A branching algorithm to reduce computational time of batch models: Application for blast analyses

Dennis, Adam A; Smyl, Danny; Stirling, Chris G.; Rigby, S.E.

doi:10.1177/20414196221085720

Cited by 4 publications

(4 citation statements)

References 29 publications

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“…CFD simulations are generally capable of replicating experimental data with good accuracy and can provide a verification approach to novel experimental work. However, despite ongoing attempts to expedite numerical analyses [168], they generally lack the necessary short computation times required for decision-making, emergency response, or even parameter-rich, risk-based studies. Neural networks have been shown to significantly improve upon the issue of computation time compared to CFD methods, and their utilisation will likely spread throughout the field as a preferred numerical-based approach in the coming years as training datasets become more thorough and data-rich.…”

Section: Discussionmentioning

confidence: 99%

A Review of Blast Loading in the Urban Environment

et al. 2023

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Urban blasts have become a significant concern in recent years. Whilst free-field blasts are well understood, the introduction of an urban setting (or any complex geometry) gives rise to multiple blast wave interactions and unique flow complexities, significantly increasing the difficulty of loading predictions. This review identifies commonly agreed-upon concepts or behaviours that are utilised to describe urban shock wave propagation, such as channelling and shielding, in conjunction with exploring urban characterisation metrics that aim to predict the effects on global blast loading for an urban blast. Likewise, discrepancies and contradictions are highlighted to promote key areas that require further work and clarification. Multiple numerical modelling programmes are acknowledged to showcase their ability to act as a means of validation and a preliminary testing tool. The findings contained within this review aim to inform future research decisions and topics better.

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Section: Discussionmentioning

confidence: 99%

A Review of Blast Loading in the Urban Environment

et al. 2023

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“…x min = 0.5, x max = 0.5+P, y min = 0, y max = 2, z min = H, z max = 0.5+H Target point grid 1 x min = 0.5001, x max = 0.5+P, y min = 0, y max = 1, z min = z max = H-0.0001 Target point grid 2 x min = 0.5001, x max = 0.5001, y min = 0, y max = 1, z min = 0, z max = H-0.0001 Alternatively, the Branching Algorithm (Dennis et al, 2022) can be used to identify unique inputs from initial conditions and the problem domain.…”

Section: Data Collection Using Prosairmentioning

confidence: 99%

“…A total of 1287 successful simulations were run, each yielding 204 independent variables and 2 output variables. Alternatively, the Branching Algorithm (Dennis et al, 2022) can be used to identify unique inputs from initial conditions and the problem domain.…”

Section: Data Collection Using Prosairmentioning

confidence: 99%

Prediction of blast loading on protruded structures using machine learning methods

Zahedi¹,

Golchin

2022

International Journal of Protective Structures

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Current empirical and semi-empirical based design manuals are restricted to the analysis of simple building configurations against blast loading. Prediction of blast loads for complex geometries is typically carried out with computational fluid dynamics solvers, which are known for their high computational cost. The combination of high-fidelity simulations with machine learning tools may significantly accelerate processing time, but the efficacy of such tools must be investigated. The present study evaluates various machine learning algorithms to predict peak overpressure and impulse on a protruded structure exposed to blast loading. A dataset with over 250,000 data points extracted from ProSAir simulations is used to train, validate, and test the models. Among the machine learning algorithms, gradient boosting models outperformed neural networks, demonstrating high predictive power. These models required significantly less time for hyperparameter optimization, and the randomized search approach achieved relatively similar results to that of grid search. Based on permutation feature importance studies, the protrusion length was considered a significantly more influential parameter in the construction of decision trees than building height.

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“…The result was the Basic Local Alignment Search Tool (BLAST) algorithm, designed to approximate the outcomes of the Smith-Waterman alignment algorithm [5] while avoiding the comparison of each residue against other residues. BLAST, being heuristic in nature, incorporates "smart shortcuts" that enhance its running speed [6]. However, this trade-off for improved speed slightly compromises the algorithm's accuracy.…”

Section: Introductionmentioning

confidence: 99%

Artificial Intelligence: Using BLAST Algorithm for DNA Classification of Thicket Vegetation

Gundu

2023

iCARTi

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Artificial Intelligence (AI) has revolutionized molecular ecology by enhancing DNA classification methods. This study explores the application of the Basic Local Alignment Search Tool (BLAST) algorithm, an AI-powered bioinformatics tool, for DNA classification within the unique ecosystem of Eastern Cape Thickets. Our focus was on leveraging BLAST's capabilities to identify and characterize plant species based on genetic sequences. We collected plant samples from diverse locations within the Eastern Cape Thickets and employed advanced DNA extraction and sequencing techniques to acquire a comprehensive dataset. BLAST analysis played a central role in comparing our sequences with the GenBank database to determine species identities and potential functions. The BLAST algorithm demonstrated remarkable efficiency in identifying known species, confirming their presence in the thicket ecosystem. Notably, BLAST's utility extended beyond species confirmation, as it unveiled sequences with limited matches, suggesting the existence of novel genetic elements specific to the region. By harnessing AI, BLAST facilitated accurate species classification and functional annotation. Our study showcases the potency of AI-driven DNA classification using the BLAST algorithm in elucidating the genetic makeup of the Eastern Cape Thickets. The algorithm's proficiency in decoding intricate genetic information, elucidating functional attributes, and predicting potential adaptations underscores its pivotal role in modern molecular ecology research. These findings contribute to the broader understanding of genetic diversity within this ecosystem and highlight the transformative impact of AI-driven bioinformatics tools on ecological studies and conservation strategies.

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A branching algorithm to reduce computational time of batch models: Application for blast analyses

Cited by 4 publications

References 29 publications

A Review of Blast Loading in the Urban Environment

A Review of Blast Loading in the Urban Environment

Prediction of blast loading on protruded structures using machine learning methods

Artificial Intelligence: Using BLAST Algorithm for DNA Classification of Thicket Vegetation

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