A near field experimental investigation of interaction between two horns /

Muresan, L. V. (Letitia V.)

January 1981

No description available.

Antennas, Horn.

A near field experimental investigation of interaction between two horns /

Muresan, L. V. (Letitia V.)

January 1981

No description available.

Antennas, Horn.

Optimum probes for near-field antenna measurements on a plane

Huddleston, G. K. (Gene Keith)

08 1900

No description available.

Near-fields

Antennas, Horn

Novel antennas on Si and organic substrates

Iliopoulos, Vasileios

08 1900

No description available.

Antennas, Horn

Micromachining

Lasers Industrial applications

Polymer liquid crystals

A novel method for incorporating periodic boundaries into the FDTD method and the application to the study of structural color of insects

Lee, Richard Todd.

January 2009

Thesis (Ph.D)--Electrical and Computer Engineering, Georgia Institute of Technology, 2009. / Committee Chair: Smith, Glenn; Committee Member: Buck, John; Committee Member: Goldsztein, Guillermo; Committee Member: Peterson, Andrew; Committee Member: Scott, Waymond. Part of the SMARTech Electronic Thesis and Dissertation Collection.

A novel method for incorporating periodic boundaries into the FDTD method and the application to the study of structural color of insects

Lee, Richard Todd

29 May 2009

In this research, a new technique for modeling periodic structures in the finite-difference time-domain (FDTD) method is developed, and the technique is applied to the study of structural color in insects. Various recent supplements to the FDTD method, such as a nearly-perfect plane-wave injector and convolutional perfectly matched layer boundary condition, are used. A method for implementing the FDTD method on a parallel, distributed-memory computer cluster is given. To model a periodic structure, a single periodic cell is terminated by periodic boundary conditions (PBCs). A new technique for incorporating PBCs into the FDTD method is presented. The simplest version of the technique is limited to two-dimensional, singly-periodic geometries. The accuracy is demonstrated by comparing to independent results calculated with a frequency-domain, mode-matching method. The periodic FDTD method is then extended to the more general case of three-dimensional, doubly-periodic problems. This extension requires additional steps and imposes new limitations. The computational cost and limitations of the method are presented. Certain species of butterflies exhibit structural color, which is caused by quasi-periodic structures on the scales covering the wings. Numerical experiments are performed to develop a technique for modeling quasi-periodic structures using the periodic FDTD method. The observed structural color of butterflies is then calculated from the electromagnetic data using colorimetric theory. Three types of butterflies are considered. The first type are from the Morpho genus. These are typically a brilliant, almost metallic, blue color. The second type is the Troides magellanus, which exhibits an interplay of structural and pigmentary color, but the structural color is only visible near grazing incidence. The final type is the Ancyluris meliboeus, which exhibits iridescence on the ventral side. For all cases, the effects of changing the dimensions of various structural elements are considered. Finally, some earlier work on the design of TEM horn antennas is presented. The TEM horn is a simple and popular antenna, but only limited design information is available in the literature. A parametric study was performed, and the results are given. A complete derivation of the characteristic impedance of the basic antenna is also presented.

Periodic boundary conditions

Structural color

Finite-difference time-domain

Butterfly

Numerical methods

Finite differences

Time-domain analysis

Maxwell equations

Antennas, Horn

Computer simulation