Articles
<![CDATA[A Novel Cpw Low Cost Lowpass Filter Integrating Periodic Structures ]]>
<![CDATA[Fouad Aytouna]]>;
<![CDATA[Jamal Zbitou]]>;
<![CDATA[Mohamed Aghoutane]]>;
<![CDATA[Naima Amar Touhami]]>;
<![CDATA[Abdelwahed Tribak]]>;
<![CDATA[Mohamed Latrach]]>
<![CDATA[ International Journal of Electrical and Computer Engineering (IJECE) Vol 6, No 3: June 2016 ]]>
Publisher : <![CDATA[Institute of Advanced Engineering and Science ]]>
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DOI: 10.11591/ijece.v6i3.pp1106-1111
<![CDATA[In this work, we propose a novel design of a planar CPW lowpass “LPF” filter based on the use of periodic structures. The periodic cells are formed from a rectangular slot repeated periodically. The originality of this work is to develop a new LPF structure which is simple, low cost for fabrication and easy to associate with others microwave planar circuits. The proposed and validated LPF is a compact planar filter structure. The final circuit is simulated and optimized by using two electromagnetic solvers, ADS (Advanced Design System) and HFSS (High Frequency Structural Simulator). After many series of optimization we have validated the final circuit into simulation by using optimization methods integrated into the both solvers, taking into account a high density of meshing in order to cover the whole circuit. The fabricated LPF circuit shows good agreement between simulation and measurement results in term of matching input impedance and insertion loss with a cutoff frequency of 1.25GHz. The entire area of the proposed LPF is 35x31 mm2.]]>
<![CDATA[Design of L-S band broadband power amplifier using microstip lines ]]>
<![CDATA[Mohamed Ribate]]>;
<![CDATA[Rachid Mandry]]>;
<![CDATA[Jamal Zbitou]]>;
<![CDATA[Larbi El Abdellaoui]]>;
<![CDATA[Ahmed Errkik]]>;
<![CDATA[Mohamed Latrach]]>;
<![CDATA[Ahmed Lakhssassi]]>
<![CDATA[ International Journal of Electrical and Computer Engineering (IJECE) Vol 10, No 5: October 2020 ]]>
Publisher : <![CDATA[Institute of Advanced Engineering and Science ]]>
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DOI: 10.11591/ijece.v10i5.pp5400-5408
<![CDATA[This contribution introduces a novel broadband power amplifier design, operating in the frequency band ranging from 1.5 GHz to 3 GHz which cover the mainstream applications running in L and S bands. Both matching and biasing networks are synthesized by using microstrip transmission lines. In order to provide a wide bandwidth, two broadband matching techniques are deployed for this purpose, the first technique is an approximate transformation of a previously designed lumped elements matching networks into microstrip matching circuits, and the second technique is a binomial multi-sections quarter wave impedance transformer. The proposed work is based on ATF-13786 active device. The simulation results depict a maximum power gain of 16.40 dB with an excellent input and output matching across 1.5 GHz ~ 3 GHz. At 2.2 GHz, the introduced BPA achieves a saturated output power of 16.26 dBm with a PAE of 21.74%, and a 1-dB compression point of 4.5 dBm input power level. The whole circuitry is unconditionally stable over the overall bandwidth. By considering the broadband matching, the proposed design compares positively with the most recently published BPA.]]>
<![CDATA[A trade-off design of microstrip broadband power amplifier for UHF applications ]]>
<![CDATA[Mohamed Ribate]]>;
<![CDATA[Rachid Mandry]]>;
<![CDATA[Jamal Zbitou]]>;
<![CDATA[Larbi El Abdellaoui]]>;
<![CDATA[Ahmed Errkik]]>;
<![CDATA[Mohamed Latrach]]>;
<![CDATA[Ahmed Lakhssassi]]>
<![CDATA[ International Journal of Electrical and Computer Engineering (IJECE) Vol 10, No 1: February 2020 ]]>
Publisher : <![CDATA[Institute of Advanced Engineering and Science ]]>
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DOI: 10.11591/ijece.v10i1.pp919-927
<![CDATA[In this paper, the design of a Broadband Power Amplifier for UHF applications is presented. The proposed BPA is based on ATF13876 Agilent active device. The biasing and matching networks both are implemented by using microstrip transmission lines. The input and output matching circuits are designed by combining two broadband matching techniques: a binomial multi-section quarter wave impedance transformer and an approximate transformation of previously designed lumped elements. The proposed BPA shows excellent performances in terms of impedance matching, power gain and unconditionally stability over the operating bandwidth ranging from 1.2 GHz to 3.3 GHz. At 2.2 GHz, the large signal simulation shows a saturated output power of 18.875 dBm with an output 1-dB compression point of 6.5 dBm of input level and a maximum PAE of 36.26%.]]>
