcome the undesired short channel effects for low cost nanoelectronic applications. However, the high series resistance associated to the source and drain extensions can arise as a serious problem when dealing with uniformly doped channel, which leads to the degradation of the device performance. Therefore, in order to obtain a global view of Double-Gate Junctionless (DGJ) MOSFET performance under critical conditions, new designs and models of nanoscale DGJ MOSFET including analog performance are important for the comprehension of the fundamentals of such device characteristics. In the present paper, a numerical investigation for the drain current and small signal characteristics is conducted for the DGJ MOSFET by including highly doped extension regions. The proposed approach, which is from a practical viewpoint a feasible technique by introducing only one ion implantation step, provides a good solution to improve the drain current, small signal parameters, analog/RF behavior and linearity of DGJ MOSFET for high performance analog applications. In this context, I–V and analog characteristics of the proposed design are investigated by 2-D numerical modeling and compared with conventional DGJ MOSFET characteristics.
Toufik B, Fayçal DJEFFAL, Elasaad C, Djemai A. Impact of the drain and source extensions on nanoscale Double-Gate Junctionless MOSFET analog and RF performances, ISSN / e-ISSN 1369-8001 / 1873-4081. Materials Science in Semiconductor ProcessingMaterials Science in Semiconductor Processing. 2016;Volume 42 :pp. 264-267.Abstract
Multi-Gate Junctionless MOSFETs are promising devices to overcome the undesired short channel effects for low cost nanoelectronic applications. However, the high series resistance associated to the source and drain extensions can arise as a serious problem when dealing with uniformly doped channel, which leads to the degradation of the device performance. Therefore, in order to obtain a global view of Double-Gate Junctionless (DGJ) MOSFET performance under critical conditions, new designs and models of nanoscale DGJ MOSFET including analog performance are important for the comprehension of the fundamentals of such device characteristics. In the present paper, a numerical investigation for the drain current and small signal characteristics is conducted for the DGJ MOSFET by including highly doped extension regions. The proposed approach, which is from a practical viewpoint a feasible technique by introducing only one ion implantation step, provides a good solution to improve the drain current, small signal parameters, analog/RF behavior and linearity of DGJ MOSFET for high performance analog applications. In this context, I–V and analog characteristics of the proposed design are investigated by 2-D numerical modeling and compared with conventional DGJ MOSFET characteristics.
Toufik B, Fayçal DJEFFAL, Elasaad C, Djemai A. Impact of the drain and source extensions on nanoscale Double-Gate Junctionless MOSFET analog and RF performances, ISSN / e-ISSN 1369-8001 / 1873-4081. Materials Science in Semiconductor ProcessingMaterials Science in Semiconductor Processing. 2016;Volume 42 :pp. 264-267.Abstract
Multi-Gate Junctionless MOSFETs are promising devices to overcome the undesired short channel effects for low cost nanoelectronic applications. However, the high series resistance associated to the source and drain extensions can arise as a serious problem when dealing with uniformly doped channel, which leads to the degradation of the device performance. Therefore, in order to obtain a global view of Double-Gate Junctionless (DGJ) MOSFET performance under critical conditions, new designs and models of nanoscale DGJ MOSFET including analog performance are important for the comprehension of the fundamentals of such device characteristics. In the present paper, a numerical investigation for the drain current and small signal characteristics is conducted for the DGJ MOSFET by including highly doped extension regions. The proposed approach, which is from a practical viewpoint a feasible technique by introducing only one ion implantation step, provides a good solution to improve the drain current, small signal parameters, analog/RF behavior and linearity of DGJ MOSFET for high performance analog applications. In this context, I–V and analog characteristics of the proposed design are investigated by 2-D numerical modeling and compared with conventional DGJ MOSFET characteristics.
