Applied and Computational Engineering

Open access

Print ISSN: 2755-2721

Online ISSN: 2755-273X

About ACE

The proceedings series Applied and Computational Engineering (ACE) is an international peer-reviewed open access series that publishes conference proceedings from various methodological and disciplinary perspectives concerning engineering and technology. ACE is published irregularly. The series contributes to the development of computing sectors by providing an open platform for sharing and discussion. The series publishes articles that are research-oriented and welcomes theoretical and applicational studies. Proceedings that are suitable for publication in the ACE cover domains on various perspectives of computing and engineering.

Aims & scope of ACE are:
·Computing
·Machine Learning
·Electrical Engineering & Signal Processing
·Applied Physics & Mechanical Engineering
·Chemical & Environmental Engineering
·Materials Science and Engineering

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Editors View full editorial board

Hisham AbouGrad
University of East London
United Kingdom
Editorial Board
Mian Umer Shafiq
UCSI University
Malaysia
Editorial Board
Bilyaminu Auwal Romo
University of East London
United Kingdom
Editorial Board
Yilun Shang
Northumbria University
United Kingdom
Associate Editor
yilun.shang@northumbria.ac.uk

Latest articles View all articles

Research Article
Published on 27 June 2025 DOI: 10.54254/2755-2721/2025.GL24381
Ruize Tian

In the context of significant renewable energy integration, power load forecasting is viewed as an essential task in energy management and power system operation and scheduling. In an effort to enhance the accuracy and precision of power load prediction, a predictive technique based on Long Short-Term Memory (LSTM) networks enhanced by the quantum-behaved particle swarm optimization (QPSO) is applied to ultra-short-term power load prediction in this paper. Initially, normalization is used to preprocess power load data before it is divided into training and testing datasets. Subsequently, global optimization of the LSTM’s essential hyperparameters and network architecture is conducted via QPSO, resulting in the development of a QPSO-LSTM forecasting model. Subsequently, the forecasting model is evaluated by employing the coefficient of determination (R²), mean absolute error (MAE), mean absolute percentage error (MAPE), and root mean square error (RMSE) as performance metrics. Finally, comparative experiments are conducted between the proposed model and traditional neural network models. The findings demonstrate that the QPSO-LSTM model offers enhanced forecasting precision and optimal fitting performance.

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Tian,R. (2025). Artificial Intelligence-Based Ultra-Short-Term Power Load Forecasting. Applied and Computational Engineering,172,1-10.
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Research Article
Published on 27 June 2025 DOI: 10.54254/2755-2721/2025.24418
Yutao Zhang

Bio-based hydrogels, derived from natural materials such as chitosan, alginate, gelatin, and collagen, have garnered significant attention for their outstanding biocompatibility and ability to mimic natural tissues. This review examines commonly used preparation methods, including physical, chemical and hybrid cross-linking, along with their primary components, such as polysaccharides and proteins. Owing to their flexibility and responsiveness, these hydrogels are widely used in areas such as soft robotics, cancer therapy and biosensing. However, despite promising advancements, significant challenges persist, particularly regarding their limited strength and stability. Future research should aim to enhance the performance and reliability of these materials to support their integration into complex medical and engineering systems.

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Zhang,Y. (2025). Review on Biological-based Hydrogels for Advanced Applications. Applied and Computational Engineering,171,21-32.
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Research Article
Published on 27 June 2025 DOI: 10.54254/2755-2721/2025.24428
Xiaogang Zhao, Ke Zhang

To enable systematic quantification and effective control of carbon emissions in the construction industry, this paper proposes a life cycle-based carbon emission model. Grounded in LCA principles, the model spans four stages: material production, construction, operation, and demolition. It integrates phased accounting with unified aggregation to ensure a closed-loop calculation process. Parameters are derived from the “Building Carbon Emission Calculation Standard” and the China Life Cycle Database (CLCD). Empirical validation on public buildings in Shanghai demonstrates the model’s stability and its ability to identify high-emission stages and optimization opportunities. The model proves applicable to carbon verification, green building evaluation, and full-process carbon management, showing strong practical value and scalability.

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Zhao,X.;Zhang,K. (2025). Construction and Empirical Study of the Quantitative Model of the Whole Process of Building Carbon Emissions. Applied and Computational Engineering,171,16-20.
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Research Article
Published on 27 June 2025 DOI: 10.54254/2755-2721/2025.24448
Changyue Li, Delun Li, Hao Wen, Jinyang Xu

This paper focuses on the research of ancient building staircases, developing multiple models for wear analysis and traffic flow prediction. Firstly, relevant data on wear and traffic flow are collected, including material properties, surface conditions, and the number of staircase users. Model I is based on material mechanics and surface wear theory, constructing W = f (F, D, M) to examine the degree of wear; Model II combines LWR traffic flow and queuing theory, constructing Q = g(ρ, v, lq, tq) to analyze traffic flow; Model III is a PSO model that improves the first two, using the mean square error between predicted and actual data as the fitness function. The results show that the staircase wear model has good explanatory power, the traffic flow model has a high accuracy rate during peak and off-peak hours, and the mean square error of the combined model after PSO optimization is reduced by 30%, with improved fitting performance, providing an important reference for the maintenance, protection, and usage planning of ancient building staircases.

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Li,C.;Li,D.;Wen,H.;Xu,J. (2025). Research on Stair Wear of Ancient Building. Applied and Computational Engineering,171,1-15.
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Volumes View all volumes

Volume 172June 2025

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Proceedings of CONF-FMCE 2025 Symposium: Semantic Communication for Media Compression and Transmission

Conference website: https://2025.conffmce.org/glasgow.html

Conference date: 24 October 2025

ISBN: 978-1-80590-221-8(Print)/978-1-80590-222-5(Online)

Editor: Anil Fernando

Volume 171June 2025

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Proceedings of the 3rd International Conference on Functional Materials and Civil Engineering

Conference website: https://2025.conffmce.org/

Conference date: 24 October 2025

ISBN: 978-1-80590-219-5(Print)/978-1-80590-220-1(Online)

Editor: Anil Fernando

Volume 170June 2025

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Proceedings of the 3rd International Conference on Mechatronics and Smart Systems

Conference website: https://2025.confmss.org/

Conference date: 16 June 2025

ISBN: 978-1-80590-217-1(Print)/978-1-80590-218-8(Online)

Editor: Mian Umer Shafiq

Volume 169June 2025

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Proceedings of CONF-MSS 2025 Symposium: Machine Vision System

Conference website: https://www.confmss.org/chicago.html

Conference date: 5 June 2025

ISBN: 978-1-80590-209-6(Print)/978-1-80590-210-2(Online)

Editor: Marwan Omar, Cheng Wang

Indexing

The published articles will be submitted to following databases below: