FİBER OPTİK AKIM SENSÖRÜNÜN MODELLENMESİ VE SİMÜLASYONU

Hakan Aydoğan; Faruk Aras

FİBER OPTİK AKIM SENSÖRÜNÜN MODELLENMESİ VE SİMÜLASYONU

Year 2008, Volume: 23 Issue: 4, 0 - , 18.02.2013

Abstract

Bu çalışmada, Faraday etkili fiber optik akım sensörünü oluşturan polarizör, analizör, lazer, fotodiyot gibi elemanlar Matlab Simulink programı kullanılarak ayrı ayrı modellenmekte ve simüle edilmektedir. Böylece sistemi oluşturan parçaların optimum performansları belirlenebilmektedir. Tüm bu modellerin birleştirilmesiyle, Faraday etkili fiber optik akım sensörünün sistem modeli oluşturulmakta ve çeşitli dinamiklere karşı cevabı incelenmektedir. Elde edilen sonuçlar analiz edilmekte ve değerlendirilmektedir. Daha düşük akımların ölçülmesi için fiberin sarım sayısının artırılması, sistem cevabını geciktirmektedir. Sistemin çıkışı, ışığın kutuplanma açısı ölçüldüğü için lazer optik gücünden etkilenmemektedir.

Keywords

Fiber optik sensor, Faraday etkisi, modelleme, simülasyon.

References

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Power Converters”, Master’s Thesis Project,
Microsystem Technology Group School of
Electrical Engineering Royal Institute of
Technology, Stockholm, 1, (2006).
2. Leung, F.Y.C., Chiu, W.C.K., Demokan, M.S.,
“Fiber-Optic Current Sensor Developed for
Power System Measurement”, IEEE Internation
Conference on Advances in Power System
Control, 637, 638, (1991).
3. Tantaswadi, P., “In-Line Sagnac Interferometer
Current Sensor”, For the Degree of Doctor of
Philosophy, Office of Graduate Studies of Texas
A&M University, 1, (1995).
4. Briffod, F., Alasia, D., Thévenaz, L., Cuénoud,
G., Robert, P., “Extreme Current Measurements
Using A Fibre Optics Current Sensor”, Optical
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(2002).
5. Ulmer, E.A., “A High-Accuracy Optical
Current Transducer for Electric Power System”,
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No. 2, 896, (1990).
6. Schaer, T., Rusnov, R., Eagle, S., Jastrebski, J.,
Albanese, S., Fernando, X., “A Dynamic
Simulation Model for Semiconductor Laser
Diodes”, IEEE CCECE Canadian Conference,
, 297, (2003).
7. Cvetković, M., Matavulj, P., Radunović, J.,
Marinčić, A., “An InGaAs P-i-N Photodiode
Model: Description and Implementations in The
Analysis of The 1.55 μm Lightwave System”,
Journal of Optical Communications, Vol. XX,
No. Y, 2, (2000).
8. Jiao, B., Wang, Z., Liu, F., Bi, W.,
“Interferometric Fiber-Optic Current Sensor with
Phase Conjugate Reflector”, Proceeding of the
IEEE International Conference on
Information Acquisition, China, 707, 708, (2006).
9. Özkan, M., “Fiber Optik Kablolar ile İletişim
ve Fiber Optik Dalgakılavuzları”, Yüksek lisans
tezi, Osmangazi Üniversitesi Fen Bilimleri
Enstitüsü, Eskişehir, 10, (1998).
10. Stokes, J.L., Bartsch, R.R., Cochrane, J.C.,
Chrien, R.E., Forman, P.J., Looney, L.D.,
Tabaka, L.J., Veeser, L.R., “Precision Current
Measurements on Pegasus II Using Faraday
Rotation”, Pulsed Power Conference, 381,
(1995).
11. Kerstetter, P.C., “Models of Optoelectronic
Devices Suitable for Electrical Circuit
Simulation”, For the Degree of Doctor of
Philosophy, Georgia Institute of Technology, 41,
, 181, (1998).
12. Si PIN photodiode S5971, S5972, S5973
series [online],
http://sales.hamamatsu.com/assets/pdf/parts_S/S5
_etc.pdf, 2, (Ziyaret tarihi: 04.04.2007).
13. Habibullah, F., Huang, W. P., “A Self-
Consistent Analysis of Semiconductor Laser Rate
Equations For System Simulation Purpose”,
Optics Communications 258, 237, 238, (2006).
14. Fiber Optics [online],
http://www.commsplace.com/Knowledge/ITcs/ht
ml/tutorials/fibre_optics/introduction_fibre_optic
s.htm, (Ziyaret tarihi: 30.04.2008).
15. Reddy, M., “Imbedded Optical Fiber Sensor
of Differential Strain And Temperature in
Graphite/Epoxy Composites”, For the Degree of
Master od Science, Virginia Polytechnic Institute
and State University, Virginia, 22, (1986).
16. Rose, A. H., Etzel, S. M. Wang, C. M.,
“Verdet Constant Dispersion in Annealed Optical
Fiber Current Sensors”, Journal of Lightwave
Technology, Vol. 15, No. 5, 806, (1997).
17. Li, H. Y., Crossley, P. A., Aggarwal, R. K.,
“Application of Fibre Optical Current Transducer
to Protection”, Developments in Power System
Protection, IEE, 275, (1997).
18. Gan, K. G., Bowers, J. E., “Measurement of
Gain, Group Index, Group Velocity Dispersion,
and Linewidth Enhancement Factor of an InGaN
Multiple Quantum-Well Laser Diode”, IEEE
Photonics Technology Letters, Vol. 16, No. 5,
, (2004).

