2022
DOI: 10.3390/math10214147
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Employing Quantum Fruit Fly Optimization Algorithm for Solving Three-Dimensional Chaotic Equations

Abstract: In a chaotic system, deterministic, nonlinear, irregular, and initial-condition-sensitive features are desired. Due to its chaotic nature, it is difficult to quantify a chaotic system’s parameters. Parameter estimation is a major issue because it depends on the stability analysis of a chaotic system, and communication systems that are based on chaos make it difficult to give accurate estimates or a fast rate of convergence. Several nature-inspired metaheuristic algorithms have been used to estimate chaotic sys… Show more

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Cited by 9 publications
(4 citation statements)
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“…As can be seen from Table 4 , the EO-GRNN performs the best, while the POS-GRNN and the FOA-GRNN have essentially the same accuracy, which can also be reflected in the absorption coefficient plot. This situation may be because PSO and FOA choose a fixed step size for exploration during optimization [ 41 ]. At the same time, EO updates the current search parameters at each iteration during optimization and compares the target values among the five candidate concentrations to avoid falling into a local optimum solution.…”
Section: Resultsmentioning
confidence: 99%
“…As can be seen from Table 4 , the EO-GRNN performs the best, while the POS-GRNN and the FOA-GRNN have essentially the same accuracy, which can also be reflected in the absorption coefficient plot. This situation may be because PSO and FOA choose a fixed step size for exploration during optimization [ 41 ]. At the same time, EO updates the current search parameters at each iteration during optimization and compares the target values among the five candidate concentrations to avoid falling into a local optimum solution.…”
Section: Resultsmentioning
confidence: 99%
“…The Lorenz attractor was introduced by Edward Lorenz [67] for modeling the phenomenon of thermal convection in fluids. Mathematically, the Lorenz attractor is described by a three-dimensional system of ordinary differential equations, as follows [68]. In Equation (15), N LM is the number of chaotic numbers generated by the logistic map.…”
Section: Lorenz Attractormentioning
confidence: 99%
“…γ, ρ, and δ are the Lorenz attractor parameters. Typical values of these constants are as follows [68]. γ = 10, ρ = 28 and δ = 8/3.…”
Section: Lorenz Attractormentioning
confidence: 99%
“…To further verify the validity of the established CEEMDAN-SE-ISSA-MKELM model in CTP forecasting, the single model, including Markov forecasting model (MFM) [37], ARIMA [38], ELM [39], LSSVM [40], LSTM [38], poly kernel ELM (pELM), RBF kernel ELM (rELM), and MKELM (combining poly kernel and RBF kernel), as well as the combined model, including CEEMDAN-MKELM, EMD-MKELM [41], CEEMD-MKELM [42], CEEMDAN-SE-MKELM, EMD-SE-MKELM, CEEMD-SE-MKELM, CEEMDAN-SE-FOA-MKELM [43], CEEMDAN-SE-PSO-MKELM [44], and CEEMDAN-SE-SSA-MKELM, are selected as the comparison model. The values of MAPE, RMSE, and R2 for the forecasted results in Guangdong's carbon market are illustrated in Figure 6.…”
Section: Comparison Analysismentioning
confidence: 99%