The exponential growth of global data traffic, driven by cloud computing, artificial intelligence, Internet of Things (IoT), high-definition streaming, and next-generation mobile networks, has redefined the structural requirements of telecommunications infrastructure. Optical fiber has progressively consolidated its role as the core physical infrastructure of global communications due to its high spectral efficiency, low attenuation, scalability, and long-distance reliability. This article critically examines peer-reviewed evidence regarding fiber’s technical foundations, economic relevance, and projected evolution across backbone, aggregation, and access layers. The literature demonstrates consistent performance advantages over copper, coaxial, and radio-based alternatives, as well as its structural role in sustaining digital infrastructure systems. Expansion dynamics in Brazil and the United States reveal distinct regulatory and market configurations that nonetheless converge toward fiber predominance. Emerging technologies—including dense wavelength division multiplexing (DWDM), space division multiplexing (SDM), coherent optical transmission, AI-assisted network optimization, and ultrahigh-density cable architectures—suggest continued scalability in the foreseeable horizon. Although deployment costs and workforce constraints remain relevant challenges, current evidence indicates no alternative transmission medium capable of delivering comparable scalability and performance under existing technological constraints. Optical fiber therefore constitutes the foundational physical layer upon which contemporary digital infrastructures are organized.
Claudio Aguiar (Sat,) studied this question.