Year 2008, Volume: 23 Issue: 4, 0 - , 18.02.2013

Hakan Aydoğan Faruk Aras

Abstract

References

1. Liehr, S., “Optical Measurement of Currents in
Power Converters”, Master’s Thesis Project,
Microsystem Technology Group School of
Electrical Engineering Royal Institute of
Technology, Stockholm, 1, (2006).
2. Leung, F.Y.C., Chiu, W.C.K., Demokan, M.S.,
“Fiber-Optic Current Sensor Developed for
Power System Measurement”, IEEE Internation
Conference on Advances in Power System
Control, 637, 638, (1991).
3. Tantaswadi, P., “In-Line Sagnac Interferometer
Current Sensor”, For the Degree of Doctor of
Philosophy, Office of Graduate Studies of Texas
A&M University, 1, (1995).
4. Briffod, F., Alasia, D., Thévenaz, L., Cuénoud,
G., Robert, P., “Extreme Current Measurements
Using A Fibre Optics Current Sensor”, Optical
Fiber Sensors Conference Technical Digest, 1,
(2002).
5. Ulmer, E.A., “A High-Accuracy Optical
Current Transducer for Electric Power System”,
IEEE Transactions on Power Delivery, Vol. 5,
No. 2, 896, (1990).
6. Schaer, T., Rusnov, R., Eagle, S., Jastrebski, J.,
Albanese, S., Fernando, X., “A Dynamic
Simulation Model for Semiconductor Laser
Diodes”, IEEE CCECE Canadian Conference,
, 297, (2003).
7. Cvetković, M., Matavulj, P., Radunović, J.,
Marinčić, A., “An InGaAs P-i-N Photodiode
Model: Description and Implementations in The
Analysis of The 1.55 μm Lightwave System”,
Journal of Optical Communications, Vol. XX,
No. Y, 2, (2000).
8. Jiao, B., Wang, Z., Liu, F., Bi, W.,
“Interferometric Fiber-Optic Current Sensor with
Phase Conjugate Reflector”, Proceeding of the
IEEE International Conference on
Information Acquisition, China, 707, 708, (2006).
9. Özkan, M., “Fiber Optik Kablolar ile İletişim
ve Fiber Optik Dalgakılavuzları”, Yüksek lisans
tezi, Osmangazi Üniversitesi Fen Bilimleri
Enstitüsü, Eskişehir, 10, (1998).
10. Stokes, J.L., Bartsch, R.R., Cochrane, J.C.,
Chrien, R.E., Forman, P.J., Looney, L.D.,
Tabaka, L.J., Veeser, L.R., “Precision Current
Measurements on Pegasus II Using Faraday
Rotation”, Pulsed Power Conference, 381,
(1995).
11. Kerstetter, P.C., “Models of Optoelectronic
Devices Suitable for Electrical Circuit
Simulation”, For the Degree of Doctor of
Philosophy, Georgia Institute of Technology, 41,
, 181, (1998).
12. Si PIN photodiode S5971, S5972, S5973
series [online],
http://sales.hamamatsu.com/assets/pdf/parts_S/S5
_etc.pdf, 2, (Ziyaret tarihi: 04.04.2007).
13. Habibullah, F., Huang, W. P., “A Self-
Consistent Analysis of Semiconductor Laser Rate
Equations For System Simulation Purpose”,
Optics Communications 258, 237, 238, (2006).
14. Fiber Optics [online],
http://www.commsplace.com/Knowledge/ITcs/ht
ml/tutorials/fibre_optics/introduction_fibre_optic
s.htm, (Ziyaret tarihi: 30.04.2008).
15. Reddy, M., “Imbedded Optical Fiber Sensor
of Differential Strain And Temperature in
Graphite/Epoxy Composites”, For the Degree of
Master od Science, Virginia Polytechnic Institute
and State University, Virginia, 22, (1986).
16. Rose, A. H., Etzel, S. M. Wang, C. M.,
“Verdet Constant Dispersion in Annealed Optical
Fiber Current Sensors”, Journal of Lightwave
Technology, Vol. 15, No. 5, 806, (1997).
17. Li, H. Y., Crossley, P. A., Aggarwal, R. K.,
“Application of Fibre Optical Current Transducer
to Protection”, Developments in Power System
Protection, IEE, 275, (1997).
18. Gan, K. G., Bowers, J. E., “Measurement of
Gain, Group Index, Group Velocity Dispersion,
and Linewidth Enhancement Factor of an InGaN
Multiple Quantum-Well Laser Diode”, IEEE
Photonics Technology Letters, Vol. 16, No. 5,
, (2004).

