Land subsidence estimation using DinSAR method ALOS PALSAR image in Padang City West Sumatra, Indonesia

Rahmi Sukmawati - Department of Physics, Universitas Negeri Padang, West Sumatra, Indonesia. LUMIR, Gyunggi, Republic of Korea.
Mirza Waqar - LUMIR, Gyunggi, Republic of Korea
- Syafriani - Department of Physics, Universitas Negeri Padang, West Sumatra, Indonesia
- Yohandri - Department of Physics, Universitas Negeri Padang, West Sumatra, Indonesia
Joshapat Sumantyo - JMRSL, Center for Environmental Remote Sensing (CEReS), Chiba University, Chiba, Japan

Abstract


Land subsidence is a phenomenon that occurs in big cities around the world and in Indonesia. Padang as one of the largest cities in West Sumatera also facing land subsidence due to natural phenomena and human induced. Padang City is located at the west coast of Sumatera Island which is the junction point of three active plates that cause frequent earthquakes. Main goals of this research are to know the distribution of area affected by land subsidence, to know the estimated value of land subsidence and to know the value of the velocity of land subsidence in Padang area using DInSAR method. The data used in this study is ALOS PALSAR Image Level 1.1 of Padang city during 2007 to 2010 was obtained through JMRSL CERES Chiba University, Japan and collected through Alaska Satellite Facility website. Differential Interferometric Synthetic Aperture Radar (DInSAR) is a technique considered to be one of the most efficient technique for detecting land subsidence. The DInSAR method is used in mapping altitude changes developed into a land-subsidence map each year. The mapping results show the distribution of the areas affected by the maximum land subsidence in Padang area of West Sumatera are Padang Utara, Nanggalo, and Padang Barat Subdistricts. The land subsidence insignificant occurred is Padang Selatan and Lubuk Begalung Subdistricts. The estimated value of the land subsidence distribution in Padang area using DInSAR method has decreased significantly after the earthquake of September 30, 2009 in Padang Utara, Nanggalo and West Padang Subdistricts is around 0 - 32.70 cm, and the value of land subsidence velocity is around 0.13 - 12 cm/year. One of the expected effects of land subsidence can be increased in the area susceptible for flooding in Padang city.

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References


H.Z. Abidin, , H. Andreas, M. Gamal, and D. Darmawan, “Land Subsidence Characteristic of Bandung Basin (Indonesia) Between 2000 and 2005 as Estimated from GPS Survey”, XXIII FIG Congress, Munich, p.1-14, 2006.

H.Z. Abidin, R. Djaja, D. Darmawan, S. Hadi, A. Akbar, H. Rajiyowiryono, C. Subarya, “Land Subsidence of Jakarta (Indonesia) and its Geodetic Monitoring System, Natural Hazards 23”, pp. 365–387, 2001.

T. O. Akbar. 2015. “Analisis Dampak Penurunan Muka Tanah Terhadap Tingkat Ekonomi Menggunakan Kombinasi Metode Dinsar Dan Sig (Studi Kasus: Kota Semarang)”. Jurnal Geodesi UNDIP.

Bappeda (Badan Perencanaan Pembangunan Daerah). 2012. Lampiran Peraturan Daerah Kota Padang Nomor 6 Tahun 2014 Tentang Rencana Pembangunan Jangka Menengah Daerah Tahun 2014-2019: Padang.

Bappeda (Badan Perencanaan Pembangunan Daerah). 2009. Geographical Location and Regional Administration of Padang: Padang.

L. Bayuaji, J.T. S. Sumantyo, and H. Kuze, “ALOS PALSAR D-InSAR for Land Subsidence Mapping in Jakarta, Indonesia,” Can. J. Remote Sensing, vol. 36, no.1, pp. 1-8, 2010.

C. P. Chang, C. T. Wang, T. Y. Chang, K. S. Chen, L. S. Liang, E. Pathier, “Application of SAR Interferometry to a large thrust deformation: the 1999 Mw=7.6 Chichi earthquake in Central Taiwan,” Geophysical Journal International,159, 9-16, 2005.

R. S. Chatterje, F. Benedicte. “Subsidence of Kolkata (Calcutta) City, India during the 1990s as Observed from Space by Differential Synthetic Aperture Radar Interferometry (D-InSAR) Technique,” Remote Sensing of Environment 102:176-185, 2006.

T. Deguchi, Y. Maruyama, M. Kato, and C. Kobayashi, Surface Displacement Around Mud Volcano, East Java Captured by InSAR Using Palsar Data. Earth Remote Sensing Data Analysist Centre (ERSDAC), Tokyo, 1-6, 2008.

ESA, InSAR Principles, Guidelines for SAR Interferometry Processing, and Interpretation (TM-19, February 2007). Frascati, Italy, 2007.

