Journal of Railway Transportation and Technology Vol. 2 No. p-ISSN: 2830-0491e-ISSN: 2830-6680 https://doi. org/10. 37367/jrtt. Realtime and Centralized Solar Panel Online Monitoring System Design Using Thingspeak Santi Triwijaya1. Dara Aulia Feriando1. Ronald Feriza1. Yahya Don2 Manajemen Transportasi Perkeretaapian. Politeknik Perkeretaapian Indonesia Madiun. Jl. Tirta Raya Pojok. Nambangan Lor. Manguharjo. Kota Madiun, 63129. INDONESIA School of Education and Modern Languages. Universiti Utara Malaysia. Malaysia Arumugam Raman. School of Education and Modern Languages. UUM, 06010 Sintok. Kedah. Malaysia Article Info ABSTRACT Article history: Indonesia is a country with a tropical climate and has a high intensity of solar irradiation. Seeing this situation. Indonesia is the right region to implement the installation of new and renewable energy such as PLTS. In the use of solar panels, the magnitude of the output power is determined by several environmental conditions, such as the intensity of sunlight, temperature, and the direction in which sunlight comes. prevent damage and deterioration in the performance of solar panels, research is needed for a more accurate and efficient use of renewable The study was a solar panel system with a Wemos D1 microcontroller that monitored online using Thing speak with the help of INA 219 and LDR sensors. Online monitoring system by recording data on current, voltage, and light intensity in real time and centralized. The system will store and record measurement data every 15 seconds in the form of JSON. XML. CSV file extensions. Error on the voltage sensor of 1. 7% for and 3. 2% for the current sensor. average panel voltage value of 12. 77 V, average panel current value of 0. 43 A and 2410 lux for light intensity at interval testing from 07:00 a. 16:00p. Received 7 February, 2023 Revised 28 March, 2023 Accepted 29 March, 2023 Keywords: Solar panels. Thingspeak. IoT. INA 219 sensor *Corresponding Author: Santi Triwijaya Department of Railway Electrical Technology. Indonesian Railway Polytechnic Jl. Tirta Raya. Pojok. Nambangan Lor. Manguharjo. Madiun. Jawa Timur 63161. Indonesia Email: santi@ppi. INTRODUCTION Indonesia is a country with a tropical climate and has a high intensity of sunlight. This is because Indonesia's position is on the equator so that the territory of Indonesia gets good sunlight. Seeing this situation. Indonesia is the right area to implement the installation of new renewable energy such as Solar Power Plants. Ae. Monitoring has the aim of obtaining feedback on the needs of the program being implemented, by knowing to need, the implementation of the program will be prepared as well as possible. The output power generated by a solar power plant can be affected by the shading on the solar panels. Ae. Research conducted by Murshiduzzaman which was published in 2021 discusses the effect of shading due to the density level of dust that sticks to or is in the environment where solar panels are placed. This study calculates the dust on solar Santi Triwijaya et al. Journal of Railway Transportation and Technology. Vol. 2 No. panels by online monitoring. Furthermore, the accumulation and look for the effectiveness of solar panels. this study it is known that dust greatly affects the output results in the form of power generated by solar panels. It also depends on the results of monitoring at the time, location and geographic conditions of observation . Ae . Monitoring the energy produced by the sun has been carried out in various mechanisms. Digital video watermarking mechanism is one of the mechanisms that can be used in monitoring solar panels. With video watermarking techniques. GPS coordinates, date, time and temperature can be monitored in real time . Ae. Another mechanism for monitoring can also be done by using a Wireless Sensor Network (WSN). With WSN, monitoring can be done effectively and efficiently. However, this also depends on the quality of the WSN sensor used . Ae. The monitoring process carried out on solar panels is carried out to see incoming data in real time, find out the amount of average daily consumption of energy produced, and the amount of loading capacity, so that electricity supply is guaranteed . In addition. Mallor in 2017 also explained that monitoring on solar panels has benefits as a study in the development of solar panels in the future . From several facts and the need for the development of previous research, research is needed for the use of renewable energy . that is more accurate and efficient. This research is a solar panel system with the Wemos D1 microcontroller that monitors online using Thingspeak. Online monitoring system by recording current, voltage and light intensity data in real time and centrally. Ae. The system will store and record measurement data every 15 seconds in the form of JSON. XML. CSV file extensions. Therefore, it is necessary to conduct research on Designing a Realtime and Centralized Solar Panel Online