In this thesis, the full-vectorial fi nite-element imaginary-distance beam propagation method (FE-ID-BPM) based on the hybrid edge/nodal elements and the perfectly matched layers (PMLs) is used to analyze various waveguides. The asymmetric metal stripe waveguide, the long-range dielectric-loaded SPP waveguide, the six-circular-air-hole fi ber, and the three-annular-shaped-air-hole fi ber are investigated. The eff ective indices, propagation lengths, and modal fi eld pro files are calculated for various boundary settings. In the asymmetric metal stripe waveguide with a thin gold stripe layer on glass substrate surrounded by air, we analyze the leaky modes for which the calculations are refined by using different values of the PML reflection coeffi cient and structure parameters. The long-range dielectric-loaded surface plasmon polariton waveguide (LR-DLSPPW), in which a thin and narrow metal stripe is sandwitched between a square dielectric ridge and a dielectric fi lm supported by a low-index substrate, supports a fundamental long-range dielectricloaded surface plasmon polariton waveguide mode with a propagation length over 6 mm at the wavelength of 1.55 m. Various widths of the Au stripe are examined to understand different guided-mode characteristics. In the two microstructured air-hole fi bers, the convergence of the e ffective refractive indices under di fferent boundary settings is studied.