<![CDATA[1.25 GHz – 3.3 GHz broadband solid state power amplifier for L and S bands applications ]]>
<![CDATA[Mohamed Ribate]]>;
<![CDATA[Rachid Mandry]]>;
<![CDATA[Jamal Zbitou]]>;
<![CDATA[Larbi El Abdellaoui]]>;
<![CDATA[Ahmed Errkik]]>;
<![CDATA[Mohamed Latrach]]>
<![CDATA[ International Journal of Electrical and Computer Engineering (IJECE) Vol 9, No 5: October 2019 ]]>
Publisher : <![CDATA[Institute of Advanced Engineering and Science ]]>
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DOI: 10.11591/ijece.v9i5.pp3633-3641
<![CDATA[The research of a single stage broadband solid-state power amplifier based on ATF13876 transistor, which operates in the frequency ranging from 1.25 GHz ~3.3 GHz is presented in this paper. To achieve the broadband performance of the operating bandwidth, a multi-section quarter wave impedance transformer and an approximate transformation of previously synthesized lumped elements into transmission lines are adopted. With neatly design of broadband matching networks and biasing circuit, excellent matching performances and unconditionally stability are achieved over the whole operating bandwidth with a maximum gain of 17.2 dB. The large signal simulation shows that the proposed circuit reaches a saturated output power of 18.12 dBm with a maximum PAE of 27.55% and a 1-dB compression point at 5 dBm input power level. Considering the wide frequency coverage, the features of the proposed design compares favorably with the contemporary state-of-the-art.]]>
<![CDATA[A new structure of a wide band bridge power limiter ]]>
<![CDATA[Khalifa Echchakhaoui]]>;
<![CDATA[Elhassane Abdelmounim]]>;
<![CDATA[Jamal Zbitou]]>;
<![CDATA[Hamid Bennis]]>
<![CDATA[ International Journal of Electrical and Computer Engineering (IJECE) Vol 10, No 4: August 2020 ]]>
Publisher : <![CDATA[Institute of Advanced Engineering and Science ]]>
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DOI: 10.11591/ijece.v10i4.pp4035-4042
<![CDATA[In this work, new design and simulation of a microstrip power limiter based on Schottky diode is presented. The proposed circuit is a zero bias power limiter built by associating a transmission line in parallel to a four Schottky rectifier bridge circuit. The first circuit using a single stage rectifier is analyzed and simulated. To improve this single stage, a second and final limiter is designed with two stages rectifier. Simulation results for the final circuit show an ideal limiter behavior and good performance of limiting rate up to 20dB for a threshold input power varying from 5 dBm to 30 dBm. While insertion loss remains low at small signal.]]>
<![CDATA[A new design of a microstrip rectenna at 5.8 GHz for wireless power transmission applications ]]>
<![CDATA[Taybi Abdellah]]>;
<![CDATA[Abdelali Tajmouati]]>;
<![CDATA[Jamal Zbitou]]>;
<![CDATA[Ahmed Errkik]]>;
<![CDATA[Mohamed Latrach]]>
<![CDATA[ International Journal of Electrical and Computer Engineering (IJECE) Vol 9, No 2: April 2019 ]]>
Publisher : <![CDATA[Institute of Advanced Engineering and Science ]]>
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DOI: 10.11591/ijece.v9i2.pp1258-1266
<![CDATA[Due to the ever-increasing power demand, the need of electricity and eco-friendly power in every nook and corner of the world, many reaserch topics have been devoted to deal with this problematic. This paper is taking part of the proposed solutions with the presentation of a novel 5.8 GHz rectenna system for wireless power transmission applications. In one hand, a miniaturized 5.8 GHz circular polarized patch antenna has been designed and simulated by using the Advanced Design System (ADS). In the other hand, a rectifier structure has been investigated and optimized by the use of the Harmonic Balance method available in ADS. The circuit is based on 5 HSMS2820 Schottky diodes implemented in a voltage multiplier topology and a load resistance of 1 KOhm. Both of the structures have been validated by simulation and experimental results and good agreement has been concluded.]]>
<![CDATA[A Compact Planar Low-Pass Filter Based on SRR-Metamateria ]]>
<![CDATA[Badr Nasiri]]>;
<![CDATA[Ahmed Errkik]]>;
<![CDATA[Jamal Zbitou]]>;
<![CDATA[Abdelali Tajmouati]]>;
<![CDATA[Larbi El Abdellaoui]]>;
<![CDATA[Mohamed Latrach]]>
<![CDATA[ International Journal of Electrical and Computer Engineering (IJECE) Vol 8, No 6: December 2018 ]]>
Publisher : <![CDATA[Institute of Advanced Engineering and Science ]]>
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DOI: 10.11591/ijece.v8i6.pp4972-4980
