Lehrstuhl für Hochfrequenztechnik

Dr.-Ing. Nasrin Nasr Esfahani

Kaiserstraße 2, R.D-047
nna@tf.uni-kiel.de

Profil von M. Sc. N. Nasr Esfahani

Werdegang

2004: Erwerb des B. Sc.-Grades (Fachrichtung  “Elektrotechnik-Nachrichtentechnik” an der Iran Universität für Wissenschaft und Technologie (IUST), Teheran, Iran)

2007: Erwerb des M. Sc.-Grades (Fachrichtung  “Elektrotechnik-Hochfrequenztechnik” an der Iran Universität für Wissenschaft und Technologie (IUST), Teheran, Iran)

2007-2009: Wissenschaftliche Mitarbeiterin an der Iran Universität für Wissenschaft und Technologie (IUST), Teheran, Iran

2010-2014: Doktorandin am Institut für Hochfrequenztechnik TUHH

2014: Promotion zum Dr.-Ing.

 

Forschungsgebiet

Analyse der Elektron-Welle Wechselwirkung in neuartigen Verzögerungsstrukturen

Metamaterial Resonatoren und Verzögerungsstrukturen

 

Lehre

Filter Theory and Synthesis

Communication Circuits

Fundamentals of Telecommunication

Mathematical Methods in Engineering

Electromagnetics

Communication Circuits Lab.

Bachelor-Praktikum Hochfrequenztechnik

 

Veröffentlichungen/Publications

[1]   N. Nasr Esfahani, M. Tayarani, “Computation of coupling between TE011 cylindrical resonators”, European Microwave Conference, pp. 846 - 849, Oct. 2007, Munich, Germany

[2]   N. Nasr Esfahani, M. Tayarani, “A new model for exact computation of coupling between TE01δ dielectric resonators”, Asia Pacific Microwave Conference (APMC), pp. 2115-2118, Dec. 2007, Bangkok, Thailand

[3]   Payamn Rezaee, N. Nasr Esfahani, M. Tayarani, and N. Mozayani, “A novel, fast and accurate approach for coupling factor computation between square open loop resonators using fuzzy inference method”, IEEE Conference, 6th International Conference on Microwave and Millimeter Wave Technology (ICMMT), pp.1282-1285, April, 2008, Nanjing, China

[4]   Payamn Rezaee, N. Nasr Esfahani, and M. Tayarani, “External Q computation by fuzzy inference method; application to microstrip filter design”, IEEE Conference, 6th International Conference on Microwave and Millimeter Wave Technology (ICMMT), pp. 971-974, April, 2008, Nanjing, China

[5]   Payamn Rezaee, N. Nasr Esfahani, M. Tayarani, and N. Mozayani, “A novel approach for designing microstrip square open loop resonator filters using fuzzy inference method”, IEEE Conference, 6th International Symposium on Electromagnetic Compatibility, pp. 747-752, Sept., 2008, Hamburg, Germany

[6]   P. Rezaee, N. Nasr Esfahani, R. Knöchel, and M. Tayarani, “Active learning method for microstrip filter design”, European Microwave Conference, pp. 369-372, Sept. 2010, Paris, France

[7]   P. Rezaee, N. Nasr Esfahani, R. Knöchel, and M. Tayarani, “Active learning method for external q computation”, German Microwave Conference (GeMic), pp. 1-4, March 2011, Darmstadt, Germany

[8]   P. Rezaee, N. Nasr Esfahani, R. Knöchel, and M. Tayarani, “Using active learning method for designing miniaturized microstrip metamaterial bandpass filters”, 25th International Symposium on Microwave and Optical Technology (ISMOT), pp. 257-260, June 2011, Prague, Czech Republic

[9]   N. Nasr Esfahani, P. Rezaee, and M. Tayarani, “Application of metamaterials in microwave humidity sensors” ”, 25th International Symposium on Microwave and Optical Technology (ISMOT), pp. 143-146, June 2011, Prague, Czech Republic

[10] P. Rezaee, N. Nasr Esfahani, R. Knöchel, and M. Tayarani, “Active learning method for designing miniaturized waveguide filters loaded by broadside-coupled split ring resonators”, in Proc. of 13th  13th International Conference on Electromagnetics in Advanced Applications (ICEAA), pp. 1074-1077, 12th-16th Sept. 2011, Torino, Italy

[11] N. Nasr Esfahani, P. Rezaee, K. Schünemann, R. Knöchel, and M. Tayarani, “Miniaturized coaxial cylindrical cavity filters based on sub-wavelength metamaterial loaded resonator”, in Proc. of 13th International Conference on Electromagnetics in Advanced  Applications (ICEAA), pp. 1086-1089, Sept. 2011, Torino, Italy

[12] N. Nasr Esfahani and K. Schünemann, “Modifying humidity sensors through the use of metamaterial structures”, in Proc. of the scientific conference on Theoretical and Methodical Problems of Radio Engineering Systems Effective Functioning, pp. 103-110, Nov. 2011, Russia

[13] N. Nasr Esfahani and K. Schünemann, “Miniaturized surface wave cylindrical metamaterial loaded resonator”, in Proc. of 7th German Microwave Conference (GeMiC), pp. 1-4, March 2012, Germany

[14] N. Nasr Esfahani and K. Schünemann, “Towards the application of MNG-loaded slow wave structures in spatial harmonic magnetrons, in Proc. of  6th International Congress on Advanced Electromagnetic Materials in Microwaves and Optics (Metamaterials),  pp. 487-489, Sept. 2012, Russia

[15] N. Nasr Esfahani, P. Rezaee, K. Schünemann, and Reinhard Knöchel, “Miniaturized coaxial cavity resonator based on anisotropic negative permeability metamaterial loading”, Microwave and Optical Technology Letters, vol. 54, no. 3, pp. 595-599, March 2012

[16] N. Nasr Esfahani and K. Schünemann, “Particle-in-cell simulations of a spatial-harmonic magnetron with a cold secondary emission cathode”, IEEE Trans. Plasma Science, vol. 40, no. 12, pp. 3512-3519, Dec. 2012

[17] N. Nasr Esfahani, M. Tayarani, and K. Schünemann, “Design and 3D particle in cell simulation of a 140GHz spatial-harmonic magnetron”, Progress In Electromagnetics Research, vol. 133, pp. 443-458, 2013

[18] N. Nasr Esfahani and K. Schünemann, “Design and simulation of a π/2-mode spatial-harmonic magnetron”, International Journal of  Electronics and Communications, AEÜ, vol. 67, no. 5, pp. 426–432, May 2013