The phenomenon of global warming can lead to thermal exposure and variations in water masses that require melting glaciers, polar ice sheets and changes in global sea level averages. This effect has an important impact on socio-economic, infrastructure and environment, which causes land changes of around 10% of the world's population. Since the end of the 18th century, changes in the position of open air from tidal stations along the coastline. However, observation of tide stations has limitations in number, distribution, and coverage, as well as variations in land subsidence. Therefore, this study analyzes sea surface variations in the Java Sea and the South China Sea during the period 2002-2019 using altimetry satellite reference mission data, namely Jason 1, Jason 2, and Jason 3. Sea level variations that need to be studied increase sea air by 4.1 mm/year, where high speeds occur around the North or South Java Sea which has a value of 7-9 mm / year. So based on these results pre-event planning can be carried out on the impact of the upcoming sea level rise.

Ablain, M., Cazenave, A., Larnicol, G., dan Balmaseda, M. 2015. “Improved sea level record over the satellite altimetry era (1993–2010) from the Climate Change Initiative project”. Ocean Science, 67-82.Revit, 2018.

Andersen, O. B., dan Scharroo, R. 2011. "Range and geophysical corrections in coastal regions: And implications for mean sea surface

determination". Dalam S. Vignudelli, A. G. Kostianoy, P. Cipollini, dan J. Benveniste, Coastal Altimetry (hal. 103-145). Berlin: Springe.

Cazenave, A., Lombard, A., dan Llovel, W. 2008. "Present-day sea level rise: a synthesis". Computation Rendus Geosiences, 761-770.

Heywood, D.I., Cornelius, S.C. & Carver, S.J. 2011. An Introduction to Geographical Information Systems. Fourth edn. London: Pearson Prentice Hall.

Cheng, Xuhua and Yiquan Qi. 2007. “Trends of Sea Level Variations in the South China Sea from Merged Altimetry Data”. Global and Planetary Change 57(3–4):371–82.

Church, J. A., and N. J. White. "Sea-level rise from the late 19th to the early 21st century." Surv. Geophys, 2011: 585-602.Moussa, W. 2014. Integration of Digital Photogrammetry and Terrestrial Laser Scanning for Cultural Heritage Data Recording. PhD Thesis Proposal. German: University of Stuttgart.

Dahuri, R., J. Rais, S. P. Ginting, and M. J. Sitepu. Pengelolaan SUmber Daya Pesisir dan Lautan secara Terpadu. Jakarta: Balai Pustaka, 2008.Trieb, P. B. & Kilpatrick, D. 2004. Digital Close-range Stereophotogrammetry for Heritage Recording. RCI Incorporation.

Handoko, E. Y., Fernandes, M. J., & Lazaro, C. 2017. "Assessment of Altimetric Range and Geophysical Corrections and Mean Sea Surface Models-Impacts on Sea Level

Variability around Indonesia Seas". Remote Sens, 102.