Enes Gül scite author profile

Machine learning (ML) methods have shown noteworthy skill in recognizing environmental patterns. However, presence of weather noise associated with the chaotic characteristics of water cycle components restricts the capability of standalone ML models in the modeling of extreme climate events such as droughts. To tackle the problem, this article suggests two novel hybrid ML models based on combination of extreme learning machine (ELM) with water cycle algorithm (WCA) and bacterial foraging optimization (BFO). The new models, respectively called ELM-WCA and ELM-BFO, were applied to forecast standardized precipitation evapotranspiration index (SPEI) at Beypazari and Nallihan meteorological stations in Ankara province (Turkey). The performance of the proposed models was compared with those the standalone ELM considering root mean square error (RMSE), Nash-Sutcliffe efficiency (NSE), and graphical plots. The forecasting results for three- and six-month accumulation periods showed that the ELM-WCA is superior to its counterparts. The NSE results of the SPEI-3 forecasting in the testing period proved that the ELM-WCA improved drought modeling accuracy of the standalone ELM up to 72% and 85% at Beypazari and Nallihan stations, respectively. Regarding the SPEI-6 forecasting results, the ELM-WCA achieved the highest RMSE reduction percentage about 63% and 56% at Beypazari and Nallihan stations, respectively.

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An improved adaptive neuro-fuzzy inference system for hydrological drought prediction in Algeria

Achite

Gül

Elshaboury

et al. 2023

Physics and Chemistry of the Earth, Parts A/B/C

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Urmia lake water depth modeling using extreme learning machine-improved grey wolf optimizer hybrid algorithm

Sales¹,

Gül

Safari

et al. 2021

Theor Appl Climatol

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Studying the Changes in the Hydro‐Meteorological Components of Water Budget in Lake Urmia

Vaheddoost

Fathian

Gül

et al. 2022

Water Resources Research

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Lake Urmia's water level decline and its socio-environmental drawbacks were continuously addressed by many researchers over the last two decades. In the mid-2000s, major changes associated with the lake water level were determined with a jump, initiated in 1993 and a subsequent decline in 1998 (Fathian & Vaheddoost, 2021a, 2021b. Since then, the lake's surface area was continuously degraded that urged decision-makers to take immediate actions. To this end, many studies have been conducted to realize, simulate, and describe the causes and aftermath of the phenomenon. Although no general conclusions are made, several issues are addressed for this drastic decline. The effect of climate change on the Lake Urmia basin was addressed by Abbasian et al. ( 2020),

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Sediment transport modeling in non-deposition with clean bed condition using different tree-based algorithms

et al. 2021

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To reduce the problem of sedimentation in open channels, calculating flow velocity is critical. Undesirable operating costs arise due to sedimentation problems. To overcome these problems, the development of machine learning based models may provide reliable results. Recently, numerous studies have been conducted to model sediment transport in non-deposition condition however, the main deficiency of the existing studies is utilization of a limited range of data in model development. To tackle this drawback, six data sets with wide ranges of pipe size, volumetric sediment concentration, channel bed slope, sediment size and flow depth are used for the model development in this study. Moreover, two tree-based algorithms, namely M5 rule tree (M5RT) and M5 regression tree (M5RGT) are implemented, and results are compared to the traditional regression equations available in the literature. The results show that machine learning approaches outperform traditional regression models. The tree-based algorithms, M5RT and M5RGT, provided satisfactory results in contrast to their regression-based alternatives with RMSE = 1.184 and RMSE = 1.071, respectively. In order to recommend a practical solution, the tree structure algorithms are supplied to compute sediment transport in an open channel flow.

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Flood hazard mapping using M5 tree algorithms and logistic regression: a case study in East Black Sea Region

et al. 2023

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Enes Gül

Robust optimization of SVM hyper-parameters for spillway type selection

Regression models for sediment transport in tropical rivers

Optimizing Extreme Learning Machine for Drought Forecasting: Water Cycle vs. Bacterial Foraging

An improved adaptive neuro-fuzzy inference system for hydrological drought prediction in Algeria

Urmia lake water depth modeling using extreme learning machine-improved grey wolf optimizer hybrid algorithm

Studying the Changes in the Hydro‐Meteorological Components of Water Budget in Lake Urmia

Sediment transport modeling in non-deposition with clean bed condition using different tree-based algorithms

Flood hazard mapping using M5 tree algorithms and logistic regression: a case study in East Black Sea Region

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