Clonal Selection Algorithm for Design of Reconfigurable Antenna Array with Discrete Phase Shifters

References

• Bucci , O. M. , Mazzarella , G. and Panariello , G. 1991 . Reconfigurable arrays by phase-only control . IEEE Trans. Antennas Propagat. , 39 : 919 – 925 .
   Web of Science ®Google Scholar
• Bucci , O. M. , D’Elia , G. K. , Mazzarella , G. and Panariello , G. 1994 . Antenna pattern synthesis: a new general approach . Proc. IEEE , 82 : 358 – 371 .
   Google Scholar
• Dobias , F. and Gunther , J. 1995 . “ Reconfigurable array antennas with phase-only control of quantized phase shifters ” . In IEEE APS Int. Symp 35 – 39 . Newport, Beach , CA
   Google Scholar
• Durr , M. , Trastoy , A. and Ares , F. 2000 . Multiple-pattern linear antenna arrays with single prefixed distributions: Modified Woodward-Lawson synthesis . Electron. Lett. , 26 : 1345 – 1346 .
   Google Scholar
• Diaz , X. , Rodriguez , J. A. , Ares , F. and Moreno , E. 2000 . Design of phase-differentiated multiple-pattern antenna arrays . Microwave Opt. Technol. Lett. , 26 : 52 – 53 .
   Web of Science ®Google Scholar
• Gies , D. and Rahmat-Samii , Y. 2003 . Particle swarm optimization for reconfigurable phase-differentiated array design . Microwave Opt. Technol. Lett. , 38 : 168 – 175 .
   Web of Science ®Google Scholar
• Baskar , S. , Alphones , A. and Suganthan , P. N. 2005 . Geneticalgorithm-based design of a reconfigurable antenna array with discrete phase shifters . Microwave Opt. Technol. Lett. , 45 : 461 – 465 .
   Web of Science ®Google Scholar
• Mahanti , G. K. , Chakraborty , A. and Das , S. Dec. 2005 . “ Floating-point genetic algorithm for design of a reconfigurable antenna arrays by phase-only control ” . In Proc. Microwave Conf. APMC’05 Vol. 5 , Dec. , Suzhou , , China 4–7
   Google Scholar
• De Castro , L. N. and Von Zuben , F. J. 2002 . Learning and optimization using the clonal selection principle . IEEE Trans. Evol. Comput. , 6 : 239 – 251 .
   Web of Science ®Google Scholar
• Jerne , N. K. 1973 . The immune system . Scientific American , 229 : 51 – 60 .
   Web of Science ®Google Scholar
• Ada , G. L. and Nossal , G. 1987 . The clonal selection theory . Scientific American , 257 : 50 – 57 .
   Web of Science ®Google Scholar
• Coello Coello , C. A. and Cortes , N. C. 2005 . Solving multiobjective optimization problems using an artificial immune system . Genetic Programming and Evolvable Machines , 6 : 163 – 190 .
   Google Scholar
• Campelo , F. , Guimaraes , F. G. , Igarashi , H. and Ramirez , J. A. 2005 . A clonal selection algorithm for optimization in electromagnetics . IEEE Trans. Magnetics , 41 : 1736 – 1739 .
   Web of Science ®Google Scholar
• Stevens , D. , Das , S. and Natarajan , B. June 2005 . “ A multi-objective algorithm for DS-CDMA code design based on the clonal selection principle ” . In GECCO’05 June , 2015 – 2020 . Washington , DC, USA 25–29
   Google Scholar
• Ong , Z. X. , Tay , J. C. and Kwoh , C. K. 2005 . Applying the clonal selection principle to find flexible job-shop schedules . Lecture Notes in Computer Science , 3627 : 442 – 455 .
   Google Scholar
• Zhong , Y. , Zhang , L. , Huang , B. and Li , P. 2006 . An unsupervised artificial immune classifier for multi/hyperspectral remote sensing imaginery . IEEE Trans. Geosci. Remote Sens. , 44 : 420 – 431 .
   Web of Science ®Google Scholar
• Babayigit , B. , Akdagli , A. and Guney , K. 2006 . A clonal selection algorithm for null synthesizing of linear antenna arrays by amplitude control . J. Electromagn. Waves Applicat. , 20 : 1007 – 1020 .
   Web of Science ®Google Scholar