Experimental Characterization and Performance Analysis of Single-Mode and Multi-Mode Optical Fibers for HighSpeed Communication and Sensing Applications

This research paper provides an in-depth experimental and theoretical investigation into the performance characteristics of single-mode and multi-mode optical fibers within modern communication and sensing frameworks. By employing a rigorous experimental setup involving high-purity silica fibers and laser diodes at telecommunication windows (1310 nm and 1550 nm), the study quantifies critical signal integrity factors, including attenuation, chromatic dispersion, and modal broadening. The narrative explores the evolution of fiber optics from early demonstrations of total internal reflection to current high-capacity systems achieving data rates exceeding 400 Gbps. Furthermore, the paper analyzes advanced optical phenomena such as nonlinear Kerr effects, including self-phase modulation and four-wave mixing, alongside engineering innovations like photonic crystal fibers and dispersion compensation techniques. The findings confirm that while single-mode fibers are superior for long-haul high-bandwidth transmission, multi-mode fibers offer practical advantages for short-range networks. Ultimately, this work serves as a comprehensive guide for optimizing fiber optic designs in telecommunications, medical imaging, and industrial sensing applications.