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IEEE Journal of Lightwave Technology
Volume 18 Number 2, February 2000

Table of Contents for this issue

Complete paper in PDF format

Optimum Index Profile of the Perfluorinated Polymer-Based GI Polymer Optical Fiber and Its Dispersion Properties

Takaaki Ishigure, Yasuhiro Koike and James W. Fleming Member, OSA

Page 178.

Abstract:

The significant advantages in bandwidth and low material dispersion of perfluorinated (PF) polymer-based graded-index polymer optical fiber (GI POF) are theoretically and experimentally reported for the first time. It is confirmed that the low attenuation and low material dispersion of the PF polymer enables 1 Gb/s km and 10 Gb/s km transmission at 0.85- µm and 1.3-µm wavelengths, respectively. The PF polymer-based GI POF has very low material dispersion (0.0055 ns/nm.km at 0.85 µm), compared with those of the conventional PMMA-based POF and of multimode silica fiber (0.0084 ns/nm.km at 0.85 µm). Since the PF polymer-based GI POF has low attenuation from the visible to near infrared region, not only the 0.65-µm wavelength which is in the low attenuation window of the PMMA-based GI POF, but other wavelengths such as 0.85-µm or 1.3- µm etc. can be adopted for the transmission wavelength. It is clarified in this paper that the wavelength dependence of the optimum index profile shape of the PF polymer-based GI POF is very small, compared to the optimum index profile shape of the silica-based multimode fiber. As a result, the PF polymer-based GI POF has greater tolerance in index profile variation for higher speed transmission than multimode silica fiber. The impulse response function of the PF polymer-based GI POF was accurately analyzed from the measured refractive index profile using a Wentzel, Kramers, Brillouin (WKB) numerical computation method. By considering all dispersion factors involving the profile dispersion, predicted bandwidth characteristic of the PF polymer-based GI POF agreed well with that experimentally measured.

References

  1. R. E. Epworth, "The phenomenon of modal noise in analogue and digital optical fiber communication", in Proc. 4th European Conf. Opt. Commun. , Genoa, Italy,Sept. 1978 , pp.  492- 501. 
  2. Y. Koike, T. Ishigure and E. Nihei, "High-bandwidth graded-index polymer optical fiber", J. Lightwave Technol., vol. 13, pp.  1475- 1489, July  1995 .
  3. T. Ishigure, E. Nihei, S. Yamazaki, K. Kobayashi and Y. Koike, "2.5 Gb/s 100 m data transmission using graded index polymer optical fiber and high speed laser diode at 650-nm wavelength ", Electron. Lett., vol. 31, no. 6, pp.  467- 468, 1995.
  4. T. Kaino, M. Fujiki and K. Jinguji, "Preparation of plastic optical fibers", Rev. Electron. Commun. Lab., vol. 32, pp.  478- 488, 1984.
  5. Y. Koike and T. Ishigure, "Progress of low-loss GI polymer optical fiber from visible to 1.5-µm wavelength", in Proc. 23rd European Conf. Opt. Commun. , vol. 1, Edinburgh, Scotland,Sept. 1997, pp.  59- 62. 
  6. N. Yoshihara, "Low-loss, high-bandwidth fluorinated POF for visible to 1.3-mm wavelength", in Proc. Optic. Fiber Conf. (OFC'98), San Jose, CA, Feb. 1998, Paper ThM4.
  7. T. Ishigure, E. Nihei and Y. Koike, "Optimum refractive index profile of the grade-index polymer optical fiber, toward gigabit data links", Appl. Opt., vol. 35, no. 12, pp.  2048- 2053, 1996.
  8. J. W. Fleming, "Material and mode dispersion in GeO 2 -B2 O3-SiO2 ", J. Amer. Cer. Soc., vol. 59, no. 11-12, pp.  503- 507, 1976.
  9. D. L. Wood and J. W. Fleming, "Computerized refractive index measurement for fiber optic glasses", in NBS Special Publication #574, J. W. Feldman, Ed., vol. 91, 1980.
  10. W. L. Bond, "Measurement of the refractive indices of several crystals", J. Appl. Phys., vol. 36, no. 5, pp.  1674- 1677, 1965 .
  11. R. Olshansky and D. B. Keck, "Pulse broadening in graded-index optical fibers", Appl. Opt., vol. 15, no. 2, pp.  483- 491, 1976.
  12. D. Marcuse, "Calculation of bandwidth from index profiles of optical fibers. 1: Theory", Appl. Opt., vol. 18, pp.  2073- 2080,  1979.