Implementation of A Flat-Bottom Luneburg Lens Based on Conformal Transformation Optics

Binbin Yang; Yongduk Oh; Xinchen Hu; Jacob J Adams

Implementation of A Flat-Bottom Luneburg Lens Based on Conformal Transformation Optics

Binbin Yang
, Yongduk Oh
, Xinchen Hu
, Jacob J Adams

Electrical and Computer Engineering

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Abstract

Using transformation optics based on numerical conformal mapping, a 2D flat-bottom Luneburg lens is designed and realized using isotropic materials. The gradient-index material profile is discretized and realized through unit cells. Full wave simulation is conducted to verify the performance. Maximum 2D directivity of 14.9 dBi is achieved for a line source when the 2D lens has a free-space electrical size of 10λ. A wide field of view (~ 120 degree) is obtained for a set of planar offset feed points spanning 3.3λ.

Original language	English
Title of host publication	Unknown book
State	Published - 2021

Cite this

@inproceedings{71ecf8fe10e8439c8723024942b74592,

title = "Implementation of A Flat-Bottom Luneburg Lens Based on Conformal Transformation Optics",

abstract = "Using transformation optics based on numerical conformal mapping, a 2D flat-bottom Luneburg lens is designed and realized using isotropic materials. The gradient-index material profile is discretized and realized through unit cells. Full wave simulation is conducted to verify the performance. Maximum 2D directivity of 14.9 dBi is achieved for a line source when the 2D lens has a free-space electrical size of 10λ. A wide field of view (\textasciitilde{} 120 degree) is obtained for a set of planar offset feed points spanning 3.3λ.",

author = "Binbin Yang and Yongduk Oh and Xinchen Hu and Adams, \{Jacob J\}",

year = "2021",

language = "English",

booktitle = "Unknown book",

}

TY - GEN

T1 - Implementation of A Flat-Bottom Luneburg Lens Based on Conformal Transformation Optics

AU - Yang, Binbin

AU - Oh, Yongduk

AU - Hu, Xinchen

AU - Adams, Jacob J

PY - 2021

Y1 - 2021

N2 - Using transformation optics based on numerical conformal mapping, a 2D flat-bottom Luneburg lens is designed and realized using isotropic materials. The gradient-index material profile is discretized and realized through unit cells. Full wave simulation is conducted to verify the performance. Maximum 2D directivity of 14.9 dBi is achieved for a line source when the 2D lens has a free-space electrical size of 10λ. A wide field of view (~ 120 degree) is obtained for a set of planar offset feed points spanning 3.3λ.

AB - Using transformation optics based on numerical conformal mapping, a 2D flat-bottom Luneburg lens is designed and realized using isotropic materials. The gradient-index material profile is discretized and realized through unit cells. Full wave simulation is conducted to verify the performance. Maximum 2D directivity of 14.9 dBi is achieved for a line source when the 2D lens has a free-space electrical size of 10λ. A wide field of view (~ 120 degree) is obtained for a set of planar offset feed points spanning 3.3λ.

M3 - Conference contribution

BT - Unknown book

ER -

Implementation of A Flat-Bottom Luneburg Lens Based on Conformal Transformation Optics

Abstract

Fingerprint

Cite this