Djamil R, Aicha K, Cherifa A, Fayçal DJEFFAL. Impacts of high-k gate dielectrics and low temperature on the performance of nanoscale CNTFETs, ISSN 1569-8025. Journal of Computational ElectronicsJournal of Computational Electronics. 2016;Volume 15 :pp 1308-1315.Abstract
The influence of gate dielectric materials on the performance of a carbon nanotube field-effect transistor has been studied by a numerical simulation model. This model is based on a two-dimensional nonequilibrium Green’s function formalism performed with the self-consistent solution of the Poisson and Schrödinger equations. The device performance is investigated in terms of leakage current, on-state current, ION/IOFF current ratio, subthreshold slope, drain-induced barrier lowering, as well as transconductance, drain conductance, and intrinsic gate delay. This study is carried out over a wide range of dielectric permittivities at low temperatures ranging from room temperature down to 100 K.
Djamil R, Aicha K, Cherifa A, DJEFFAL F. Impacts of high-k gate dielectrics and low temperature on the performance of nanoscale CNTFETs. Journal of Computational ElectronicsJournal of Computational Electronics. 2016;15 :1308-1315.
Djamil R, Aicha K, Cherifa A, Fayçal DJEFFAL. Impacts of high-k gate dielectrics and low temperature on the performance of nanoscale CNTFETs, ISSN 1569-8025. Journal of Computational ElectronicsJournal of Computational Electronics. 2016;Volume 15 :pp 1308-1315.Abstract
The influence of gate dielectric materials on the performance of a carbon nanotube field-effect transistor has been studied by a numerical simulation model. This model is based on a two-dimensional nonequilibrium Green’s function formalism performed with the self-consistent solution of the Poisson and Schrödinger equations. The device performance is investigated in terms of leakage current, on-state current, ION/IOFF current ratio, subthreshold slope, drain-induced barrier lowering, as well as transconductance, drain conductance, and intrinsic gate delay. This study is carried out over a wide range of dielectric permittivities at low temperatures ranging from room temperature down to 100 K.
Djamil R, Aicha K, Cherifa A, DJEFFAL F. Impacts of high-k gate dielectrics and low temperature on the performance of nanoscale CNTFETs. Journal of Computational ElectronicsJournal of Computational Electronics. 2016;15 :1308-1315.
Djamil R, Aicha K, Cherifa A, Fayçal DJEFFAL. Impacts of high-k gate dielectrics and low temperature on the performance of nanoscale CNTFETs, ISSN 1569-8025. Journal of Computational ElectronicsJournal of Computational Electronics. 2016;Volume 15 :pp 1308-1315.Abstract
The influence of gate dielectric materials on the performance of a carbon nanotube field-effect transistor has been studied by a numerical simulation model. This model is based on a two-dimensional nonequilibrium Green’s function formalism performed with the self-consistent solution of the Poisson and Schrödinger equations. The device performance is investigated in terms of leakage current, on-state current, ION/IOFF current ratio, subthreshold slope, drain-induced barrier lowering, as well as transconductance, drain conductance, and intrinsic gate delay. This study is carried out over a wide range of dielectric permittivities at low temperatures ranging from room temperature down to 100 K.
Djamil R, Aicha K, Cherifa A, DJEFFAL F. Impacts of high-k gate dielectrics and low temperature on the performance of nanoscale CNTFETs. Journal of Computational ElectronicsJournal of Computational Electronics. 2016;15 :1308-1315.
Djamil R, Aicha K, Cherifa A, Fayçal DJEFFAL. Impacts of high-k gate dielectrics and low temperature on the performance of nanoscale CNTFETs, ISSN 1569-8025. Journal of Computational ElectronicsJournal of Computational Electronics. 2016;Volume 15 :pp 1308-1315.Abstract
The influence of gate dielectric materials on the performance of a carbon nanotube field-effect transistor has been studied by a numerical simulation model. This model is based on a two-dimensional nonequilibrium Green’s function formalism performed with the self-consistent solution of the Poisson and Schrödinger equations. The device performance is investigated in terms of leakage current, on-state current, ION/IOFF current ratio, subthreshold slope, drain-induced barrier lowering, as well as transconductance, drain conductance, and intrinsic gate delay. This study is carried out over a wide range of dielectric permittivities at low temperatures ranging from room temperature down to 100 K.

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