Abstract:
It is expected that the explosion in Internet traffic implies a paradigm shift from a voice network to a data-centric network. The first and most important requirement of...Show MoreMetadata
Abstract:
It is expected that the explosion in Internet traffic implies a paradigm shift from a voice network to a data-centric network. The first and most important requirement of future transport networks is the large bandwidth transport capability which enables the paradigm shift. In addition, requirements for new service attributes are becoming more tangible. Furthermore, high reliability will be indispensable because the multimedia network will be the basis for the information society. To develop the robust and efficient networks that satisfy the requirements above, new network architectures and technologies should be developed. Photonic networks employing dense WDM technologies appear to be the solution. In this article, first the basic concept of the future photonic network is depicted. Next, the capability of large-capacity fiber transmission is shown. The critical degradation factor of fiber nonlinearity is analyzed, and the effectiveness of distributed amplification is quantitatively demonstrated. Furthermore, advances in fiber amplifiers which greatly widen the usable fiber window are shown. Other key technologies such as absolute frequency referencing and multiple channel frequency management techniques are also discussed.
Published in: IEEE Communications Magazine ( Volume: 37, Issue: 2, February 1999)
DOI: 10.1109/35.747252
References is not available for this document.
Select All
1.
K. Sato, "Introduction strategy of photonic network technologies to create bandwidth abundant multimedia networks", Trends in Optics and Photonics, vol. 20, June 1998.
2.
J. Kani, "Bidirectional transmission to suppress inter-wavelength-band nonlinear interactions in ultra-wideband WDM transmission systems", 3rd Optoelect. Conf. '98 Tech. Dig., pp. 412-413, 1998.
3.
G. P. Agrawal, Nonlinear Fiber Optics, Boston:Academic, 1989.
4.
N. Takachio and S. Ohteru, "Scale of WDM transport network using different types of fibers", IEEE JSAC Special Issue on High-Capacity Optical Transport Networks, 1998.
5.
H. Masuda, "Wideband and low noise optical amplification using distributed Raman amplifiers and erbium-doped fiber amplifiers", Proc. ECOC ' 98, 1998.
6.
M. Nissov, "100 Gb/s (1×10 Gb/s) WDM Transmission over 7200 km using distributed Raman amplification", ECOC '97, 1997.
7.
R. W. Tkach and F. Forghieri, "Lightwave system limitations of nonlinear optical effects", Proc. ECOC '96, 1996.
8.
T. Komukai, "Upconversion Pumped Thulium-Doped Fluoride Fiber Amplifier and Lase Operating at 1.47 mm", IEEE Quantum Elect., vol. 31, pp. 1880-1889, 1995.
9.
A. Imaoka and M. Teshima, Optical frequency reference in optical path networks based on WDM technique, pp. 37-43, Nov. 1996.
10.
M. Teshima, M. Koga and K. Sato, "25GHz-spaced and over 3 THz-span optical frequency grids anchored at 193.1 THz using injection and mode-locked laser diode", Proc. 23rd Euro. Conf. Opt. Commun., 1997.
11.
K. Sato, Advances in Transport Network Technologies — Photonic Networks ATM and SDH, Artech, 1996.
