"...comprehensively written and illustrated..." (Measurement & Control, May 2003)

Preface.

Acknowledgments.

Introduction to Fiber–Optic Transmission.

Fiber–Optic Cable.

Connectors, Splices, and Other Passive Devices.

Light Sources.

Light Detectors.

Impairments to Light Transmission.

Regenerators and Fiber–Optic Amplifiers.

Wave–Division Multiplexing.

Synchronous Optical Network (SONET) and Synchronous Digital Hierarchy (SDH).

Link Engineering of Lightwave Systems.

Outside Plant Considerations.

System Availability and Survivability.

Powering Options to Improve Availability.

Hybrid Fiber–Coax (HFC) Systems.

On–Premises Wiring of Buildings––Fiber Optics.

Tools for Trouble Shooting Fiber–Optic Systems.

Optical Networking.

Appendix: Acronyms and Abbreviations.

Index.

ROGER L. FREEMAN is a widely recognized expert in telecommunications systems engineering, with over forty–five years of experience in the field. He is the founder and principal of Roger Freeman Associates, a senior life member of the IEEE, and a member of the SCTE. Previous to this Mr. Freeman was principal engineer for advanced system planning at the Raytheon Company; technical manager of ITT Marine, Europe, and staff consultant for ITT Laboratories, Madrid, Spain, and ITU Regional Planning Expert for Northern South America.

A text that sheds much–needed light on one of telecommunication′s brightest technologies

Fiber optics has assumed a dominant place among the available technologies to slake the ever–growing worldwide thirst for bandwidth. As miles and miles of optical fiber cable is being buried underground and under the sea, the demand for those capable of designing and installing fiber–optic systems has also grown. This book gathers all the essential information needed by the network architects, engineers, and craftspeople who plan, install, and maintain fiber–optic systems.

Requiring only a basic math and physics background, Fiber–Optic Systems for Telecommunications acts as both a tutorial and practical reference on both theory and practical applications.

It discusses:
∗ Loss–limited and dispersion–limited fiber links
∗ Optical networking
∗ Availability and survivability of fiber–optic networks
∗ Dense wave–division multiplexing (DWDM)
∗ Light transmission impairments, including Brillioun scattering, Raman scattering, four–wave mixing, polarization mode dispersion (PMD), and other non–linear effects
∗ Hybrid fiber–coax CATV networks
∗ Fiber–optic link budgets and tradeoffs

The text stresses design methods for achieving advanced performance on fiber–optic systems inside cost–effective limits. At the same time, a good dose of practical application is provided to the reader. For example, there is an extensive section on the application of an OTDR (optical time domain reflectometer) for performance measurement and troubleshooting of optical systems.

The book examines the maximum capacity of high–quality single–mode fiber. Here, the ITU has made some major contributions in this arena in their G.650 and G.950 recommendations. The author describes the ITU "grid" or wavelength assignment chart for the 1550 nm band. How close can these light carriers be placed before serious performance degradation occurs? He describes ultimate bit rate capacity in this band alone in the hundred of terabits reaching a final bit rate capacity possibly in the low thousands of terabits per second. The author communicates the excitement of such research in his writing.