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- Title
A Machine Learning Strategy for the Quantitative Analysis of the Global Warming Impact on Marine Ecosystems.
- Authors
Alhakami, Hosam; Kamal, Mustafa; Sulaiman, Muhammad; Alhakami, Wajdi; Baz, Abdullah
- Abstract
It is generally observed that aquatic organisms have symmetric abilities to produce oxygen (O 2) and fix carbon dioxide (C O 2) . A simulation model with time-dependent parameters was recently proposed to better understand the symmetric effects of accelerated climate change on coastal ecosystems. Changes in environmental elements and marine life are two examples of variables that are expected to change over time symmetrically. The sustainability of each equilibrium point is examined in addition to proving the existence and accuracy of the proposed model. To support the conclusions of this research compared to other studies, numerical simulations of the proposed model and a case study are investigated. This paper proposes an integrated bibliographical analysis of artificial neural networks (ANNs) using the Reverse-Propagation with Levenberg–Marquaradt Scheme (RP-LMS) to evaluate the main properties and applications of ANNs. The results obtained by RP-LMS show how to prevent global warming by improving the management of marine fish resources. The reference dataset for greenhouse gas emissions, environmental temperature, aquatic population, and fisheries population (GAPF) is obtained by varying parameters in the numerical Adam approach for different scenarios. The accuracy of the proposed RP-LMS neural network is demonstrated using mean square error (MSE), regression plots, and best-fit output. According to RP-LMS, the current scenario of rapid global warming will continue unabated over the next 50 years, damaging marine ecosystems, particularly fish stocks.
- Subjects
MARINE ecology; MACHINE learning; LEARNING strategies; MARINE resource management; MARINE biology; ARTIFICIAL neural networks
- Publication
Symmetry (20738994), 2022, Vol 14, Issue 10, pN.PAG
- ISSN
2073-8994
- Publication type
Article
- DOI
10.3390/sym14102023