Prediction of Gasification Process via Random Forest Regression Model Optimized with Meta-Heuristic Algorithms

Prediction of Gasification Process via Random Forest Regression Model Optimized with Meta-Heuristic Algorithms

This research presents an innovative predictive modeling approach for estimating Hydrogen and Nitrogen quantities in gasification processes, vital for converting carbonaceous feedstocks into valuable gases with minimal environmental impact. It addresses the pressing need for cost-effective and preci...

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Bibliographic Details
Main Author: Eunsung Oh
Format: Article
Language:English
Published: Bilijipub publisher 2024-03-01
Series:Journal of Artificial Intelligence and System Modelling
Subjects:
gasification
biomass
machine learning
random forest
snake optimization
equilibrium optimizer
Online Access:https://jaism.bilijipub.com/article_193317_15b39d9b201fff259fe95018a33c4640.pdf
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Summary:This research presents an innovative predictive modeling approach for estimating Hydrogen and Nitrogen quantities in gasification processes, vital for converting carbonaceous feedstocks into valuable gases with minimal environmental impact. It addresses the pressing need for cost-effective and precise solutions in gasification, streamlining estimation processes across various operational conditions, enhancing safety, and enabling data-driven optimization.  The current study involves organizing input data into eighteen distinct variables, comprising cellulose, hemicellulose, lignin, lower heating value, particle size, oxygen content, nitrogen content, volatile matter content, carbon content, hydrogen content, sulfur content, SB, moisture, temperature, ash content, equivalence ratio, residence time, and fixed carbon. This study leverages Random Forest Regression (RFR) to analyze gas generation outputs based on historical data. It enhances RFR's predictive accuracy by integrating advanced optimization techniques like Snake Optimization and Equilibrium Optimizer. This approach marks a significant step forward in optimizing gasification processes, promoting more efficient and sustainable conversion of carbonaceous feedstock. The results demonstrate the superior predictive performance of the RFSO model, achieving a remarkable R2 value of 99.7% in training for both Hydrogen (H_2) and Nitrogen (N_2). The optimized models, RFEO and RFSO, consistently outperform the baseline RFR model in forecasting accuracy metrics such as MSE and RMSE, emphasizing their reliability and effectiveness in predicting gasification outcomes.
ISSN:3041-850X

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