Metaheuristics-optimized deep learning to predict generation of sustainable energy from rooftop plant microbial fuel cells
Journal
International Journal of Energy Research
Journal Volume
46
Journal Issue
15
Pages
21001
Date Issued
2022-12-01
Author(s)
Abstract
Plant microbial fuel cells (PMFCs) are an emergent green-energy technology that continuously converts solar energy into electricity. Placing PMFCs on the roofs of urban buildings can help to create green urban environments even as they generate power. The power generation performance of PMFCs is affected by a range of environmental factors, so their power generation capacity is difficult to estimate. To develop an artificial intelligence model to forecast PMFC power generation accurately, relevant results obtained using shallow and deep learning techniques are compared for the first time. Once deep learning techniques had been identified as superior for this purpose, they were used with a bio-inspired optimization algorithm to dynamically setting the model hyperparameters. The developed model can also be applied to estimate the power generation capacity of PMFC devices in the future. The model was trained using data collected from sensors in a site experiment that was carried out using PMFCs embedded with Chinese pennisetumin (Pennisetum alopecuroides), narrowleaf cattail (Typha angustifolia), dwarf rotala (Rotala rotundifolia), and no plant as a control group. The original data of device parameters, environmental parameters, and the measured power generation of PMFCs in numerical form were applied to train shallow learning and time-series deep learning models. Meanwhile, the state-of-the-art sliding window technique was used to establish a numerical matrix, which was converted into a 2D image-like format to represent inputs for deep convolutional neural network (CNN) models. The accuracy in predicting the power generation capacity of PMFC devices showed that EfficientNet, an advanced type of CNN, was the best model among the shallow and deep learning techniques. These analytical results demonstrate the superior performance of deep CNNs in learning image features and their consequent suitability for constructing PMFC power generation forecasting models. To enhance the generalization performance of CNN, a newly developed bio-inspired optimization algorithm, jellyfish search (JS), was incorporated into this model to determine the optimal hyperparameters, yielding the hybrid JSCNN model. This investigation revealed that the JS optimization algorithm can find better values of hyperparameters of the CNN and stabilize model accuracy. Notably, once the optimal hyperparameters have been obtained using JS, the computation time of the hybrid JSCNN model is shorter than that of the generic CNN model, supporting the need to determine the appropriate hyperparameter values in deep learning. This study is the first to use its particular setup and to offer its particular precautions; it therefore contributes to the body of domain knowledge and practicality of sustainable PMFCs.
Subjects
building energy management | computer vision-based deep learning | green energy conversion and forecasting | jellyfish search optimizer | plant microbial fuel cell | wireless sensor network application
Publisher
WILEY-HINDAWI
Type
journal article