Precise Prediction of Biochar Yield and Proximate Analysis by Modern Machine Learning and SHapley Additive exPlanations

Le, Anh Tuan; Pandey, Ashok; Sirohi, Ranjan; Sharma, Prabhakar; Chen, Wei-Hsin; Pham, Nguyen Dang Khoa; Tran, Viet Dung; Nguyen, Xuan Phuong; Hoang, Anh Tuan

doi:10.1021/acs.energyfuels.3c02868

Cited by 20 publications

(4 citation statements)

References 74 publications

(134 reference statements)

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“…It is noted that solar energy, wind power, hybrid energy, geothermal energy, hydrogen energy, bioenergy, biofuels, biomass, and ocean energy can all employ AI models Chen et al, 2021;W.-H. Chen et al, 2022bW.-H. Chen et al, , 2022aJha et al, 2017;Tabanjat et al, 2018;Tuan Hoang et al, 2021). Besides, Support Vector Machines (SVMs), Artificial Neural Networks (ANNs), Ensemble, Wavelet Neural Networks (WNNs), SHapley Additive exPlanations, and Decision Trees are some examples of AI algorithms (de Ville, 2013; Le et al, 2023;Li et al, 2023;V. G. Nguyen et al, 2023;Said et al, 2022;Sharma et al, 2022b;Veza et al, 2022a;Zhang et al, 2022).…”

Section: Review Articlementioning

confidence: 99%

Harnessing artificial intelligence for data-driven energy predictive analytics: A systematic survey towards enhancing sustainability

Le,

Priya,

et al. 2024

Int. J. Renew. Energy Dev.

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The escalating trends in energy consumption and the associated emissions of pollutants in the past century have led to energy depletion and environmental pollution. Achieving comprehensive sustainability requires the optimization of energy efficiency and the implementation of efficient energy management strategies. Artificial intelligence (AI), a prominent machine learning paradigm, has gained significant traction in control applications and found extensive utility in various energy-related domains. The utilization of AI techniques for addressing energy-related challenges is favored due to their aptitude for handling complex and nonlinear data structures. Based on the preliminary inquiries, it has been observed that predictive analytics, prominently driven by artificial neural network (ANN) algorithms, assumes a crucial position in energy management across various sectors. This paper presents a comprehensive bibliometric analysis to gain deeper insights into the progression of AI in energy research from 2003 to 2023. AI models can be used to accurately predict energy consumption, load profiles, and resource planning, ensuring consistent performance and efficient resource utilization. This review article summarizes the existing literature on the implementation of AI in the development of energy management systems. Additionally, it explores the challenges and potential areas of research in applying ANN to energy system management. The study demonstrates that ANN can effectively address integration issues between energy and power systems, such as solar and wind forecasting, power system frequency analysis and control, and transient stability assessment. Based on the comprehensive state-of-the-art study, it can be inferred that the implementation of AI has consistently led to energy reductions exceeding 25%. Furthermore, this article discusses future research directions in this field.

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Section: Review Articlementioning

confidence: 99%

Harnessing artificial intelligence for data-driven energy predictive analytics: A systematic survey towards enhancing sustainability

Le,

Priya,

et al. 2024

Int. J. Renew. Energy Dev.

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“…This estimates the amount of variation in the dependent variable that is predicted from the independent variables. Its value ranges from zero to one, with a higher value indicating a better match between the model and the data [79][80][81][82]. R 2 may be stated mathematically as follows:…”

Section: Coefficient Of Determination (R 2 )mentioning

confidence: 99%

“…Coefficient of determination (r 2 ): This estimates the amount of variation in the dependent variable that is predicted from the independent variables. Its value ranges from zero to one, with a higher value indicating a better match between the model and the data [79][80][81][82]where the coefficient of determination (R2. R 2 may be stated mathematically as follows:…”

Section: Model Evaluation Techniquesmentioning

confidence: 99%

Leveraging Artificial Intelligence to Enhance Port Operation Efficiency

Dinh,

Pham,

Nguyen

et al. 2024

Polish Maritime Research

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Maritime transport forms the backbone of international logistics, as it allows for the transfer of bulk and long-haul products. The sophisticated planning required for this form of transportation frequently involves challenges such as unpredictable weather, diverse types of cargo kinds, and changes in port conditions, all of which can raise operational expenses. As a result, the accurate projection of a ship’s total time spent in port, and the anticipation of potential delays, have become critical for effective port activity planning and management. In this work, we aim to develop a port management system based on enhanced prediction and classification algorithms that are capable of precisely forecasting the lengths of ship stays and delays. On both the training and testing datasets, the XGBoost model was found to consistently outperform the alternative approaches in terms of RMSE, MAE, and R2 values for both the turnaround time and waiting period models. When used in the turnaround time model, the XGBoost model had the lowest RMSE of 1.29 during training and 0.5019 during testing, and also achieved the lowest MAE of 0.802 for training and 0.391 for testing. It also had the highest R2 values of 0.9788 during training and 0.9933 during testing. Similarly, in the waiting period model, the XGBoost model outperformed the random forest and decision tree models, with the lowest RMSE, MAE, and greatest R2 values in both the training and testing phases.

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“…To improve the process and attain the required performance, it is vital to understand how these factors interrelate and how they create the impact on the drilled hole quality characteristics, such as circularity, taper angle, and surface roughness [17][18][19]. Manufacturing experts and researchers have been giving a lot of attention lately to machine learning (ML) algorithms for modeling and process optimization [20][21][22]. With the procedure of machine learning (ML) algorithms, complex relationships between input factors and output responses can be efficiently seized, agreeing for exact prediction-making and the identification of primary processes [23][24][25].…”

Section: Introductionmentioning

confidence: 99%

Machinability study on abrasive waterjet drilling of YSZ-coated inconel 718 superalloy: optimization and modelling by machine learning

Siva Kumar,

Nagarajan,

Vasudevan

2024

Eng. Res. Express

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The purpose of this research is to ascertain the optimal abrasive waterjet drilling parameters for making holes on Inconel 718 superalloy coated with yttrium-stabilized zirconia, namely waterjet pressure (JP), standoff distance (SD), abrasive flow rate (FR), and angle of impact (AI). The study explores the predictive modeling of the entry diameter (DN) and exit diameter (DX) of the drilled holes using an amalgamation of experimental analysis, response optimization and machine learning approaches. Eight different ML techniques are used to predict DN and DX. Better values of DN=1.31352 mm and DX=1.00515 mm are obtained through Random Forest for the setting of JP=175 MPa, FR=250 g/min, SD=1.45455 mm, and AI=0.909091 deg. Further, the tuning of hyperparameters of Random Forest algorithm is performed to study the improvement in measuring DN and DX. The least value of total absolute error=0.468 is observed while finding the DN and DX using Random Forest algorithm than the traditional response optimization method with reference to the confirmation test results. The work provides important insights for enhancing the machinability of YSZ-coated Inconel 718 superalloy utilizing the AWJ drilling process by bridging the gap between manufacturing research, machine learning, and real-world applications.

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Precise Prediction of Biochar Yield and Proximate Analysis by Modern Machine Learning and SHapley Additive exPlanations

Cited by 20 publications

References 74 publications

Harnessing artificial intelligence for data-driven energy predictive analytics: A systematic survey towards enhancing sustainability

Harnessing artificial intelligence for data-driven energy predictive analytics: A systematic survey towards enhancing sustainability

Leveraging Artificial Intelligence to Enhance Port Operation Efficiency

Machinability study on abrasive waterjet drilling of YSZ-coated inconel 718 superalloy: optimization and modelling by machine learning

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