Title :
Modeling of highly multimode waveguides for time-domain simulation
Author_Institution :
Inst. of Theor. Electr. Eng. & Photonics, Univ. of Siegen, Germany
Abstract :
Optical interconnection technology on the printed circuit board level is a key technology for future microelectronic equipment. Its industrial application requires sophisticated processes and technologies for the manufacturing as well as the design. In this paper, a modeling approach for a static and a time-domain simulation of board-integrated highly multimode optical waveguides with manufacturing based rough surfaces is presented. The transfer behavior of the waveguides is determined by a numerical computation of the step response using a Monte Carlo based ray tracing procedure. The step response is piecewise approximated by exponential functions in order to obtain an analytical representation of the pulse response. This approach allows the application of very fast semi-analytical recursive convolution algorithms.
Keywords :
Monte Carlo methods; function approximation; optical interconnections; optical waveguide theory; printed circuit accessories; printed circuit design; ray tracing; rough surfaces; step response; time-domain analysis; Monte Carlo based ray tracing procedure; analytical representation; board-integrated highly multimode optical waveguides; exponential functions; highly multimode waveguides; manufacturing based rough surfaces; microelectronic equipment; modeling approach; numerical computation; optical interconnection technology; piecewise approximation; printed circuit board level; pulse response; semi-analytical recursive convolution algorithms; step response; time-domain simulation; Circuit simulation; Computational modeling; Manufacturing industries; Manufacturing processes; Microelectronics; Optical interconnections; Optical waveguides; Printed circuits; Pulp manufacturing; Time domain analysis;
Journal_Title :
Selected Topics in Quantum Electronics, IEEE Journal of
DOI :
10.1109/JSTQE.2003.812486
