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ÇİFT GEÇİŞLİ L BAND ERBİYUM KATKILI FİBER YÜKSELTECİN SICAKLIK BAĞIMLILIĞININ İNCELENMESİ

EXAMINATION OF TEMPERATURE DEPENDENCE OF DOUBLE PASS L BAND ERBIUM DOPED FIBER AMPLIFIER

Journal Name:

  • Gazi Üniversitesi Mühendislik-Mimarlık Fakültesi Dergisi

Publication Year:

  • 2012

Key Words:

Keywords (Original Language):

Author NameUniversity of AuthorFaculty of Author
Abstract (2. Language): 
In this study, temperature dependent gain variation of single pass (SP) and double pass (DP) L band erbium doped fiber amplifiers (L-EDFA) has been examined. To do this L-EDFA is experimentally investigated by pumping bi-directionally using 980 nm pump lasers and input signals at -20 dBm powers in the temperature range between 0 °C and 60 °C. Experimental results show that, the gain of DP L-EDFA is higher than that of SP L-EDFA gain. However, the results also show that, temperature dependence of DP L-EDFA is higher than that of SP EDFA. Finally, it is observed that DP L-EDFA can be operated temperature independent in range between 1568 nm and 1588 nm.
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Abstract (Original Language): 
Bu çalışmada, tek geçişli (SP) ve çift geçişli (DP) L band erbiyum katkılı fiber yükseltecin (L-EDFA) sıcaklığa bağımlı kazanç değişimi incelenmiştir. Bu amaçla L-EDFA, 0 °C ile 60 °C arasındaki sıcaklık aralığında, -20 dBm güçteki giriş sinyalleri ve 980 nm pompa lazerleri ile iki yönlü pompalanarak deneysel olarak incelenmiştir. Deneysel sonuçlar DP L-EDFA kazancının SP L-EDFA kazancından daha yüksek olduğunu göstermektedir. Ancak sonuçlar aynı zamanda DP L-EDFA’nın sıcaklık bağımlılığının SP L-EDFA’dan daha yüksek olduğunu da göstermektedir. Sonuç olarak, DP L-EDFA’nın 1568 nm - 1588 nm aralığında sıcaklıktan bağımsız olarak çalıştırılabileceği görülmüştür.
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REFERENCES

References: 

