The Analytical Foundations of Loop Antennas and Nano-Scaled Rings [electronic resource] /
by Arnold McKinley.
- 1st ed. 2019.
- XXII, 203 p. 78 illus., 70 illus. in color. online resource.
- Signals and Communication Technology, 1860-4870 .
- Signals and Communication Technology, .
Introduction -- Wave-Matter Interactions -- Perfectly Conducting Closed Loops -- Lossy Metal Closed Loops and Nano-Rings -- Split-Ring Resonators -- Multiple-Gap Ring Resonators -- Non-Toroidal Nano-rings -- Arrays of Nano-rings -- Fabrication of Nano-rings -- Applications -- Computations.
This book develops the analytical theory of perfectly conducting and lossy metal, circular, round-wire loop antennas and nano-scaled rings from the radio frequency (RF) regime through infrared and the optical region. It does so from an antenna theory perspective. It is the first time that all of the historical material found in the literature has appeared in one place. It includes, particularly, material that has appeared in the literature only in the last decade and some new material that has not yet been published. The book derives the input impedance, resonances and anti-resonances, the RLC circuit model representation, and radiation patterns not only of closed loops and rings, but also of loops and rings loaded randomly and multiply with resistive and reactive impedances. Every derivation is compared with simulations run in Microwave Studio (MWS). It looks carefully at the physical response of loop antennas and nano-rings coupled to a source at one point in the periphery and at such rings illuminated by a plane wave arriving from every different direction with the E-field in all polarizations. The book ends with a brief look at polygonal loops, two dimensional arrays of nano-rings, and Yagi-Uda arrays. .
9789811358937
10.1007/978-981-13-5893-7 doi
Telecommunication. Optical materials. Microtechnology. Microelectromechanical systems. Engineering mathematics. Engineering—Data processing. Microwaves, RF Engineering and Optical Communications. Optical Materials. Microsystems and MEMS. Mathematical and Computational Engineering Applications.