EM simulation using the Laguerre-FDTD scheme for multiscale 3-D interconnections

Ha, Myunghyun

07 November 2011

As the current electronic trend is toward integrating multiple functions in a single electronic device, there is a clear need for increasing integration density which is becoming more emphasized than in the past. To meet the industrial need and realize the new system-integration law [1], three-dimensional (3-D) integration is becoming necessary. 3-D integration of multiple functional IC chip/package modules requires co-simulation of the chip and the package to evaluate the performance of the system accurately. Due to large scale differences in the physical dimensions of chip-package structures, the chip-package co-simulation in time-domain using the conventional FDTD scheme is challenging because of Courant-Friedrich-Levy (CFL) condition that limits the time step. Laguerre-FDTD has been proposed to overcome the limitations on the time step. To enhance performance and applicability, SLeEC methodology [2] has been proposed based on the Laguerre-FDTD method. However, the SLeEC method still has limitations to solve practical 3-D integration problems. This dissertation proposes further improvements of the Laguerre-FDTD and SLeEC method to address practical problems in 3-D interconnects and 3-D integration. A method that increases the accuracy in the conversion of the solutions from Laguerre-domain to time-domain is demonstrated. A methodology that enables the Laguerre-FDTD simulation for any length of time, which was challenging in prior work, is proposed. Therefore, the analysis of the low-frequency response can be performed from the time-domain simulation for a long time period. An efficient method to analyze frequency-domain response using time-domain simulations is introduced. Finally, to model practical structures, it is crucial to model dispersive materials. A Laguerre-FDTD formulation for frequency-dependent dispersive materials is derived in this dissertation and has been implemented.

Unconditionally stable method

Finite-difference time-domain

Computational electromagentics

Laguerre-FDTD

Integrated circuits

Three-dimensional integrated circuits

Semiconductors

Effects of Induced Electric Fields on Tissues and Cells

Sequin, Emily Katherine

03 October 2014

No description available.

Biomedical Engineering

Biomedical Research

Electromagnetics

Engineering

Experiments

Medical Imaging

Mechanical Engineering

Eddy Currents

electromagentics

induced electric fields

galvanotaxis

electrotaxis

cells motility

colorectal cancer

liver metastasis

margin determination

modelling induced electromagnetic fields