1. Yamada, M., “Overview of wideband optical
fiber amplification technologies”, NTT
Technical Review, 2(12), 34, 2004.
2. Sakamoto, T., Mori, A., Masuda, H., Ono, H.,
“Wideband rare-earth-doped fiber amplification
technologies – Gain bandwidth expansion in the
C and L bands”, NTT Technical Review, 2(12),
38, 2004.
3. Bouzid, B., Abdullah, M.K., Mahdi, M.A.,
“High-Gain Erbium-Doped Fiber Amplifier
Incorporating a Double-Pass Amplification
Technique as a Preamplifier”, Laser Physics,
18(4), 460-463, 2008.
4. Liang, T.C., Hsu, S., “The L-band EDFA of High
Clamped Gain and Low Noise Figure
Implemented Using Fiber Bragg Grating and
Double-Pass Method”, Optics Comm., 281(5),
1134-1139, 2008.
5. Jamaludin, M. Z., Abdullah, M. K., Abdullah, F.,
Abas, A.F., MAhdi, M.A., Rahman, F., “A
Hybrid High-Gain Double-Pass Erbium-Doped
Fiber Amplifier with Dispersion Compensation
Feedback Loop”, Optics and Laser Technol.,
40(2), 270-272, 2008.
6. Naji, A.W., Abidin, M. S. Z., Al-Mansoori, M.H.,
Faidz, A.R., Mahdi, M.A., “Experimental
Investigation of noise in Double-Pass Erbium-
Doped Fiber Amplifiers”, Laser Physics Lett.,
4(2), 145-148, 2007.
7. Chang, C. L., Wang, L., Chiang, Y. J., “A Dual
Pumped Double-Pass L-Band EDFA with High
Gain and Low Noise”, Optics Comm., 267(1),
108-112, 2006.
8. Altuncu, A., “Band Selection in Broadband Loop
ASE Source Using Seed Signal Injection”, IEEE
Photon. Technol. Lett., 18(9), 1043-1045, 2006.
9. Harun, S.W., Samsuri, N.M., Ahmad, H., “Gain-
Clamping Techniques in Two-Stage Double-Pass
L-Band EDFA”, Pramana-Journal of Physics,
66(3), 539-545, 2006.
10. Yi, L.L., Zhan, L., Hu, W.S., Xia, Y.X., “Tunable
Gain-Clamped Double-Pass Erbium-Doped Fiber
Amplifier”, Optics Express, 14(2), 570-574,
2006.
11. Yi, L.L., Zhan, L., Taung, C.S., Luo, S.Y., Hu,
W.S., Su, Y.K., Xia, Y.X., Leng, L.F., “Low
Noise Figure All-Optical Gain-Clamped Parallel
C+L Band Erbium-Doped Fiber Amplifier Using
an Interleaver”, Optics Express, 13(12), 4519-
4524, 2005.
12. Ji, J.H., Zhan, L., Yi, L.L., Tang, C.C., Ye, Q.H.,
Xia, Y.X., “Low Noise-Figure Gain-Clamped LM.
Yücel ve H.H. Göktaş Çift Geçişli L Band Erbiyum Katkılı Fiber Yükseltecin Sıcaklık Bağımlılığının İncelenmesi
242 Gazi Üniv. Müh. Mim. Fak. Der. Cilt 27, No 2, 2012
Band Double-Pass Erbium-Doped Fiber Ring
Lasing Amplifier with an Intereaver”, J. of
Lightwave Technol., 23(3), 1375-1379, 2005.
13. Samsuri, N.M., Harun, S.W., Ahmad, H.,
“Comparison of Performances Between Partial
Doublepass and full double-pass systems in Two-
Stage L-Band EDFA”, Laser Physics Lett.,
1(12), 610-612, 2004.
14. Harun, S.W., Samsuri, N.M., Ahmad, H., “Gain
Enhancement in Partial Double-Pass L-Band
EDFA System Using a Band-Pass Filter”, Laser
Physics Lett., 2(1), 36-38, 2005.
15. Harun, S.W., Samsuri, N.M., Ahmad, H., “Gain
Clamping in Double-Pass L-Band EDFA Using a
Ring Resonator”, Microwave and Optical
Technol. Lett., 43(6), 484-486, 2004.
16. Naji, A.W., Abidin, M.S.Z., Kassir, A.M., Al-
Mansoori, M.H., Abdullah, M.K., Mahdi, M.A.,
“Trade-Off between Single and Double Pass
Amplification Schemes of 1480-nm Pumped
EDFA”, Microwave and Optical Technol.
Lett., 43(1), 38-40, 2004.
17. Yi, L.L., Zhan, L., Ji, J.H., Ye, Q.H.,, Xia, Y.X.,
“Improvement of gain and noise figure in doublepass
L-band EDFA by incorporating a fiber
Bragg grating”, IEEE Photon. Technol. Lett.,
16(4), 1005-1007, 2004.
18. Harun, S.W., Ahmad, H., “Efficient and lownoise
gain flattened double-pass L-band erbiumdoped
fiber amplifier”, Microwave and Optical
Technol. Lett., 40(2), 112-114, 2004.
19. Harun, S.W., Poopalan, P., Ahmad, H., “Double
pass L-band erbium-doped fiber amplifier with
enhanced gain characteristics”, Indian Journal
of Physics, 77B(4), 435-437, 2003.
20. Harun, S.W., Poopalan, P., Ahmad, H., “Gain
enhancement in L-band EDFA through a doublepass
technique”, IEEE Photon.Technol. Lett.,
14(3), 296-297, 2002.
21. Harun, S.W., Ahmad, H., “Gain Clamped Two-
Stage Double-Pass L-Band EDFA with a Single
Fibre Bragg Grating”, Chinese Physics Lett.,
21(10), 1954-1957 2004.
22. Yucel, M., Goktas, H.H., “Design of gain
flattened ultra-wide band hybrid optical
amplifier”, J. Fac. Eng. Archit. Gazi Univ., 22,
863–868, 2007.
