Design and experiment of ocean current power generation system have been carried out using the Bach In Indonesia, the tsunami early warning system only applies the earthquake and hydrosphere relationship model to predict tsunamis. To date, no tsunami detector has used radar or GNSS technology. GNSS technology can be applied as an early warning system for tsunamis, provided that tsunamis are caused by earthquakes greater than 7 magnitudes, occur 70 kilometers below sea level, and are caused by normal faults. This could be an alternative to Bouy GNSS which is expensive to install and maintain, especially for countries with vast oceans such as Indonesia. In this paper, a review of the application of GNSS signal reflection was carried out using one International GNSS Service (IGS) station, JOG2, and one Continuously Operating Reference Station (CORS), CLSA, each located in Java and Sumatra to investigate the availability of sea level monitoring in Indonesia. Determination of sea level is obtained from two methods, the GNSS signal phase data analysis method and the GNSS Signal-to-Noise Ratio (SNR) data analysis method. Both methods use reflected GNSS signals or multipath effects to obtain sea level. The results of the study show that the number of satellites that pass through Indonesia every 15 minutes is enough to get sea-level data  every 15 minutes to one hour. This shows that it is possible to apply the multipath effect to obtain sea level information in Indonesia to detect tides and tsunamis as part of the tsunami early warning system in Indonesia.

Vennell, S.W., Funke, S., Draper, C., Stevens, & Divett, T. (2015). Designing large arrays of tidal turbines: a synthesis and review. Renewable and Sustainable Energy Reviews, 41 (5),454-472.

Kamoji, M. Kedare, S, Prabhu, S. (2009). Performance Test on Helical Savonius Rotors. Renewable Energy, 34(3), 521-529.

Gorlov, A. M. (1998). Helical turbines fot the Gulf Stream: Conceptual approach design of a large- scale floating power farm.Marine Technology, 35(1), 175-177.

Mauller, G. & Kauppert, K. (2004). Performance characteristic of water wheels. Journal of Hydraulic Research, 42 (5), 1-6

Akimoto, H., Tanaka, K.., & Uzawa J (2013). A conceptual study of floating axis water current turbine for low-cost energy capturing from river, tide and ocean current Renewable Energy 57(1), 283-288.

Hassanzadeh, R., Yaakob, U., Gholami, A., Pourmahdavi, M, Hoissenzadeh, M., Taheri M. M. & Ahmed, Y. (2018). Experimental investigation of an innovative configuration for new marine current turbine.Renewable Energy, 18 (1), 92-93

Khan, M. J., Iqbal, M. T. & Quiacoe, J. E. (2008). River current energy conversion system: Progress, prospects and challenges Renewable Sustain Energy Reviews,8(3), 2177-2179

Bhayo, B. & Kayiem. (2017). Experimental Characterization and Comparison of Performance of S-Rotor for Standalone Wind Power System. Journal of Energy. 138 (2), 752-763.

Wu, H. N., Chen, L. J., Ming, H. Y., Li, W. Y. & Chen, B. F., (2012). On design and performance prediction of the horizontal-axis water turbine. Ocean Engineering, 50(1), 23-30.