logo CRAS
Comptes Rendus. Physique

Enhanced integrated multiband HPM radiator, combining a hyperband source with a high-Q frequency selective surface
Comptes Rendus. Physique, Online first (2021), pp. 1-10.

Article du numéro thématique : URSI-France 2020 Workshop
[Journées URSI-France 2020]

This work presents advances on the development of a resonant radiator, obtained as the augmentation of a conventional Impulse Radiating Antenna (IRA) with a Frequency Selective Surface (FSS), in the L-band. An improved passband-type FSS is obtained by exploring the Multiple Split Ring Resonators (MCSRR) unit cells to obtain a higher Q-factor radiator. The effects of a multiband and of a tunable FSS’s are also studied and verified via simulations. A variety of applications are enabled by modifying the UWB waveform from the IRA into a damped sinusoidal from the combined radiator like IEMI testing, hardening of infrastructures, cloaking of wide aperture radiators, among other. The system analysis methodology can also be applied to other FSS geometries, or the combinations of various of them.

Première publication :
DOI : https://doi.org/10.5802/crphys.63
Mots clés : Frequency selective surface, Complementary split ring resonators, Electromagnetic hardening, Hyperband radiators, HPM sources, IEMI
@article{CRPHYS_2021__22_S1_A8_0,
     author = {Fernando Albarracin-Vargas and Felix Vega and Chaouki Kasmi and David Martinez and Lars Ole Fichte},
     title = {Enhanced integrated multiband {HPM} radiator, combining a hyperband source with a {high-Q} frequency selective surface},
     journal = {Comptes Rendus. Physique},
     publisher = {Acad\'emie des sciences, Paris},
     year = {2021},
     doi = {10.5802/crphys.63},
     language = {en},
     note = {Online first},
}
Fernando Albarracin-Vargas; Felix Vega; Chaouki Kasmi; David Martinez; Lars Ole Fichte. Enhanced integrated multiband HPM radiator, combining a hyperband source with a high-Q frequency selective surface. Comptes Rendus. Physique, Online first (2021), pp. 1-10. doi : 10.5802/crphys.63.

[1] D. D. V. Giri; F. M. Tesche Modeling of propagation losses in common residential and commercial building walls, 2013 (http://ece-research.unm.edu/summa/notes/In/IN624.pdf, Interaction Notes 624, 24 pages, published by the Summa Foundation)

[2] D. V. Giri; R. Hoad; F. Sabath Implications of high-power electromagnetic (HPEM) environments on electronics, IEEE Electromagn. Compat. Mag., Volume 9 (2020) no. 2, pp. 37-44 | Article

[3] C. E. Baum Radiation of impulse-like transient fields, 1989 (http://ece-research.unm.edu/summa/notes/SSN/note321.pdf, Sensor and Simulation Notes 321, 28 pages, published by the Summma Foundation)

[4] C. E. Baum; E. G. Farr Impulse radiating antennas, Ultra-Wideband, Short-Pulse Electromagnetics (H. L. Bertoni; L. Carin; L. B. Felsen, eds.), Volume 2, Springer US, Boston, MA, 1993, pp. 139-147 | Article

[5] F. M. Tesche; D. V. Giri Modification of impulse-radiating antenna waveforms for infrastructure element testing, 2015 (http://ece-research.unm.edu/summa/notes/SSN/SSN572.pdf, Sensor and Simulation Notes 572, 25 pages, published by the Summa Foundation)

[6] W. Bigelow; E. Farr; J. S. Tyo A frequency selective surface used as a broadband filter to pass low-frequency UWB while reflecting X-band radar, 2006 (http://www.farr-research.com/Papers/ssn506.pdf, Sensor and Simulation Notes 506, 17 pages, published by the Summa Foundation)

[7] C. Yang; P.-G. Liu; X.-J. Huang A novel method of energy selective surface for adaptive HPM/EMP protection, IEEE Antennas Wirel. Propag. Lett., Volume 12 (2013), pp. 112-115 | Article

[8] S. Monni; D. J. Bekers; M. van Wanum; R. van Dijk; A. Neto; G. Gerini; F. E. van Vliet Limiting frequency selective surfaces, 2009 European Microwave Conference (EuMC) (2009), pp. 606-609

[9] M. Mavridou; K. Konstantinidis; A. Feresidis; P. Gardner Novel tunable frequency selective meta-surfaces, 2016 46th European Microwave Conference (EuMC) (2016), pp. 301-304 | Article

[10] D. Li; T. Li; E. Li; Y. Zhang A 2.5-D angularly stable frequency selective surface using via-based structure for 5G EMI shielding, IEEE Trans. Electromagn. Compat., Volume 60 (2017) no. 3, pp. 768-775 | Article

[11] B. A. Munk Frequency Selective Surfaces: Theory and Design, John Wiley & Sons, New York, 2005

[12] J. B. Pendry; A. J. Holden; D. J. Robbins; W. J. Stewart Magnetism from conductors and enhanced nonlinear phenomena, IEEE Trans. Microw. Theory Techniq., Volume 47 (1999) no. 11, pp. 2075-2084 | Article

[13] R. Marqués; J. D. Baena; M. Beruete; F. Falcone; T. Lopetegi; M. Sorolla; F. Martín; J. Garcia Ab initio analysis of frequency selective surfaces based on conventional and complementary split ring resonators, J. Opt. A: Pure Appl. Opt., Volume 7 (2005) no. 2, p. S38-S43

[14] J. D. Ortiz; J. D. Baena; V. Losada; F. Medina; J. L. Araque Spatial angular filtering by FSSs made of chains of interconnected SRRs and CSRRs, IEEE Microw. Wirel. Compon. Lett., Volume 23 (2013) no. 9, pp. 477-479 | Article

[15] F. Bilotti; A. Toscano; L. Vegni Design of spiral and multiple split-ring resonators for the realization of miniaturized metamaterial samples, IEEE Trans. Antennas Propag., Volume 55 (2007) no. 8, pp. 2258-2267 | Article

[16] J. D. Baena; J. Bonache; F. Martin; R. M. Sillero; F. Falcone; T. Lopetegi; M. A. G. Laso; J. Garcia-Garcia; I. Gil; M. F. Portillo; M. Sorolla Equivalent-circuit models for split-ring resonators and complementary split-ring resonators coupled to planar transmission lines, IEEE Trans. Microw. Theory Techniq., Volume 53 (2005) no. 4, pp. 1451-1461 | Article

[17] R. Marques; F. Mesa; J. Martel; F. Medina Comparative analysis of edge- and broadside-coupled split ring resonators for metamaterial design—theory and experiments, IEEE Trans. Antennas Propag., Volume 51 (2003) no. 10, pp. 2572-2581 | Article

[18] O. V. Mikheev; S. A. Podosenov; K. Y. Sakharov; A. A. Sokolov; Y. G. Svekis; V. A. Turkin New method for calculating pulse radiation from an antenna with a reflector, IEEE Trans. Electromagn. Compat., Volume 39 (1997) no. 1, pp. 48-54 | Article

[19] F. M. Tesche; M. Ianoz; T. Karlsson EMC Analysis Methods and Computational Models, John Wiley & Sons, New York, 1996