POTENSI SENSOR SERAT OPTIK DETEKSI KONSENTRASI KOLESTEROL SEBAGAI MEDIA PEMBELAJARAN GELOMBANG DAN OPTIK
DOI:
https://doi.org/10.26740/jppipa.v2n1.p1-5Keywords:
media pembelajaran, sensor serat optik, larutan kolesterolAbstract
Penggunaan media pembelajaran sangat dibutuhkan salah satu mata kuliah gelombang dan optik. Salah satu solusi penggunaan media pembelajaran pada perkuliahan gelombang dan optik dengan menggunakan sensor serat optik untuk deteksi konsentrasi kolesterol. Penelitian ini bertujuan untuk mendeteksi konsentrasi kolesterol dengan prinsip perambatan sinar laser yang dipandu serat optik coupler sebagai profil berbasis intensitas melalui medium larutan kolesterol dengan konsentrasi yang bervariasi. Adapun variasi konsentrasi larutan kolesterol adalah 0 ppm, 50 ppm, 100 ppm, 150 ppm, 200 ppm, 250 ppm, dan 300 ppm. Mekanisme kerja deteksi konsentrasi kolesterol adalah perambatan sinar laser He-Ne panjang gelombang 632,5 nm melalui serat optik coupler pada larutan kolesterol dan dipantulkan kembali oleh cermin datar kemudian sinar pantul dipandu melalui serat optik coupler sehingga terdeteksi oleh detektor silikon SL-818 yang berupa tegangan output. Hasil pendeteksian menunjukkan bahwa tegangan output maksimum menunjukkan penurunan secara linier terhadap peningkatan konsentrasi larutan kolesterol dengan sensitivitas 0,0016 mV/ppm dan linieritas lebih dari 96%. Hasil penelitian ini menunjukkan parameter dan kinerja sensor yang akurat sehingga memiliki potensi sebagai media perkuliahan gelombang dan optik.References
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Sastikumar D., G. Gobi, B. Renganathan. 2010. Determination Of The Thicness Of A Transparent Plate Using A Reflective Fiber Optic Displacement Sensor. Optics & Laser Technology, 42, 911 - 917
Siriwan Nantaphola, Orawon Chailapakul, Weena S. 2015. Sensitive and selective electrochemical sensor using silver nanoparticles modified glassy carbon electrode for determination of cholesterol in bovine serum, Sensors and Actuators B 207, 193198.
Swatland H. J. 2001. Effect Of Connective Tissue On The Shape Of Reflectance Spectra Obtained With A Fibre-Optic Fat-Depth Probe In Beef. Meat Science, 57, 209 - 213.
Xiaojun Cai, Xia Gaoa L.W., Xianfu Lin. 2013. A layer-by-layer assembled and carbon nanotubes/gold nanoparticles-based bienzyme biosensor for cholesterol detection, Sensors and Actuators B 181, 575 583.
Yasin M., H. Ahmad, K. Thambiratnam, A. A. Jasim, S. W. Phang, S. W. Harun. 2013. Design of Multimode Tapered Fibre Sensor for Glucose Detection, Optoelectronics and Advanced Materials Vol. 7, No. 5 - 6. p. 371 - 376.
Yasin M., Harun S.W., Kusminarto, Karyono, Ahmad H. 2007. Construction of fiber optic sensor for micro-displacement measurement based on refelctive intensity modulation techniuque., 2nd Jogja International Physics Conference, 6-8 September, Gadjah Mada University, Yogayakarta.
Budiyanto.M. 2011. Peningkatan Hasil Belajar Mahasiswa Sains Pada Pembelajaran Interaksi Antar Faktor Fisik (IAFF) Dengan Media Pembelajaran Motor Listrik. Laporan PTK Lembaga Penelitian Unesa.
Cox B. 2013. Introduction to Laser-Tissue Interactions, Optics In Medicine
Csele, M. 2004. Fundamental of Light Sourcesand Laser. John Wiley and Sons
Faria J.B. 1998. A theoretical analysis of the bifurcated fiber bundle displacement sensor. IEEE Trans on Inst and Meas., vol. 47, pp. 742-747.
Griffith.DJ. 1999. Introduction to Elektrodynamics. New Jersey. Prentice Hall.