23. Yucel, M., Goktas, H.H., “Gain flattening
configurations at the L band erbium doped fiber
amplifiers”, IEEE 15th Signal Process. and
Comm. App., 1–4, 2007.
24. Goktas, H.H., Yucel, M., “Gain flattening filter
optimization of the two stage C band erbium
doped fiber amplifiers (EDFA)”, J. Inst. Sci.
Technol. Sakarya Univ., 10, 10–13, 2006.
25. S., Dung, Chi, J.C., S., Wen, “Gain Flattening of
Erbium-doped Fibre Amplifier Using Fibre Bragg
Gratings”, Electronics Letters, 34(6), 555,
1998.
26. Choi, H. B., Oh, J. M., Lee, D., Ahn, S.J., Park,
B.S, Lee, S.B. “Simple and efficient L-Band
Erbium-Doped Fiber Amplifiers for WDM
Networks”, Optics Comm., 213, 63-66, 2002.
27. Mahdi, M. A., Sheih, S. J. “Gain-Flattened
Extended L-band EDFA with 43nm Bandwidth
Suitable for High Signal Powers”, Optics
Comm., 234, 229-233, 2004.
28. Mizuno, K., Nishi, Y., Mimura, Y., Lida, Y.,
Matsuura, H., Yoon, D., Aso, O., Yamamoto, T.,
Toratani, T., Ono, Y., Yo, A. “Development of
Etalon-Type Gain-Flattening Filter”, Furukawa
Review, 19, 53-58, 2000.
29. Yucel, M., Celebi, F. V., Goktas, H.H.,
“Temperature independent length optimization of
L-band EDFAs providing flat gain”, Optik, 122
(10), 872-876 2011.
30. Goktas, H.H., Yucel, M., “A fuzzy logic based
device for the determination of temperature
dependence of EDFAs”, Microwave and
Optical Technol. Lett., 50, 2331–2334, 2008.
31. Wysocki, P., Conti, N., Holcomb, D., “Simple
modeling approach for the temperature
dependence of the gain of erbium-doped fiber
amplifiers”, SPIE Photonics East, Proc.:
Optical Devices for Fiber Comm., 3847, 214,
1999.
32. Bolshtyansky, M., Wysocki, P., Conti, N.,
“Model of temperature dependence for gain
shape of erbium-doped fiber amplifier”, J. of
Lightwave Technol., 18 1533–1540, 2000.
33. Lolivier, L., Grillet, A., Roy, F., Hamoir, D.,
“DGE-based variable gain EDFA improves both
gain flatness and noise figure for a 70 ◦ C
temperature operating range”, Optical Fiber
Comm. Conf. OFC/NFOEC, 4, 3, 2005.
34. Nakaji, H., Ishizawa, Y., Ohmura, M., Shibata,
T., Inoue, A., Shige- matsu, M., “A temperatureinsensitive
erbium-doped fiber amplifier for
terrestrial wavelength-division-multiplexing
systems”, IEEE Photonics Technol. Lett., 15,
1522–1524, 2003.
35. Lee, W.J., Min, B., Ahn, S., Park, N.,
“Simulation for the effect of cascaded gaintemperature
dependence on 40 channel - 50
EDFA WDM link under temperature
fluctuations”, Lasers and Electro-Optics
CLEO/Pacific Rim’99, 3, 646–647, 1999.
36. Im, Y.E., Oh, K., Chang, S.H., Kim, K.,
DiGiovanni, D.J., “Reduction of temperaturedependent
gain in L-band EDFA using
antimony–aluminum codoped silica EDF”, IEEE
PhotonicsTechnol. Lett., 17, 1839–1841, 2005.
37. Desurvire, E., “Erbium-Doped Fiber Amplifier:
Principles and Applications”, John Wiley and
Sons. Inc., NewYork, 1994.
38. McCumber, D.E., “Theory of phonon-terminated
optical masers”, Phys. Rev., 134, A299–A305,
1964.
Çift Geçişli L Band Erbiyum Katkılı Fiber Yükseltecin Sıcaklık Bağımlılığının İncelenmesi M. Yücel ve H.H. Göktaş
Gazi Üniv. Müh. Mim. Fak. Der. Cilt 27, No 2, 2012 243
39. Miniscalco, W.J., Quimby, R. S., “General
procedure for the analysis of Er3+ cross
sections”, Opt. Lett.,16, 258–260, 1991.
40. Berkdemir, C., Özsoy, S., “The temperature
dependent performance analysis of EDFAs
pumped at 1480nm: a more accurate propagation
equation”, Optics Express 13, 5179–5185, 2005.
41. Lin, M.C., Chi, S., “The gain and optimal length
in the erbium-doped fiber amplifiers with 1480
nm pumping”, IEEE Photonics Technol. Lett.,
4, 354–356, 1992.
42. Yucel, M., Goktas, H.H., Ozkaraca, O.,
“Temperature dependence of noise figure in the
erbium doped fiber amplifier”, J. Fac. Eng.
Archit. Gazi Univ., 25(3), 635–641, 2010.
43. Yucel, M., Goktas, H.H., “Determination of
minimum temperature coefficient of C band
EDFA”, Journal of Applied Sciences, 8(23),
4464-4467, 2008.
44. Hossain, N., Naji, A. W., Mishra, V., Abbou, F.
M., Al-Mansoori, M. H., Mahdi, M. A., Faidz, A.
R., “Modeling, Optimization, and Experimental
Evaluation Of Remotely Pumped Double-Pass
EDFA”, Microwave and Optical Technol.
Lett., 49(9), 2257-2261, 2007

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