Power facilities that use solar radiation to generate electricity are known as solar power plants. As an alternative energy source, using the sun for energy demands has a lot of promise in today's world. The energy generated or released by a light source is the sun. As is well known, the sun provides a significant portion of the world's illumination energy. In this situation, solar energy may be used in conjunction with other machinery that contributes and has the ability to convert solar radiation into electrical energy through the use of solar panels, which are apparatuses that transform solar radiation into electrical energy. Apart from that, solar panels are the most promising and have the most potential when compared to other energy sources. It can be argued that solar panels are the primary factor in optimising the potential of solar energy reaching the earth. The weather affects solar panel performance. Solar panels must constantly be pointed in the direction of the sun's rays in order to work well, as the sun's location on the surface of the planet varies with time. From the explanation above, a plan was made for a solar power plant in Pinggir Laut Village, Rokan Hilir Regency complex using 60 units of 200 WP panels, 56 units of 12V 100 Ah batteries, 2 units of 8000W inverter, and 2 units of a charger controller with a voltage rating of 120 Ampere.

Keywords: Feasibility, PLTS, Planning, Photovoltaic, Power plants.

Keywords: Feasibility, PLTS, Planning, Photovoltaic, Power plants.

P. Xofis, P. Konstantinidis, I. Papadopoulos, and G. Tsiourlis, “Integrating remote sensing methods and fire simulation models to estimate fire hazard in a south-east mediterranean protected area,” Fire, vol. 3, no. 3, pp. 1–23, 2020.

R. M. Rodney et al., “Physical and Mental Health Effects of Bushfire and Smoke in the Australian Capital Territory 2019–20,” Front. Public Heal., vol. 9, no. October, pp. 1–13, 2021.

M. Papatsimouli, L. Lazaridis, D. Ziouzios, M. Dasygenis, and G. Fragulis, “Internet Of Things (IoT) awareness in Greece,” SHS Web Conf., vol. 139, p. 03013, 2022.

P. Borkar, P. U. Chanana, S. K. Atwal, T. G. Londe, and Y. D. Dalal, “The Replacement of HMI (Human-Machine Interface) in Industry Using Single Interface Through IoT,” 2021.

R. Fauzi Siregar, R. Syahputra, and M. Yusvin Mustar, “Human-Robot Interaction Based GUI,” J. Electr. Technol. UMY, vol. 1, no. 1, pp. 10–19, 2017.

B. Robert and E. B. Brown, “Short Message Services,” no. 1, pp. 1–14, 2004.

A. H. Bhattarai, G. Y. Sanjaya, A. Khadka, R. Kumar, and R. A. Ahmad, “The addition of mobile SMS effectively improves dengue prevention practices in community: an implementation study in Nepal,” BMC Health Serv. Res., vol. 19, 2019.

N. T. Trung, X.-H. Le, and T. M. Tuan, “Enhancing Contrast of Dark Satellite Images Based on Fuzzy Semi-Supervised Clustering and an Enhancement Operator,” Remote Sens., vol. 15, no. 6, 2023.

S. M. M. Abbasi and A. A. Jalali, “Fuzzy tracking control of fuzzy linear dynamical systems.,” ISA Trans., 2020.

S. Madhura, G. Deepthi, B. Chinnitaha, and D. Disha, “IoT Based Monitoring and Control System using Sensors,” June 2021, 2021.

Dr. Pavan Shukla, Utkarsh Srivastava, Sridhar Singh, and Rishabh Tripathi, Rakesh Raushan Sharma, “Automatic Engine Locking System Through Alcohol Detection,” Int. J. Eng. Res., vol. V9, no. 05, pp. 637–640, 2020.

P. Technical, “KY-026 Flame-sensor module,” pp. 118–124, 2017.

Hanwei Electronics, “Technical Mq-2 Gas Sensor,” Smoke Sens., vol. 1, no. 1, pp. 3–5, 2006.

N. Evalina, D. Sholeha, and F. I. Pasaribu, “Power Measurement System Prototype Design Used in Household Loads with The Arduino,” vol. 1, no. 2, pp. 56–60, 2022.

M. A. Mazidi, S. Naimi, and S. Naimi, “AVR Microcontroller and Embedded Systems The.” p. 118, 2011.

Rohana and Suwarno, “Optimization circuit based buck-boost converter for charging the solar power plant,” Indones. J. Electr. Eng. Comput. Sci., vol. 6, no. 2, pp. 254–258, 2017.

GSM SIM900A MODEM, “Gprs /Gsm Sim900a Modem User Manual,” Res. Policy.