Hida N., N. Bidin, M. Abdullah, M. Yasin. 2013. Fiber Optic Displacement Sensor for Honey Purity Detection in Distilled Water. Optoelectronics and Advanced Materials Vol. 7, No. 7 - 8. p. 565 - 568.
Jatmiko B, Wahono W., Martini, Budiyanto M. 2015. Buku Prototipe Kurikulum Pendidikan Sains Berorientasi KKNI. Jaudar Press.
Jian Ji, Zhihui Zhou, Xiaolian Zhao, Jiadi Sun, Xiulan Sun. 2015. Electrochemical sensor based on molecularly imprintedfilm at Au nanoparticles-carbon nanotubes modified electrode for determination of cholesterol. Biosensors and Bioelectronics 66, 590595.
Niemz, M.H. 2007. Laser Tissue Interaction, Fundmental and Aplication. Third Enlarge Edition, Springer
Perez Miguel A., Gonzalez Olaya, Arias Jose R. 2013. Optical Fiber Sensors for Chemical and Biological Measurements. Licensee InTech.
Prasad, P.N. 2003. Introduction to Biophotonics, Wiley Interscience, John Wiley Publication
Rahman H. A., S. W. Harun, M. Yasin, H. Ahmad. 2012. Fiber Optic Salinity Sensor Using Beam-Through Technique. Optik xxx.
Rahman H. A., S. W. Harun, M. Yasin, H. Ahmad. 2012. Fiber Optic Salinity Sensor Using Fiber Optic Displacement Measurement with Flat and Concave Mirror. IEEE Journal of Selected Topics in Quantum Electronics, Vol. 18, No. 5, pp. 1529 - 1533.
Rahman H. A. , S. W. Harun, Saidin N., M. Yasin, H. Ahmad. 2012. Fiber Optic Displacement Sensor for Temperature Measurement. IEEE Sensors Journal Vol. 12, No. 5, pp. 1361 - 1364.
Saniye Soylemez, Yesemin A.U., Cevher Gundo H., Yavuz Ergun, Levent T. 2015. Electrochemical and optical properties of a conducting polymer and its use in a novel biosensor for the detection of cholesterol. Sensors and Actuators B 212, 425433.
Sastikumar D., G. Gobi, B. Renganathan. 2010. Determination Of The Thicness Of A Transparent Plate Using A Reflective Fiber Optic Displacement Sensor. Optics & Laser Technology, 42, 911 - 917
Siriwan Nantaphola, Orawon Chailapakul, Weena S. 2015. Sensitive and selective electrochemical sensor using silver nanoparticles modified glassy carbon electrode for determination of cholesterol in bovine serum, Sensors and Actuators B 207, 193198.
Swatland H. J. 2001. Effect Of Connective Tissue On The Shape Of Reflectance Spectra Obtained With A Fibre-Optic Fat-Depth Probe In Beef. Meat Science, 57, 209 - 213.
Xiaojun Cai, Xia Gaoa L.W., Xianfu Lin. 2013. A layer-by-layer assembled and carbon nanotubes/gold nanoparticles-based bienzyme biosensor for cholesterol detection, Sensors and Actuators B 181, 575 583.
Yasin M., H. Ahmad, K. Thambiratnam, A. A. Jasim, S. W. Phang, S. W. Harun. 2013. Design of Multimode Tapered Fibre Sensor for Glucose Detection, Optoelectronics and Advanced Materials Vol. 7, No. 5 - 6. p. 371 - 376.
Yasin M., Harun S.W., Kusminarto, Karyono, Ahmad H. 2007. Construction of fiber optic sensor for micro-displacement measurement based on refelctive intensity modulation techniuque., 2nd Jogja International Physics Conference, 6-8 September, Gadjah Mada University, Yogayakarta.
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Published
2018-07-09
How to Cite
Budiyanto, M., Suhariningsih, S., & Yasin, M. (2018). POTENSI SENSOR SERAT OPTIK DETEKSI KONSENTRASI KOLESTEROL SEBAGAI MEDIA PEMBELAJARAN GELOMBANG DAN OPTIK. JPPIPA (Jurnal Penelitian Pendidikan IPA), 2(1), 1–5. https://doi.org/10.26740/jppipa.v2n1.p1-5
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