Enterprise AI Analysis
Prediction of waste generation forecast and emission potential on the Erode City solid waste dump yards based on machine learning approach
Authors: E. B. Priyanka¹, S. Vijayshanthy², S. Thangavel¹, R. Anand3,4, G. B. Bhavana³, Baseem Khan 4,5,6, K. Jeyanthi & A. Ambikapathy
Proposed research presents a data-driven framework for forecasting municipal solid waste (MSW) generation and emission dynamics in Erode City, India, by employing supervised machine learning algorithms. Leveraging a five-year dataset (2019-2024) comprising socio-economic variables, zonal waste typologies, and historical waste volumes, the model integrates Support Vector Machine (SVM), Random Forest (RF), and Naive Bayes (NB) classifiers. Feature selection and proximity ranking techniques were applied to identify high-impact variables, with plastic and organic waste emerging as dominant predictors. Data pre-processing included normalization, missing value imputation, and spatial zoning analysis. The model was validated through cross-validation with an 80:20 training-to-testing ratio. Among the tested models, SVM exhibited Superior performance, achieving a prediction accuracy of 96%, lowest mean squared error (MSE = 4860), and minimal computational latency (0.67 seconds), indicating suitability for real-time deployment. The integration of proximity matrix analysis and zonal feature clustering enhanced interpretability and robustness. The proposed framework demonstrates significant potential for scalable waste forecasting applications, enabling emission quantification and strategic decision-making. Future work includes the incorporation of real-time sensor data, temporal decomposition, and hybrid deep learning architectures to optimize waste handling and carbon mitigation strategies.
The Erode City waste management landscape is ripe for AI-driven transformation. Our analysis reveals key performance indicators and identifies areas for significant operational and environmental improvement.
0%
SVM Prediction Accuracy
MSE=0
Lowest Mean Squared Error
0s
Computational Latency (SVM)
Deep Analysis & Enterprise Applications
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Executive Summary
Proposed Methodology
Results and Discussion
96%
SVM Prediction Accuracy Achieved
MSE=4860
Lowest Mean Squared Error for Robustness
Erode City Waste Management Case Study
Erode City, Tamil Nadu, faces significant challenges in municipal solid waste management, generating an average of 250 metric tons of waste daily. Dumping sites at Vendipalayam (19.45 acres) and Vairapalayam (7.4 acres) suffer from frequent fire incidents, foul odors, and groundwater contamination, leading to public protests. Historical data, socioeconomic surveys, and real-time monitoring are integrated to model waste generation and inform strategic interventions, aiming to address critical environmental and public health concerns. Key findings indicate plastic and organic waste as dominant contributors.
Enterprise Process Flow: Waste Management Methodology
Real-time Dump Yard Survey
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Historical Data Collection
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Validation & Field Data Acquisition
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Multi-stage Cluster Sampling & Data Consolidation
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ML Model Development & Pre-processing
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Waste Disposal Analysis using ML
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Identify Influencing Waste Impacts
| Model | Accuracy | Computation Time | Error Rate |
|---|---|---|---|
| SVM | 96% | 0.67 Sec | Low |
| RF | 91.54% | 0.79 Sec | Moderate |
| NB | 93.21% | 0.93 Sec | High |
A comparative analysis of the Support Vector Machine (SVM), Random Forest (RF), and Naive Bayes (NB) algorithms for waste forecasting shows SVM leading in accuracy and computational efficiency. SVM demonstrated superior performance with a prediction accuracy of 96% and the lowest testing Mean Squared Error (MSE) of 4860, with a minimal computational latency of 0.67 seconds, making it ideal for real-time deployment.
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Estimated Annual Savings
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Employee Hours Reclaimed Annually
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Your AI Implementation Roadmap
A typical phased approach to integrate advanced AI into your waste management operations, ensuring smooth adoption and measurable results.
Phase 1: Data Audit & Strategy (1-2 Months)
Comprehensive review of existing waste generation data, infrastructure, and operational workflows. Develop a tailored AI strategy and identify key integration points for ML models.
Phase 2: Pilot Program & Model Training (2-4 Months)
Deploy AI models on a pilot scale (e.g., specific zones in Erode City). Collect real-time data from IoT sensors, refine feature selection, and train SVM/RF/NB models for accurate forecasting and classification.
Phase 3: Full-Scale Deployment & Integration (3-6 Months)
Expand AI solutions across all operational areas. Integrate models with existing municipal systems, including collection route optimization, smart bin management, and emission monitoring platforms.
Phase 4: Continuous Optimization & Scaling (Ongoing)
Monitor AI model performance, gather user feedback, and continuously fine-tune algorithms. Explore advanced deep learning architectures and real-time sensor data for further enhancements and scalability.
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