A novel multi-objective approach based on improved electromagnetism-like algorithm to solve optimal power flow problem considering the detailed model of thermal generators

Jeddi, Babak; Einaddin, Alireza Hatefi; Kazemzadeh, Rasool

doi:10.1002/etep.2293

Cited by 14 publications

(9 citation statements)

References 63 publications

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“…Table 3 presents a comparison of the outcomes obtained from minimizing the FC of Sc. 1 in relation to various other optimization approaches, which are the Black-Hole-Based Optimizing Method (BHBOM) [40], DE versions [52], Symbiotic Organisms Search (SOS) [60], Crow Search Optimization (CSO) [61], Modified CSO (MCSO) [62], Improved Moth-Flame Optimization (IMFO) [63], Developed Grey Wolf Optimization (GWO) [64], Improved Electromagnetism-like Optimization Algorithm (IEOA) [65], Moth Swarm Algorithm (MSA) [66], Ensemble Constraint Handling Technique with DE (ECHT-DE) [67], Evolutionary Algorithm (EA) [68], