Simplified Prediction-Based AI-IoT Model for Energy Management Scheme in Standalone PV Powered Greenhouse

IEEE Journal of Emerging and Selected Topics in Industrial Electronics Pub Date : 2024-07-09 DOI:10.1109/JESTIE.2024.3425670

Soumya Ranjan Biswal;Tanmoy Roy Choudhury;Subhendu Bikash Santra;Babita Panda;Subhrajyoti Mishra;Sanjeevikumar Padmanaban

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Abstract

Automated greenhouse is essential for sustainable development and food security. Photovoltaic (PV) power with physical sensors-based control using Internet of Things needs high initial investment and operational cost. This also needs significant installed storage capacity. In the proposed solution, the dependency on physical sensors like temperature, humidity, soil moisture sensors, etc., are eliminated due to the application of eXtreme Gradient Boosting-based machine learning (ML) algorithm. The training and testing of ML algorithm are performed with one-year physical data (approx. 50k @10 min interval) from greenhouse which provides accurate mapping (Temperature MAPE: 1.51%, R ² : 0.9785 and Humidity MAPE: 1.68%, R ² : 0.9867) between predicted and sensor data. Also, a novel priority-based demand side management scheme is implemented which includes load shifting which reduces the requirement of installed PV and storage capacity. A reduction of 63.27% storage capacity is possible with proposed control approach. ML algorithm is programmed using Python language and implemented in Raspberry Pi-3B+ SBC. For physical verification of the proposed control unit, a laboratory-based prototype is developed with PV emulator (1.5 kW), programmable electronic load box, and relay unit controlled through Arduino UNO, Raspberry Pi-3B+ SBC, ESP-32 Combo unit.

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基于简化预测的AI-IoT模型的独立光伏温室能源管理方案

自动化温室对可持续发展和粮食安全至关重要。基于物联网物理传感器控制的光伏发电初期投资和运营成本较高。这也需要安装大量的存储容量。在提出的解决方案中，由于应用了基于极端梯度增强的机器学习（ML）算法，消除了对温度、湿度、土壤湿度传感器等物理传感器的依赖。机器学习算法的训练和测试是用一年的物理数据(大约。50k @10 min间隔)，提供了预测数据和传感器数据之间的精确映射（温度MAPE: 1.51%, R2: 0.9785，湿度MAPE: 1.68%, R2: 0.9867）。此外，还实施了一种新的基于优先级的需求侧管理方案，该方案包括负载转移，从而减少了对安装光伏和存储容量的需求。采用所提出的控制方法，可以减少63.27%的存储容量。ML算法采用Python语言编写，在Raspberry Pi-3B+ SBC上实现。为了对所提出的控制单元进行物理验证，开发了一个基于实验室的原型，其中包括PV模拟器（1.5 kW）、可编程电子负载箱和通过Arduino UNO、Raspberry Pi-3B+ SBC、ESP-32 Combo单元控制的继电器单元。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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IEEE Journal of Emerging and Selected Topics in Industrial Electronics

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