This letter proposes a novel technique for evaluating the longitudinal distribution of the Raman gain characteristics in optical fibers connected to a reference optical fiber with a known Raman gain efficiency. This technique can evaluate the Raman gain efficiency in test fibers using a simplified experimental setup. We performed experiments on various test fibers and confirmed that their Raman gain efficiency can be obtained easily and accurately by employing a reference fiber.

This letter describes the polarization mode dispersion (PMD) characteristic of optical fiber ribbons inserted tightly into helical slots. We investigate the mechanism of the birefringence induced in the optical fiber ribbons by lateral stress resulting from tension and bending in the helical slots. We discuss methods for the design of low PMD cables with reduced birefringence by considering coating materials and tensile strain control.

This letter proposes novel optical fiber cables with extremely small cable diameter that employs rollable 20-fiber ribbons, which will improve fiber ribbon and cable productivity compared with optical fiber cable employing rollable 4-fiber ribbons. We fabricated the cables and investigated its feasibility in terms of high-count compactness, cable productivity, fiber strain induced by cable bending, optical loss characteristics and capacity for mass splicing. As a result, we confirmed the excellence of these cables and their fiber splicing workability.

This paper describes a low-loss submarine optical fiber cable for a long-distance submarine repeaterless transmission system that employs remote pumping. The features of this system are that it has an increased signal power budget and is cost effective and easy to maintain. First, we investigated the relationship between the signal and pump losses and the Raman gain efficiency of optical fiber needed to achieve a submarine repeaterless transmission system operating at 2.5 Gbps and over a distance exceeding 370 km. We manufactured a submarine optical fiber cable based on the results and confirmed that it had low-loss characteristics. Second, we evaluated the long-term loss stability of the optical fiber with a high-power continuous wave (CW) laser light as the pump source. We confirmed that the loss remained unchanged after 1900 hours of exposure to 8 W CW laser light at a wavelength of 1.48 µm. This submarine optical fiber cable is being employed in a commercial submarine repeaterless transmission system between Okinawa and Miyakojima.

To avoid over-engineered and expensive systems, it is important that the design takes account of variations in optical fiber characteristics due to the presence of many fiber pieces and splices in optical fiber networks. We present a design method for optical fiber networks that employ distributed Raman amplification (DRA), that considers variations in both optical losses at signal and pump wavelengths, Raman gain characteristics and splice losses. Our method can be applied to the design of both newly developed systems and installed systems. We show design examples based on our method and reveal the practicability of our method.