<![CDATA[In this work, a novel design of a Microstrip Low-pass filter based on metamaterial square split ring resonators (SRRs) is proposed. The SRRs has been added to obtain a reduced size and high performances. The filter is designed on an FR-4 substrate having a thickness of 1.6mm, a dielectric constant of 4.4 and loss tangent of 0.025. The proposed low-pass filter is characterized by a cutoff frequency of 2.4 GHz and an attenuation level below than -20dB in the stopband. The LPF is designed, simulated and optimized by using two electromagnetic solvers CST microwave studio and ADS. The computed results obtained by both solvers are in good agreement. The total surface area of the proposed circuit is 18x18mm2 excluding the feed line, its size is miniaturized by 40% compared to the conventional filter. The experimental results illustrate that the filter achieves very good electrical performances in the passband with a low insertion loss of 0.2 dB. Moreover, a suppression level can reach more than 35 dB in the rejected band.]]>
<![CDATA[A New Design of a CPW-Fed Dual-Band Monopole Antenna for RFID Readers ]]>
<![CDATA[Ahmed El Hamraoui]]>;
<![CDATA[EL Hassane Abdelmounim]]>;
<![CDATA[Jamal Zbitou]]>;
<![CDATA[Hamid Bennis]]>;
<![CDATA[Mohamed Latrach]]>
<![CDATA[ International Journal of Electrical and Computer Engineering (IJECE) Vol 8, No 2: April 2018 ]]>
Publisher : <![CDATA[Institute of Advanced Engineering and Science ]]>
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DOI: 10.11591/ijece.v8i2.pp1040-1047
<![CDATA[This paper comes with a new dual-band planar monopole antenna fed by Coplanar Waveguide (CPW) line designed for RFID readers and it operates at 2.45 GHz, 5.80 GHz. This antenna is designed with reasonable gain, low profile and low cost production. The designed antenna based on theoretical equations is simulated and validated by using ADS from Agilent technologies and CST Microwave Studio electromagnetic solvers. A parametric study of the proposed antenna has been carried out by optimizing some critical parameters. The antenna has a total area of 35×38 mm2 and mounted on an FR4 substrate with dielectric permittivity constant 4.4 and thickness of 1.6 mm and loss tangent 0.025. The comparison between simulation and measurement results permits to validate the final achieved antenna structure in the desired RFID frequencies bands. Details of the proposed antenna design and both simulated and experimental results are described and discussed]]>
<![CDATA[A Miniature L-slot Microstrip Printed Antenna for RFID ]]>
<![CDATA[Mohamed Ihamji]]>;
<![CDATA[El hassane Abdelmounim]]>;
<![CDATA[Jamal Zbitou]]>;
<![CDATA[Hamid Bennis]]>;
<![CDATA[Mohamed Latrach]]>
<![CDATA[ TELKOMNIKA (Telecommunication Computing Electronics and Control) Vol 16, No 5: October 2018 ]]>
Publisher : <![CDATA[Universitas Ahmad Dahlan ]]>
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DOI: 10.12928/telkomnika.v16i5.9378
<![CDATA[This work presents a miniature microstrip antenna at 2.45 GHz by using the slots technique. This microstrip antenna is fed by a CPW technique and designed for RFID reader system on FR4 substrate. A size reduction equal to 66.6% has been obtained compared to the conventional rectangular microstrip antenna. The total area of the final circuit is 19x31 mm2. The validated antenna has good matching input impedance with a stable radiation pattern, a loss return of -40 dB, and a gain of 1.78 dBi, a prototype of the proposed antenna has been fabricated and measured.]]>
<![CDATA[A New Compact CPW-Fed Dual-Band Uniplanar Antenna for RFID Applications ]]>
<![CDATA[Ahmed El Hamraoui]]>;
<![CDATA[El Hassane Abdelmounim]]>;
<![CDATA[Jamal Zbitou]]>;
<![CDATA[Laarbi Elabdellaoui]]>;
<![CDATA[Hamid Bennis]]>;
<![CDATA[Mohamed Latrach]]>
<![CDATA[ TELKOMNIKA (Telecommunication Computing Electronics and Control) Vol 16, No 1: February 2018 ]]>
Publisher : <![CDATA[Universitas Ahmad Dahlan ]]>
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DOI: 10.12928/telkomnika.v16i1.7560
<![CDATA[In this paper a new dual-band uniplanar monopole antenna fed by Coplanar Waveguide (CPW) line is proposed for Radio Frequency Identification (RFID) applications. The antenna structure includes a CPW fed line and the dual-band operation is achieved from the G-shaped folded antenna. The antenna parameters have been investigated and optimized by using CST Microwave Studio. To validate the CST Microwave Studio results before the antenna achievement, we have conducted another study by using ADS. The final circuit was achieved, measured and validated. Experimental results show that the proposed antenna with compact size of 30*45 mm2 is simple in design and compact in size. It exhibits broadband impedance matching, consistent omnidirectional radiation patterns and appropriate gain characteristics suitable for the microwave RFID applicartions.]]>
