The need for information on potential fishing zones based on remote sensing satellite data (ZPPI) in coastal waters is increasing. This study aims to create an information model of such zones in coastal waters (coastal ZPPI). The image data used include GHRSST, SNPP-VIIRS and MODIS-Aqua images acquired from September 1^st-30^th, 2018 and September 1^st-30^th, 2019, together with other supporting data. The coastal ZPPI information is based on the results of thermal front SST detection and overlaying this with chlorophyll-a. The method of determining the thermal front sea surface temperature (SST) used Single Image Edge Detection (SIED). The chlorophyll-a range used was in the mesotropic area (0.2-0.5 mg/m³). Coastal ZPPI coordinates were determined using the polygon centre of mass, while the coastal ZPPI information generated was only for coastal areas with a radius of between 4-12 nautical miles and was divided into two criteria, namely High Potential (HP) and Low Potential (LP). The results show that the coastal ZPPI models were suitable to determine fishing locations around Nias Island. The percentage of coastal ZPPI information generated was around 90% information monthly. In September 2018, 27 days of information were produced, consisting of 11 HP sets of coastal ZPPI information and 16 sets of LP information, while in September 2019 it was possible to produce 29 days of such information, comprising 11 sets of HP coastal ZPPI information and 18 LP sets. The use of SST parameters of GHRSST images and the addition of chlorophyll-a parameters to MODIS-Aqua images are very effective and efficient ways of supporting the provision of coastal ZPPI information in the waters of Nias Island and its surroundings.

Potential Fishing Zones, Coastal ZPPI, GHRSST, Single Image Edge Detection (SIED), Nias Island

Angraeni, Rezkyanti, N.I., Safruddin, & Zainuddin, M. (2014). Spatial and Temporal Analysis of Skipjack Tuna (Katsuwonus pelamis) Catch and Thermal Front during the Transition Season in the Bone Bay. Jurnal IPTEKS PSP, 1(1), 20 – 27.

Balaguru, B., Ramakrishnan, S.S., Vidhya, R., & Thanabalan, P. (2014). A Comparative Study on Utilization Of Multi-Sensor Satellite Data To Detect Potential Fishing Zone (PFZ). The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, XL-8, 2014. ISPRS Technical Commission VIII Symposium, 09 - 12 December 2014, Hyderabad, India.

Departemen Kelautan dan Perikanan. (2008). Implementation Guidelines for Fisheries Port Management, Jakarta.

Hamzah, R., Prayogo, T., & Marpaung, S. (2016). Method Of Determination Points Coordinate for Potential Fishing Zone Based on Detection of Thermal Front Sea Surface Temperature. Jurnal Penginderaan Jauh, 13(2), 97–108.

Hasyim, B. (2015). Indonesian Institute of Aviation and Space Develop the Potential Fishing Zones. https://berita2bahasa.com/berita/1/15591610-lapan-kembangkan-zppi-bantu-nelayan-identifikasi-zona-ikan. Accessed 20 Jan 2020.

Hanintyo, R., Hadianti, S., Mahardhika, R.M.P., Aldino, & Islamy, F. (2015). Seasonal Distribution of Thermal Front Events Based on Aqua-MODIS Imagery in WPP-RI 714, 715, WPP-RI 716. Prosiding Seminar Nasional Penginderaan Jauh Nasional 2015.

Lasabuda, R. (2013). Regional Development in Coastal and Ocean in Archipelago Perspective of The Republic of Indonesia. Jurnal Ilmiah Platax, I-2, 92-101.

Marpaung, S., Prayogo, T., Parwati, E., Setiawan, K.T & Roswintiarti, O. (2018). Study On Potential Fishing Zones (PFZ) Information Based On S-Npp Viirs And Himawari-8 Satellites Data. International Journal of Remote Sensing and EarthSciences, 15(1), 51–62.

Nurdin, S., Mustapha, M., Lihan, T., & Zainuddin, M. (2017). Applicability of remote sensing oceanographic data in the detection of potential fishing grounds of Rastrelliger kanagurta in the archipelagic waters of Spermonde, Indonesia. Fisheries Research, 196, 1-12.

Paena, M., Suhaimi, R.A., & Undu, M.C. (2015). Analysis of Dissolved Oxygen Concentration (DO), pH, Salinity and Temperature in the rainy season on the decline in water quality in the Punduh Waters Pesawaran Regency Lampung Province. Seminar Nasional Kelautan X â€Sinergitas Teknologi dan Sumber Daya Kelautan untuk Mewujudkan Indonesia sebagai Poros Maritim Dunia†Fakultas Teknik dan Ilmu Kelautan Universitas Hang Tuah, Surabaya 21 Mei 2015.

Pauly, D., & Christensen, V. (1993). Stratified Models of Large Marine Ecosystem: A General Approach and an Application to the South China Sea. In: K. Sherman, L.M Alexander and B.D Gold (Eds.), Large Marine Ecosystems: Stress, mitigation and Sustainability. Washington, D.C: AAAS Press:3-14.

Purwanto, A.D & Harsanugraha, W.K. (2012). Analysis of Sea Surface Temperature (SST) in the Western Java Sea Based on NOAA-AVHRR and MODIS Data. Prosiding PIT MAPIN XIX. Makassar.

Purwanto, A.D., Prayogo, T., & Marpaung, S. (2020). Identification of Coral Reef Using Sentinel 2A Satellite Imagery (Case Study: Coastal Waters of Northern Nias). Jurnal Teknologi Lingkungan, 21(1), , 095-108.

Retnowati, E. (2011). Indonesian fishermen in the vortex of structural poverty (social, economic and legal perspectives)Jurnal Perspektif, XVI(3), 149-159.

Simbolon, D. & Girsang, H.S. (2009). Relationship between chlorophyl-a concentration and frigate mackerel catches in fishing ground of Pelabuhanratu waters. Jurnal Penelitian Perikanan Indonesia, 15(4), 297-305.

Simbolon, D., Silvia, S & Wahyuningrum, P.I. (2013). The Prediction of Thermal Front and Upwelling as Indicator of Potential Fishing Grounds in Mentawai Water. Marine Fisheries, 4(1), 85-95.

Suwargana, N., & Ariel, M., (2004). Determination of Sea Surface Temperature and Chlorophyll Concentration for Developing of Predictional / Fishing Ground Models using MODIS Data. Jurnal Penginderaan Jauh dan Pengolahan Data Citra Digital, 1(1), 1-13.

Telaumbanua, S.B. (2009). A Study of Capture Fisheries Development in Nias Regency. Tesis. Sekolah Pascasarjana Institut Pertanian Bogor: Bogor.

Winardi, & Manuputy, A.E.W. (2007). Nias Ecology Baseline. Jakarta: COREMAP II–LIPI.

Zainuddin, M., Kiyofuji, H., Saitoh, K., & Saitoh, S. (2006). Using multi-sensor satellite remote sensing and catch data to detect ocean hot spots for albacore (Thunnus alalunga) in the northwestern North Pacific. Deep-Sea Research II 53(3-4) 419–431.

Zainuddin, M. (2011). Skipjack Tuna In Relation To Sea Surface Temperature And Chlorophyll-A Concentration Of Bone Bay Using Remotely Sensed Satellite Data. Jurnal Ilmu dan Teknologi Kelautan Tropis, 3(1), 82-90.

Zebua, N.D. & Ramli. (2014). Analyze the effect of the number of fleets, the number of fisherman, GDP, and investment to the production of fisheries in the region of Nias (Panel Data Analysis).. Jurnal Ekonomi dan Keuangan, 2(8), 463-474.