International Journal on Advanced Science, Engineering and Information Technology

This work aims to achieve a functional system in terms of software and hardware to measure humidity with temperature and raining fall. Also, this system allows monitoring the date and time. We used Arduino Nano with the interfacing of the DHT22 sensor and a raindrop sensor placed in the local environment to measure the mentioned data. After designing the system that depends on the microcontroller Embedded on the Arduino board, we will display the data on a screen of the PC by the Arduino window (serial monitor) and display it on the LCD screen. This paper describes a simple portable design for humidity, temperature, and rain or no rain. The portable design can be made with a low cost of electronic components. It is efficiently and locally available so that it can be used to monitor weather conditions at any place. The test results showed that this system's component is small and can be packaged in a small plastic box. Besides, through the programming, we recorded the data on the Excel program, and at the same time. The data were recorded in a memory added to the manufactured system. The data obtained every five seconds are the (date, time, temperature, humidity, weather if rainy or not rainy). The system consists of two parts; the first part is inside the indoor, and it can be placed outdoor as needed and the second part is a rain sensor that can be placed outdoor. In case of rain, the buzzer and LED can be turned on to indicate the condition of rain.

Devaraju, J. T., Suhas, K. R., Mohana, H. K., & Patil, V. A. (2015). Wireless portable microcontroller based weather monitoring station. Measurement, 76, 189-200.â€

Noordin, K. A., Onn, C. C., & Ismail, M. F. (2006). A low-cost microcontroller-based weather monitoring system. CMU journal, 5(1), 33-39.â€

Rao, B. S., Rao, K. S., & Ome, N. (2016). Internet of Things (IoT) based weather monitoring system. international journal of advanced research in computer and communication engineering, 5(9), 312-319.â€

Jiang, P., Xia, H., He, Z., & Wang, Z. (2009). Design of a water environment monitoring system based on wireless sensor networks. Sensors, 9(8), 6411-6434.â€

Kulkarni, P. A., & Vaijanath, V. Y. (2015). An economical weather monitoring system based on GSM using solar and wind energy. International Journal of Advanced Technology and Innovative Research Volume, 7, 0263-0268.â€

Sharaf, H. K., Ishak, M. R., Sapuan, S. M., Yidris, N., & Fattahi, A. (2020). Experimental and numerical investigation of the mechanical behavior of full-scale wooden cross arm in the transmission towers in terms of load-deflection test. Journal of Materials Research and Technology, 9(4), 7937-7946.â€

Sharaf, H. K., Ishak, M. R., Sapuan, S. M., & Yidris, N. (2020). Conceptual design of the cross-arm for the application in the transmission towers by using TRIZ–morphological chart–ANP methods. Journal of Materials Research and Technology, 9(4), 9182-9188.â€

Kumar, A., & Hancke, G. P. (2014). Energy efficient environment monitoring system based on the IEEE 802.15. 4 standard for low cost requirements. IEEE Sensors Journal, 14(8), 2557-2566.â€

Jiang, P., Xia, H., He, Z., & Wang, Z. (2009). Design of a water environment monitoring system based on wireless sensor networks. Sensors, 9(8), 6411-6434.â€

Xiao, L., & Wang, Z. (2011). Internet of things: A new application for intelligent traffic monitoring system. Journal of networks, 6(6), 887.â€

Sharaf, H. K., Salman, S., Dindarloo, M. H., Kondrashchenko, V. I., Davidyants, A. A., & Kuznetsov, S. V. (2021). The effects of the viscosity and density on the natural frequency of the cylindrical nanoshells conveying viscous fluid. The European Physical Journal Plus, 136(1), 1-19.â€

Sarkar, I., Pal, B., Datta, A., & Roy, S. (2019). Wi-Fi-Based Portable Weather Station for Monitoring Temperature, Relative Humidity, Pressure, Precipitation, Wind. Information and Communication Technology for Sustainable Development: Proceedings of ICT4SD 2018, 933, 399.â€

Benghanem, M. (2009). Measurement of meteorological data based on wireless data acquisition system monitoring. Applied energy, 86(12), 2651-2660.â€

Sharaf, H. K., Salman, S., Abdulateef, M. H., Magizov, R. R., Troitskii, V. I., Mahmoud, Z. H., ... & Mohanty, H. (2021). Role of initial stored energy on hydrogen microalloying of ZrCoAl (Nb) bulk metallic glasses. Applied Physics A, 127(1), 1-7.â€

N Genikomsakis, K., Galatoulas, N. F., I Dallas, P., Candanedo Ibarra, L. M., Margaritis, D., & S Ioakimidis, C. (2018). Development and on-field testing of low-cost portable system for monitoring PM2. 5 concentrations. Sensors, 18(4), 1056.â€

Martín-Garín, A., Millán-García, J. A., Baïri, A., Millán-Medel, J., & Sala-Lizarraga, J. M. (2018). Environmental monitoring system based on an Open Source Platform and the Internet of Things for a building energy retrofit. Automation in Construction, 87, 201-214.â€

Yunus, N. A. M., Zainudin, M. A., Sulaiman, N., & Abbas, Z. A. (2018, November). Microfluidic Fluid Flow Design with Arduino Relay and Temperature Controller for Processor. In 2018 IEEE 5th International Conference on Smart Instrumentation, Measurement and Application (ICSIMA) (pp. 1-4). IEEE.

Waaiz, M., Reddy, K. K., & Punyaseshudu, D. (2017). Design and Development of Portable Automatic Weather System. International Journal of Applied Environmental Sciences, 12(2), 383-398.â€

Gunawan, T. S., Munir, Y. M. S., Kartiwi, M., & Mansor, H. (2018). Design and implementation of portable outdoor air quality measurement systemn using arduino. International Journal of Electrical and Computer Engineering, 8(1), 280.â€

Ni, Y. Q., Xia, Y., Liao, W. Y., & Ko, J. M. (2009). Technology innovation in developing the structural health monitoring system for Guangzhou New TV Tower. Structural Control and Health Monitoring: The Official Journal of the International Association for Structural Control and Monitoring and of the European Association for the Control of Structures, 16(1), 73-98.â€

Al-Kuwari, M., Ramadan, A., Ismael, Y., Al-Sughair, L., Gastli, A., & Benammar, M. (2018, April). Smart-home automation using IoT-based sensing and monitoring platform. In 2018 IEEE 12th International Conference on Compatibility, Power Electronics and Power Engineering (CPE-POWERENG 2018) (pp. 1-6). IEEE

Khandakar, A., Chowdhury, M. E., Ahmed, R., Dhib, A., Mohammed, M., Al-Emadi, N. A., & Michelson, D. (2019). Portable system for monitoring and controlling driver behavior and the use of a mobile phone while driving. Sensors, 19(7), 1563.â€.â€