Monitoring System Using Thingspeak. RESEARCH METHOD The implementation of this research is an effort to get results that are in accordance with the objectives of the tool made. To get the expected research results, carried out step by step in going through it. Start Concept design make a solar panel monitoring tool with thinkspeak does it function as Yes collect data and End Figure 1. Research Flowchart Santi Triwijaya et al. Journal of Railway Transportation and Technology. Vol. 2 No. Figure 1 is a flowchart of the research method used as a reference for the stages of the research process. The concept in designing the monitoring tool that will be made is carried out starting from collecting data to look for theories and data related to the research that will be carried out. Next, the design of a solar panel monitoring tool is carried out using thinkspeak. In this design includes circuit hardware design, software design . , and tool mechanical design. Then do the integration between hardware and software. The function of the equipment that has been made is tested to find out whether it is functioning as expected. Testing is divided into three categories of testing, namely hardware testing on each system set, software testing on each system set, and overall tool system testing. If the results of the tests that have been carried out are in accordance with the expected results, then the test is declared to have been completed. However, if the tests carried out are not in accordance with the expected results, then a re-check will be carried out in the design. Hardware design The block diagram in Figure 2 above is a block of the process of designing solar panel hardware to be the main supply for generating the voltage that is stored in the battery. The battery can be used to supply the Wemos microcontroller, the supply from the battery to the microcontroller is coupled with a stepdown voltage to lower the voltage from 12 Volts to 5 Volts as the voltage required by the microcontroller to monitor it, when the current and voltage sensors have measured the current generated by the solar panel, then on Wemos will be controlled and regulated to calculate the amount of current, voltage, and light intensity. A change in the intensity of the sun's light causes other sensor parameters to change in value as well. The resulting values of the parameters can be monitored through the website which is connected via the Wemos communication line with the Esp8266 Wi-Fi module. Thingspeak as an interface will display data from the serial monitor and will be sent. Solar Panel Sensor INA 219 Solar Charge Control Sensor INA 219 Battery Step Down Arduino Figure 2. System Block Diagram The hardware design will discuss the overall schematic of the tool system. The overall system schematic is a combination of several circuits that have been configured with each other. The schematic of this . Santi Triwijaya et al. Journal of Railway Transportation and Technology. Vol. 2 No. system is the overall circuit used in the tool control system. The schematic of the overall tool control system used in the design of the final project tool is shown in Figure 3. Figure 3. Schematic software design Software design contains the process of creating a tool system program. Furthermore, the electrical design contains the process of making a centralized solar panel online monitoring system tool using the Thingspeak web. The system design stages that will be carried out in this study are explained in the flowchart of Figure 4 . Starting with testing the connection on the wifi. If the device is connected to wifi then the system will start working. Furthermore, data in the form of voltage, current and solar intensity from sensor readings can be sent to thingspeak. Program design for a solar panel monitoring system is done with the Arduino IDE software. In programming on arduino the sensor reading results will be sent to the ESP-826 module. The program for reading the voltage, current and solar intensity sensors is shown in Figure 4. ESP8266 is in charge of sending data from sensor readings to the Thingspeak platform via Wi-Fi. Program to send data to the Thingspeak platform via a secret API key that has been obtained from an email that has been registered as a The program as a Thingspeak Network Connection is shown in Figure 4 . Santi Triwijaya et al. Journal of Railway Transportation and Technology. Vol. 2 No. void loop() Start int Solar_Intensity1= digitalRead(D. Solar_Intensity1= Solar_Intensity1-1. cahaya = abs(Solar_Intensity. Connecting to wifi Serial. println(Solar Intensit. value = analogRead. nalogPi. Vmodul = . alue * 5. / 1023. vf= Vmodul / (R2/(R1 R. wifi connected? hasil = vf-7. Serial. print("Module output voltage = "). Yes Serial. print(Vmodul,. Serial. print("volt"). Serial. print(". Measurement results = "). system works Serial. Serial. println("volt"). uploading data from sensor readings of voltage, current and solar intensity to delay. #include