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CLC number: TN82
On-line Access: 2020-03-18
Received: 2019-09-11
Revision Accepted: 2019-12-25
Crosschecked: 2020-02-24
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A look at field manipulation and antenna design using 3D transformation electromagnetics and 2D surface electromagnetics
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Peng-fei Zhang, Yu-kai Yan, Ying Liu, Raj Mittra. A look at field manipulation and antenna design using 3D transformation electromagnetics and 2D surface electromagnetics[J]. Frontiers of Information Technology & Electronic Engineering, 2020, 21(3): 351-365.
@article{title="A look at field manipulation and antenna design using 3D transformation electromagnetics and 2D surface electromagnetics",
author="Peng-fei Zhang, Yu-kai Yan, Ying Liu, Raj Mittra",
journal="Frontiers of Information Technology & Electronic Engineering",
volume="21",
number="3",
pages="351-365",
year="2020",
publisher="Zhejiang University Press & Springer",
doi="10.1631/FITEE.1900489"
}
%0 Journal Article
%T A look at field manipulation and antenna design using 3D transformation electromagnetics and 2D surface electromagnetics
%A Peng-fei Zhang
%A Yu-kai Yan
%A Ying Liu
%A Raj Mittra
%J Frontiers of Information Technology & Electronic Engineering
%V 21
%N 3
%P 351-365
%@ 2095-9184
%D 2020
%I Zhejiang University Press & Springer
%DOI 10.1631/FITEE.1900489
TY - JOUR
T1 - A look at field manipulation and antenna design using 3D transformation electromagnetics and 2D surface electromagnetics
A1 - Peng-fei Zhang
A1 - Yu-kai Yan
A1 - Ying Liu
A1 - Raj Mittra
J0 - Frontiers of Information Technology & Electronic Engineering
VL - 21
IS - 3
SP - 351
EP - 365
%@ 2095-9184
Y1 - 2020
PB - Zhejiang University Press & Springer
ER -
DOI - 10.1631/FITEE.1900489
Abstract: While many techniques have been developed for the design of different types of antennas, such as wire antenna, patch antenna, lenses, and reflectors, these cannot be said general-purpose strategies for the synthesis and design of antennas to achieve the performance characteristics specified by users. Recently, there has been an increasing need for the development of antenna design techniques because of the advent of 5G and a variety of space, defense, biological, and similar applications, for which a robust and general-purpose design tool is not to be developed. The main objective of this study is to take a look at antenna design from the field manipulation point of view, which has the potential to partially fulfill this need. We review the existing field manipulation techniques, including field transformation methods based on Maxwell’s and wave equations, point out some limitations of these techniques, and then present ways to improve the performance of these methods. Next, we introduce an alternative approach for field manipulation based on two-dimensional (2D) metasurfaces, and present laws of the generalized reflection and refraction that are based on 2D surface electromagnetics. Then, we explore how to overcome the limitations of conventional reflection and refraction processes that are strictly bounded by the critical angle. Finally, we provide some application examples of field manipulation methods in the antenna design, with a view on developing a general-purpose strategy for antenna design for future communication.
[1]Achouri K, Salem MA, Caloz C, 2015. General metasurface synthesis based on susceptibility tensors. IEEE Trans Antenn Propag, 63(7):2977-2991.
[2]Cui TJ, Qi MQ, Wan X, et al., 2014. Coding metamaterials, digital metamaterials and programmable metamaterials. Light Sci Appl, 3(10):e218.
[3]Jia X, Yang F, Vahabzadeh Y, et al., 2018. Multiple beam forming using spherical metasurfaces. IEEE Int Symp on Antennas and Propagation & USNC/URSI National Radio Science Meeting, p.1709-1710.
[4]Jiang WX, Chin JY, Li Z, et al., 2008. Analytical design of conformally invisible cloaks for arbitrarily shaped objects. Phys Rev E, 77(6):066607.
[5]Kwon DH, Werner DH, 2008. Restoration of antenna parameters in scattering environments using electromagnetic cloaking. Appl Phys Lett, 92(11):113507.
[6]Lai Y, Chen HY, Zhang ZQ, et al., 2009. Complementary media invisibility cloak that cloaks objects at a distance outside the cloaking shell. Phys Rev Lett, 102(9):093901.
