Analysis of Dirty Adapters and Dirty Connectors on Fiber Optic Transmission
DOI:
https://doi.org/10.62671/jataed.v2i1.58Keywords:
Passive Splitter 1:16 , Dirty Adapter, Dirty Connector, Fiber Optic, AttenuationAbstract
The author conducts research on dirty adapters and dirty connectors in fiber optic transmission to determine the value or attenuation that will be produced due to the influence of dirty adapters and dirty connectors. This study was conducted to evaluate the attenuation value due to dirty adapters and dirty connectors in fiber optic transmission before and after the use of Passive Splitter 1: 16. The method used includes the initial step of calibration between the Optical Power Meter (OPM) and Handheld Light Source (HLS). The HLS was connected to the first Optical Distribution Point (ODP) with a patch cord cable to provide attenuation, and data was taken at the second ODP using the OPM. The power data received on the unproblematic core (gray) without the 1:16 Passive Splitter was 0.65 dB, while with the 1:16 Passive Splitter the attenuation increased to 13.71 dB. The red dirty adapter causes 5.99 dB of attenuation without the Passive Splitter 1:16 and 19.21 dB with the Passive Splitter 1:16. The brown dirty connector exhibits an attenuation of 4.68 dB without the Passive Splitter 1:16 and 19.08 dB with the Passive Splitter 1:16. These findings suggest that the physical condition and cleanliness of the components significantly impact the attenuation in the fiber optic network.
References
Ardina, E. N., Dr. Supari, & Cahyono, T. D. (2023). Implementasi Fiber Optik di Ranah Industri dan Penyambungan Fiber Optik Menggunakan Splicer di SMK Telkom Tunas Harapan. Abdimas, 2(2), 9–15. Retrieved from http://www.itbsemarang.ac.id/sijies/index.php/abdimas
Asril, A. A., Septima, U., Dewi, R., Maria, P., & Herda, D. L. (2023). Fiber Optical Network Damage Detection Passive Splitter 1:8 in ODC uses IOT Technology as a means of Real Time Reporting. Brilliance: Research of Artificial Intelligence, 3(2), 122–133. https://doi.org/10.47709/brilliance.v3i2.2966
Chen, L., Su, Q., Liu, S., & Li, L. (2021). Infiltrated hollow core fiber interferometer for high sensitive temperature and refractive index sensing. Optik, 243. https://doi.org/10.1016/j.ijleo.2021.167336
Daniel, S., Prasetyo, J., & Widodo, S. (2021a). Rancang Bangun Alat Trainer Jaringan Kabel Serat Optik Untuk Kompetensi Teknisi Instalasi Fiber Optik Dan Praktikum Fiber Optik. Integrated Lab Journal, 09(02), 63–79.
Daniel, S., Prasetyo, J., & Widodo, S. (2021b). Rancang Bangun Alat Trainer Jaringan Kabel Serat Optik Untuk Kompetensi Teknisi Instalasi Fiber Optik Dan Praktikum Fiber Optik. Integrated Lab Journal, 09(02).
Datta, A., & Saha, A. (2020). Realization of a highly sensitive multimode interference effect-based fiber-optic temperature sensor by radiating with a Vortex beam. Optik, 218. https://doi.org/10.1016/j.ijleo.2020.165006
Han, Y., Gong, L., Meng, F., Chen, H., Wang, Y., Li, Z., … Wang, W. (2021). Highly sensitive temperature sensor based on surface plasmon resonance in a liquid-filled hollow-core negative-curvature fiber. Optik, 241. https://doi.org/10.1016/j.ijleo.2021.166970
Juwari, J., Jayadi, P., & Sussolaikah, K. (2022). Analisis Redaman Kabel Fiber Optic Patchcord Single Core. JURIKOM (Jurnal Riset Komputer), 9(2), 202. https://doi.org/10.30865/jurikom.v9i2.3950
Liu, M., & Fu, W. (2020). Multi-core fiber based coherent transceiver utilizing self-homodyne detection and ICA based channel equalization for optical intra-datacenter interconnects. Optik, 205. https://doi.org/10.1016/j.ijleo.2020.164215
Liu, Y., & Song, H. (2021). Theoretical analysis on polarization characteristics of spun birefringent optical fiber based on an analytical Jones matrix model. Optik, 228. https://doi.org/10.1016/j.ijleo.2020.166179
Mardhatillah, K., Asril, A. A., Yustini, & Yulindon. (2022). Analisa Rugi-Rugi Sambungan Kabel Drop Core Terhadap Performansi Jaringan Optik Di Gedung G Lantai 3 Politeknik Negeri Padang. Jurnal Fokus Elektroda, 7(3), 172–177.
Maria, P., Adila Asril, A., Wiharti, W., & Prayama, D. (2022). Fiber to The Home (FTTH) Network Design in Analyzing Macro Bending Problems in The Home Cable Installation Segment. International Journal of Advanced Science Computing and Engineering (Vol. 4).
Nugroho A K, H. R., Wahyu, N. K., Kota Malang Jl Tlogowaru No, P., & Malang, K. (2019). Analisis Redaman Pada Sistem Fiber Optic Akibat Adanya Penambahan ST-Adapter The Analysis Of Attenuation In Fiber Optic System Due To Embedded ST-Adapter.
Rahmania. (2019). Analisis Power Budget Jaringan Komunikasi Serat Optik Di PT.Telkom Akses Makassar. Vertex Elektro, 01(02), 52.
Rahmatulloh, M. A., Hanto, D., Yantidewi, M., Rianaris, A., & Firdaus, R. A. (2023). Analisis Redaman Fiber Optik dengan Menggunakan Pemodelan Software Optisystem. Jurnal Kolaboratif Sains, 6(7), 630–639. Retrieved from https://jurnal.unismuhpalu.ac.id/index.php/JKS
Tian, P., Bi, W., Wang, X., Jin, W., Zhang, B., Fu, X., & Fu, G. (2021). Dual-core mode converter with long period fiber grating. Optik, 231. https://doi.org/10.1016/j.ijleo.2021.166461
Wu, Y., Liu, B., Nan, T., Wu, J., Mao, Y., Ren, J., … Zhang, Y. (2021). Fiber optic hybrid structure based on an air bubble and thin taper for measurement of refractive index, temperature, and transverse load. Optik, 241. https://doi.org/10.1016/j.ijleo.2021.166962
Yuseliani, R. D., Asril, A. A., Maria, P., & Yulindon. (2022). Penambahan Optical Distribution Point (ODP) Menggunakan Metode Branching Dalam Perancangan Jaringan Fiber To The Home (FTTH) Di Gedung G Lantai 3 Politeknik Negeri Padang. Jurnal Ilmiah Poli Rekayasa, 17(2), 58–63.
Zhu, F., Zhang, Y., Qu, Y., Su, H., Zhao, L., & Guo, Y. (2020). Fiber-optic hybrid structure sensor for simultaneous measurement of transverse load and temperature. Optik, 208. https://doi.org/10.1016/j.ijleo.2019.164078
Zukri, I. M., Yolanda, A., Yustini, & Yulindon. (2022). Analisis Pengaruh Penggunaan Passive Splitter Pada Optical Distribution Point (ODP) Terhadap Kinerja Jaringan Di Rumah Pelanggan. Jurnal Ilmiah Poli Rekayasa, 18(1), 32–37.
Downloads
Published
Issue
Section
License
Copyright (c) 2024 Muhammad Fachrel Farhan, Popy Maria, Amelia Yolanda, Aprinal Adila Asril
This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.