A. Fauzi, K. Sutarman, H. Hamdi, Penyelidikan Karakteristik Batuan di Kota Padang Menggunakan Metode Geofisika dan Geomorfologi untuk Memetakan Daerah Rawan Bencana. Laporan Penelitian Hibah Kompetitif Sesuai Prioritas Nasional Batch 1, Bidang Mitigasi dan Managemen Bencana, 2009.

R. M. Goldstein and C.L. Werner,”Radar Interferogram Phase Filtering for Geophysical Applications.” Geophysical Research Letters, 25, 4035-4038, 1998.

I. Gumilar, H.Z. Abidin and L.M. Hutasoit, Pemetaan karakteristik Penurunan Muka Tanah Berdasarkan Metode Geodetik Serta Dampaknya Terhadap Perluasan Banjir di Cekungan Bandung. ITB: Bandung, 2012.

R. T. Hanson, L. Zhen, & C. Faunt, “Simulation of subsidence for the regional aquifer system in the Santa Clara Valley, California,” Proc., 7th International Symposium on Land Subsidence, Shanghai (CN), 2005.

T. L. Holzer, & D. L. Galloway, “Impacts of Land Subsidence caused by withdrawal of underground fluids in the United States”. Engineering Geology. 16,87-99, 2005.

C. S. Hou, J. C. Hu, L.C. Shen, J. S. Wang, C. L. Chen, T. C. Lai, C. Huang, Y. R. Yang , R. F. Chen, Y. G. Chen, J. Angelier, “Estimation of subsidence using GPS measurements, and related hazard: the Pingtung Plain, southwestern Taiwan,” Comptes Rendus Geosci 337(13):1184–1193, 2005.

W. C. Hung, and C. S. Liu, Taiwan land subsidence monitoring and surveying analysis. Report of Industrial Technology Research Institute (ITRI), Hsinchu 335 pp. (in Chinese), 2007.

(2015) Geografis Kota Padang [Online].

Available: (https://padangkota.bps.go.id/statictable/2015/04/26/2/letak-geografis-kota-padang.html)

R. Marfai, “GIS Modelling of River and Tidal Flood Hazards in A Waterfront City (Case Study: Semarang City, Central Java, Indonesia),” ITC, The Netherlands, p.1-123, 2003.

P. W. Noppadol, P. H. Giao, P. Nutalaya, Land subsidence in Bangkok, Thailand. Engineering Geology, 82, 187−201, 2006.

Y. Potter. ( 2009) Faktor-Faktor Penyebab Penurunan Muka Tanah (Land Subsidence). [Online]. Available: https://yudopotter.wordpress.com/2009/05/06/faktor-faktor-penyebab-penurunan-muka-tanah-land-subsidence/

Y. Prasetyo, dan A. Janisa, Penerapan Teknik Differential Interferometric Synthetic Aperture Radar (DInSAR) Untuk Kajian Pemantauan dan Pengukuran Penurunan Muka Tanah (Studi Kasus: Lembang Bandung). Forum Ilmiah Ikatan Surveyor Indonesia, Pekanbaru 10-11 November 2010.

E. A. Saputro, Deteksi Penurunan Muka Tanah Kota Semarang Dengan Teknik Differential Interferometric Aperture Radar (DInSAR) Menggunakan Software ROI_PAC Berbasis Open Source. Teknik Geodesi FT Universitas Diponegoro, 2012.

C. Sato, M. Haga, & J. Nishino, “Land subsidence and groundwater management in Tokyo”. International Review for Environmental Strategies, 6(2), 403−424, 2006.

S. Stramondo , C. Bignami, M. Chini, N. Pierdicca, A. Tertulliani, “Satellite radar and optical remote sensing for earthquake damage detection: results from different case studies,” International Journal of Remote Sensing. 27(20): 4433–4447, 2006.

D. Raucoules, C. Colesanti, C. Carnec, “Use of SAR interferometry for detecting and assessing ground subsidence,” Comptes Rendus Geosciences, 339, 2007, pp. 289-302.

M. Syafiudin, Fifik and R.S. Chatterjee, “Potensi Pemanfaatan Teknologi Diferential Interferometric Syinthetic Aperture Radar (D-INSAR) Berbasis Satelit Untuk Pemanfaatan Penurunan Muka Tanah di Cekungan Bandung” Jurnal Ilmiah Geomatika Vol. 15 No. 1, Agustus 2009.

D. M. Tralli, R. G. Blom, V. Zlotnicki, A. Donnellan & D. L. Evans, “Satellite remote sensing of earthquake, volcano, flood, landslide, and coastal inundation hazards” ISPRS Journal of Photogrammetry and Remote Sensing. 59(4), 185-198, 2005.




DOI: http://dx.doi.org/10.24036/10673171074