[7]Lee C, Sainati R, Franklin RR, 2018. Frequency selective surface effects on a coplanar waveguide feedline in Fabry-Perot cavity antenna systems. IEEE Antenn Wirel Propag Lett, 17(5):768-771.
[8]Lee JG, Lee JH, 2017. Low-profile Fabry-Perot cavity (FPC) antenna using meta-surface for dual-band. Int Symp on Antennas and Propagation, p.1-2.
[9]Leonhardt U, 2006. Optical conformal mapping. Science, 312(5781):1777-1780.
[10]Li LL, Ruan HX, Liu C, et al., 2019. Machine-learning reprogrammable metasurface imager. Nat Commun, 10(1): 1082.
[11]Lian RN, Tang ZY, Yin YZ, 2017. Design of a broadband polarization-reconfigurable Fabry-Perot resonator antenna. IEEE Antenn Wirel Propag Lett, 17(1):122-125.
[12]Liu R, Ji C, Mock JJ, et al., 2009. Broadband ground-plane cloak. Science, 323(5912):366-369.
[13]Liu ZG, 2010. Fabry-Perot resonator antenna. J Infrar Millim Terah Wave, 31(4):391-403.
[14]Liu ZG, 2016. Broadband Fabry-Perot cavity leaky wave antenna with parabolic-shape reflector. IEEE 5th Asia- Pacific Conf on Antennas and Propagation, p.355-356.
[15]Marin JG, Baba AA, Cuenca DL, et al., 2019. High-gain low- profile chip-fed resonant cavity antennas for millimeter- wave bands. IEEE Antenn Wirel Propag Lett, 18(11): 2394-2398.
[16]Mittra R, Zhou Y, Zhang P, 2016. A look at electromagnetic field transformation using transformation optics (TO): wave equation and scattering matrix formalisms. Forum Electromagn Res Meth Appl Technol, 15:004.
[17]Pendry JB, Schurig D, Smith DR, 2006. Controlling electromagnetic fields. Science, 312(5781):1780-1782.
[18]Ratni B, de Lustrac A, Piau GP, et al., 2018. Phase modulation in partially reflective surfaces for beam steering in Fabry- Perot cavity antennas. Asia-Pacific Microwave Conf, p.1052-1054.
[19]Schurig D, Pendry JB, Smith DR, 2006. Calculation of material properties and ray tracing in transformation media. Opt Expr, 14(21):9794-9804.
[20]Silva A, Monticone F, Castaldi G, et al., 2014. Performing mathematical operations with metamaterials. Science, 343(6167):160-163.
[21]Wei WL, Mahdjoubi K, Brousseau C, et al., 2016. Enhancement of directivity of an OAM antenna by using Fabry- Perot cavity. 10th European Conf on Antennas and Propagation, p.1-4.
[22]Yang F, Rahmat-Samii Y, 2019. Surface Electromagnetics: with Applications in Antenna, Microwave, and Optical Engineering. Cambridge University Press, Cambridge, UK.
[23]Yang R, Tang WX, Hao Y, et al., 2011. A coordinate transformation-based broadband flat lens via microstrip array. IEEE Antenn Wirel Propag Lett, 10:99-102.
[24]Yu NF, Genevet P, Kats MA, et al., 2011. Light propagation with phase discontinuities: generalized laws of reflection and refraction. Science, 334(6054):333-337.
[25]Yu NF, Genevet P, Aieta F, et al., 2013. Flat optics: controlling wavefronts with optical antenna metasurfaces. IEEE J Sel Top Quant Electron, 19(3):4700423.
[26]Zhang L, Chen XQ, Liu S, et al., 2018. Space-time-coding digital metasurfaces. Nat Commun, 9(1):4334.
[27]Zhang PF, Gong SX, Mittra R, 2017. Beam-shaping technique based on generalized laws of refraction and reflection. IEEE Trans Antenn Propag, 66(2):771-779.
[28]Zhang PF, Li P, Mittra R, 2018. On the design of conformal radomes for beam-shaping of antennas. IEEE Int Symp on Antennas and Propagation & USNC/URSI National Radio Science Meeting, p.1541-1542.
[29]Zhang PF, Wang S, Li P, 2019. Analysis of some mathematical questions of transformation optics and its application to stealth carpet design. J Electron Inform Technol, 41(6): 1336-1343 (in Chinese).
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