There are 85 citations in total.

Details

Primary Language	Turkish
Journal Section	Makaleler
Authors	Hakan Aydoğan This is me Faruk Aras This is me
Publication Date	February 18, 2013
Submission Date	February 18, 2013
Published in Issue	Year 2008 Volume: 23 Issue: 4

Cite

APA	Aydoğan, H., & Aras, F. (2013). FİBER OPTİK AKIM SENSÖRÜNÜN MODELLENMESİ VE SİMÜLASYONU. Gazi Üniversitesi Mühendislik Mimarlık Fakültesi Dergisi, 23(4).
AMA	Aydoğan H, Aras F. FİBER OPTİK AKIM SENSÖRÜNÜN MODELLENMESİ VE SİMÜLASYONU. GUMMFD. March 2013;23(4).
Chicago	Aydoğan, Hakan, and Faruk Aras. “FİBER OPTİK AKIM SENSÖRÜNÜN MODELLENMESİ VE SİMÜLASYONU”. Gazi Üniversitesi Mühendislik Mimarlık Fakültesi Dergisi 23, no. 4 (March 2013).
EndNote	Aydoğan H, Aras F (March 1, 2013) FİBER OPTİK AKIM SENSÖRÜNÜN MODELLENMESİ VE SİMÜLASYONU. Gazi Üniversitesi Mühendislik Mimarlık Fakültesi Dergisi 23 4
IEEE	H. Aydoğan and F. Aras, “FİBER OPTİK AKIM SENSÖRÜNÜN MODELLENMESİ VE SİMÜLASYONU”, GUMMFD, vol. 23, no. 4, 2013.
ISNAD	Aydoğan, Hakan - Aras, Faruk. “FİBER OPTİK AKIM SENSÖRÜNÜN MODELLENMESİ VE SİMÜLASYONU”. Gazi Üniversitesi Mühendislik Mimarlık Fakültesi Dergisi 23/4 (March 2013).
JAMA	Aydoğan H, Aras F. FİBER OPTİK AKIM SENSÖRÜNÜN MODELLENMESİ VE SİMÜLASYONU. GUMMFD. 2013;23.
MLA	Aydoğan, Hakan and Faruk Aras. “FİBER OPTİK AKIM SENSÖRÜNÜN MODELLENMESİ VE SİMÜLASYONU”. Gazi Üniversitesi Mühendislik Mimarlık Fakültesi Dergisi, vol. 23, no. 4, 2013.
Vancouver	Aydoğan H, Aras F. FİBER OPTİK AKIM SENSÖRÜNÜN MODELLENMESİ VE SİMÜLASYONU. GUMMFD. 2013;23(4).

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