Proceedings National Conference PKM Center

Mi merupakan salah satu makanan yang disukai oleh masyarakat Indonesia. Potensi bahaya mi dapat terjadi ketika adanya penyelewengan seperti penggunaan formalin dalam pegawetannya. Formalin yang merupakan senyawa tersusun atas karbon, hidrogen, dan oksigen dengan rumus CH₂O memilki efek menyebabkan iritasi tenggorokan, hidung, mata, kulit dan asma hingga kanker pada saluran pernafasan dan pencernaan bilaterminum dalam konsentrasi tinggi. Detektor formalin pada mi berbasis fiber optik dan internet of things menjadi salah satu alat dalam pendeteksian formalin. Detektor ini berprinsip pada penggunaan fiber optik dalam pendeteksian formalin pada sampel. Hasil konsentrasi yang diperoleh akan ditampilkan pada OLED serta dikirmkan menuju smarthphone melalui bantuan sistem internet of things. Hasil desain 3 dimensi dari alat dapat dibuat dan begitu pula proses penggunaan alat tersebut.

World Instant Noodles Association. 2019. Global Demand for Instant Noodles. Osaka: World Instant Noodles Association. https://instantnoodles.org/en/noodles/market.html (diakses pada 01 September 2019).

Sa’diyah, H., Regeista, F., Syahwal, A. J., dan Yatmo, A. H. 2013. Digital Formaldehyde Meter” Inovasi Pendeteksi Kandungan Formalin Cepat Dan Akurat Dengan Teknologi Berbasis Instrumen Electronic Nose. Prosiding Elektronik (e-Proceedings) PIMNAS Program Kreativitas Mahasiswa-Karsa Cipta (PKM-KC), Ditjen Dikti Kemdikbud RI, Jakarta.

Olivero, M. , G. Perrone, A. Vallan, and D. Tosi. 2014. Comparative Study of Fiber Bragg Gratings and Fiber Polarimetric Sensors for Structural Health Monitoring of Carbon Composites. Advances in Optical Technologies, 2014 (804905): 1-8.

Sikander, M., Malik, A., Khan, M.S.G., Qurratul-ain., dan Khan, R.G., 2017. Instant Noodle: are They Really Good for Health? A Review. Electronic Journal of Biology. 13(3): 222-227.

Anggraeni, R. and Saputra, D., 2018. Physicochemical characteristics and sensorial properties of dry noodle supplemented with unripe banana flour. Food Research, 2(3): 270-278.

Zhang, N. and Ma, G., 2016. Noodles, traditionally and today. Journal of Ethnic Foods, 8(3):1-4.

Cheung, A.F.P. and Lam, D.S.C., 2017. Formalin: a formaldehyde analogue. Can J Ophthalmol, 52(2): 229.

Immaculate, J. and Jamila, P. 2018. Quality characteristics including formaldehyde content in selected Sea foods of Tuticorn, southeast coast of India. International Food Research Journal, 25(1): 293-302.

Mamun, M.A.A., Rahman, M.A., Zaman, M.K., Ferdousi, Z., and Reza, M.A., 2014. Toxicological effect of formalin as food preservativeon kidney and liver tissues in mice model. Journal of Environmental Science, Toxicology and Food Technology, 8(9): 47-51.

Jain, S.R., Nahar, P.S., and Baig, M.M., 2012. Study of Formalin Toxicity in MBBS Students. International Journal of Science and Research, 1(3): 233-235.

Soumya and Singh, S., 2014. Fiber Optic Communication in Computer Networking and Security. Interntional Journal of Electrical, Electronics and Data Communication, 2(3): 62-64.

Hida, N., Bidin, N., Abdullah, M., and Yasin, M., 2013. Fiber optic displacement sensor for honey purity detection in distilled water. Optoelectronics and Advances Material. 7(7-8): 565-568.

Budiyanto, M., Suharningsih, and Yasin, M., 2017. Potensi Sensor Serat Optik Deteksi Konsentrasi Kolesterol sebagai Media Pembelajaran Gelombang dan Optik. Jurnal Penelitian Pendidikan IPA, 2(1): 1-5.

Aljaber, N.A., Mhdi, B.R., Ahmmad, S.K., Hamode, J.F., Azzawi, M.H., Kalad, A.H., and Ali, S.M., 2014. Design and Construction Fiber Sensor Detection System for Water Nitrite Pollution. IOSR Journal of Engineering, 4(2): 37-43.

Varghese, P.B., John, S., and Madhusoodanan, K.N., 2010. Fiber Optic Sensor for the Measurement of Concentration of Silica in Water with Dual Wavelength Probing. Review of Scientific Instrument, 81: 1-5.

Thévenaz, L. Next Generation of Optical Fibre Sensors: New Concepts and Perspectives. In Proceedings of the 23rd International Conference on Optical Fibre Sensors (SPIE 9157), Santander, Spain, 2–6 June 2014; p. 9157AN.

Burgess, L.W. 1995. Absorption-based sensors. Sens. Actuators B Chem., 29: 10–15.

Quintero, S.M.M., Valente, L.C.G., Gomes, M.S.D.P., Silva, H.G.D., Souza, B.C.D., Morikawa, S.R.K. 2018. All-fiber CO2 sensor using hollow core PCF operating in the 2 µm region. Sensors, 18(12): 4393.

Fabian, M., Lewis, E., Newe, T., & Lochmann, S. (2009). Fibre-Optic Evanescent-Wave Field Fluid Concentration Sensor. In 6th International Multi-COnference on Systems, Signals and Devices.

Sharifpour-boushehri, S., Hosseini-golgoo, S. M., & Sheikhi, M. (2015). A low cost and reliable fiber optic ethanol sensor based on nano-sized. Optical Fiber Technology, 24, 93–99. http://doi.org/10.1016/j.yofte.2015.05.002