Abstract
In phased arrays, the generation of adapted pattern according to the signal scenario requires an efficient adaptive algorithm. The antenna array is expected to maintain sufficient gain towards each of the desired source and suppress the probing sources. This will cancel the signal transmission towards each of the hostile probing sources and leads to active cancellation. In this book, the modified improved LMS algorithm is employed for weight adaptation of dipole array for the generation of beam pattern in multiple signal environments. The performance of dipole phased array is demonstrated in terms of fast convergence, output noise power and output signal-to-interference-and-noise ratio. The mutual coupling effect and role of edge elements are taken into account. It is shown that dipole array along with an efficient algorithm is able to maintain multilobe beamforming with accurate and deep nulls towards each probing source. This work has application towards active radar cross section (RCS) reduction. This book consists of formulation, algorithm description and result discussion on active cancellation of hostile probing sources in phased antenna array. It includes numerous illustrations demonstrating the theme of the book for different signal environments and array configuration. The concept discussed in this book is simple to understand, even for the students and beginners in the field of phased arrays and adaptive array processing.
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Adve, R.S., and T.K. Sarkar. 2000. Compensation for the effects of mutual coupling on direct data domain adaptive algorithms. IEEE Transactions on Antennas and Propagation 48: 86–94.
Balanis, C.A. 2005. Antenna theory, analysis and design, 3rd edn, 1117 p. Hoboken, New Jersey: Wiley. ISBN:0-471-66782-X.
Bernardi, G., M. Felaco, M.D. Urso, L. Thimmoneri, A. Ferina, and E.F. Meliado. 2011. A simple strategy to tackle mutual coupling and platform effects in surveillance systems. Progress In Electromagnetics Research C 20: 1–15.
Compton, Jr., R.T. 1982. A method of choosing element patterns in an adaptive array. IEEE Transactions on Antennas and Propagation AP-30: 489–493.
Elliott, R.S., and G.J. Stern. 1981a. The design of microstrip dipole arrays including mutual coupling, Part I: Theory. IEEE Transactions on Antennas and Propagation AP-29: 757–760.
Elliott, R.S., and G.J. Stern. 1981b. The design of microstrip dipole arrays including mutual coupling, Part II: Experiment. IEEE Transactions on Antennas and Propagation AP-29: 761–765.
Ganz, M.W., R.L. Moses, and S.L. Wilson. 1990. Convergence of the SMI and the diagonally loaded SMI algorithms with weak interference. IEEE Transactions on Antennas and Propagation 38: 394–399.
Godara, L.C. 2004. Smart antennas, 448 p. Washington DC: CRC Press. ISBN:0-8493-1206-X.
Griffith, K.A., and I.J. Gupta. 2008. Effect of mutual coupling on the performance of GPS AJ antennas. in Proceedings of IEEE Symposium on Position, Location, and Navigation Symposium, Monterey, CA, May, pp. 871–877.
Gupta, I.J., and A.A. Ksienski. 1982. Dependence of adaptive array performance on conventional array design. IEEE Transactions on Antennas and Propagation AP-30: 549–553.
Gupta, I.J., J.A. Ulrey, and E.H. Newman. 2005. Effects of antenna element bandwidth on adaptive array performance. IEEE Transactions on Antennas and Propagation AP-53: 2332–2336.
Hansen, R.C. 1996. Finite array scan impedance Gibbsian models. Radio Science 31: 1631–1637.
Hansen, R.C. 1999. Anomalous edge effects in finite arrays. IEEE Transactions on Antennas and Propagation 47(3): 549–554.
Hansen, R.C. 2004. Linear connected arrays. IEEE Antenna and Wireless Propagation Letters 3: 154–156.
Hui, H.T. 2004. A practical approach to compensate for the mutual coupling effect of an adaptive dipole array. IEEE Transactions on Antennas and Propagation 52: 1262–1269.
Hui, H.T. 2002. Reducing the mutual coupling effect in adaptive nulling using a re-defined mutual impedance. IEEE Microwave and Wireless Components Letter 12: 178–180.
Kim, K., T.K. Sarkar, and M.S. Palma. 2002. Adaptive processing using a single snapshot for a nonuniformly spaced array in the presence of mutual coupling and near-field scatterers. IEEE Transactions on Antennas and Propagation 50: 582–590.
Parhizgar, N., M.A.M. Shirazi, A. Alighanbari, and A. Sheikhi. 2013. Adaptive nulling of a linear dipole array in the presence of mutual coupling. International Journal of RF and Microwave Computer Aided Engineering 24: 30–38.
Rabinovich, V., and N. Alexandrov. 2012. Antenna arrays and automotive applications, 206 p. New York: Springer Science and Business Media. ISBN:9781461410744.
Singh, H., and R.M. Jha. 2013. Efficacy of modified improved LMS algorithm in active cancellation of probing in phased array. Journal of Information Assurance and Security 8: 10 p.
Svendsen, A.S.C., and I.J. Gupta. 2012. The effect of mutual coupling on the nulling performance of adaptive antennas. IEEE Antennas and Propagation Magazine 54(3): 17–38.
Tennant, A., M.M. Dawoud, and A.P. Anderson. 1994. Array pattern nulling by element position perturbations using a genetic algorithm. Electronics Letters 30: 174–176.
Yuan, Q., Q. Chen, and K. Sawaya. 2006. Performance of adaptive array antenna with arbitrary geometry in the presence of mutual coupling. IEEE Transactions on Antennas and Propagation AP-54: 1991–1996.
Zhang, Y., K. Hirasawa, and K. Fujimoto. 1987. Signal bandwidth consideration of mutual coupling effects on adaptive array performance. IEEE Transactions on Antennas and Propagation AP-35: 337–339.
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Singh, H., Ankaiah, N.B., Jha, R.M. (2015). Active Cancellation of Probing in Linear Dipole Phased Array. In: Active Cancellation of Probing in Linear Dipole Phased Array. SpringerBriefs in Electrical and Computer Engineering(). Springer, Singapore. https://doi.org/10.1007/978-981-287-829-8_1
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DOI: https://doi.org/10.1007/978-981-287-829-8_1
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