The Cisangkuy sub-watershed is part of the Citarum watershed with ±300 km of river length. The total area is in line with the potential of water resources which is quite good, but over time the hydrological condition of the site has decreased. Decreasing the hydrological state is due to changes in land use and land cover from year to year and is indicated by high discharge and flooding in the rainy season. This study aims to find the optimal location of artificial recharge to maintain water balance in the Cisangkuy sub-watershed. Fuzzy logic is used for determining the location of artificial recharge by considering the input variable DRASTIC in the form of depth to groundwater level, net recharge, aquifer media, soil type, slope, vadose zone, and hydraulic conductivity. In addition, subtractive clustering is performed to obtain the class of each DRASTIC parameter. Furthermore, a genetic algorithm is carried out to get the optimal location of the artificial recharge zone. The priority zone is indicated by the high class of each DRASTIC parameter input. Combined fuzzy logic and genetic algorithm show that the optimal location for artificial recharge is in the northern part of the Cisangkuy sub-watershed, precisely in the Banjaran area.

Aller, L., Bennet, T., Lehr, J. H., Petty, R. J., Hackett G., 1987. DRASTIC: A standardized system for evaluating groundwater pollution potential using hydrogeologic settings, US Environ. Protection Agency EPA/600/2-85-018.

Alzwar, M., Akbar, N., Bachri, S., 1992. Peta Geologi Lembar Garut dan Pameungpeuk, Jawa. Pusat Penelitian dan Pengembangan Geologi, Bandung.

Azis, A., Prihandono, B., Ilhamsyah, 2016. Algoritma Genetika Pada Pemograman Linear dan Nonlinear. Buletin Ilmiah

Mat. Stat. dan Terapannya (Bimaster), 5, 265-274.

Baalousha, H, 2010. Assessment of a groundwater quality monitoring network using vulnerability mapping and geostatistics: A case study from Heretaunga Plains, New Zealand. Agriculture Water Management, 97, 240–246.

Banjarnahor, 2012. Aplikasi logika fuzzy dalam penentuan kepuasan pasien rawat inap (Studi Kasus RSU HERNA Medan). Tesis Program Magister, Universitas Sumatera Utara.

Barbulescu, A., 2020. Assessing groundwater vulnerability: DRASTIC and DRASTIC-like methods: A Review. Water. 12, 1–22.

Bonita, R., Mardyanto, M. A., 2015. Studi water balance air tanah di Kecamatan Kejayan, Kabupaten Pasuruan, Provinsi Jawa Timur. Jurnal Teknik ITS. 4, 21–26.

Fetter, C. W., 2000. Applied hydrogeology 4th edition. Prentice Hall. United States.

Fitts, C. R., 2013. Groundwater science, second edition, Academic Press, USA.

Ghazavi, R., Babaei, S., Erfanian, M., 2018. Recharge wells site selection for artificial groundwater recharge in an urban area using fuzzy logic technique. Water Resources Management. 32, 3821–3834.

Hadi, S., 2004. Penilaian kerentanan air tanah tak tertekan terhadap pencemaran di Daerah Bandung dan sekitarnya dengan metode DRASTIC. Buletin Geologi Tata Lingkungan. 14, 17–39.

Harefa, K., 2017. Penerapan fuzzy inference system untuk menentukan jumlah pembelian produk berdasarkan data persediaan dan penjualan. Jurnal Informatika Universitas Pamulang. 2, 205–213.

Hartanto, P., 2017. Perhitungan neraca air DAS Cidanau menggunakan metode thornthwaite. Jurnal RISET Geologi dan Pertambangan. 27, 213–225.

Haupt, R.L., Haupt S.E., 2004. Practical genetic algorithms, 2nd edn. John Wiley & Sons press, New Jersey

IWACO/WASECO, 1991. Peta Hidrogeologi Kabupaten Bandung Skala 1:100.000, Jawa Barat.

Kusumawardani, M., Hidayat, Y., Murtilaksono, K., 2018. Analisis respon hidrologi dan kualitas air DAS Cisangkuy. Jurnal Ilmu Tanah dan Lingkungan. 20, 49–56.

Lashari, Kusumawardani, R., Prakasa, F., 2017. Analisa distribusi curah hujan di Area Merapi menggunakan metode aritmatika dan poligon. Jurnal Teknik Sipil & Perencanaan. 19, 39–48.

Mahmudy, W.F., Marian, R.M., Luong, L.H.S., 2013. Real coded genetic algorithms for solving flexible job-shop scheduling problem – Part II: optimization. Advanced Materials Research. 701, 364-369.

Pane, S., Awangga, R., Rachmadani, E., Permana, S., 2019. Implementasi Algoritma Genetika Untuk Optimalisasi Pelayanan

Kependudukan. Jurnal Tekno Insentif, 13, 36-43.

Primajaya, A., Sari, B., 2018. Random forest algorithm for prediction of precipitation. Indonesian Journal of Artificial Intelligence and Data Mining, 1, 27–31.

Rahimi, S., Roodposhti, M., 2014. Using combined ahp–genetic algorithm in artificial groundwater recharge site selection of Gareh Bygone Plain, Iran. Environmental Earth Sciences. 72, 1979–1992.

Resubun, M., Wahjunie, E., Tarigan, S., 2019. Analisis Ketersediaan dan Kebutuhan Air di DAS Cisangkuy. Musamus AE

Featuring Journal, 2, 1-10.

Sampe, H., Juwana, I., Marganingrum, D., 2018. Kajian Perhitungan Beban Pencemaran Sungai Cisangkuy di Cekung

Bandung dari Sektor Pertanian. Jurnal Rekayasa Hijau, 2, 165-175.

Silitonga, P., 1973. Peta Geologi Lembar Bandung, Jawa. Pusat Penelitian dan Pengembangan Geologi, Bandung.

Sugianti, K., Mulyadi, D., Maria, R., 2016. Analisis kerentanan pencemaran air tanah dengan pendekatan metode DRASTIC di Bandung Selatan. Jurnal Lingkungan dan Bencana Geologi. 7, 19–33.

Wakhidah, N., 2012. Klasifikasi data multidimensi menggunakan substractive clustering dan k-nearest neightbor. Jurnal Transformatika. 10, 11–19.

Yang, W., Cao, W., Chung, T., Morris, J., 2005. Applied numerical methods using matlab®, John Wiley & Sons, Inc., Hoboken, New Jersey, Canada.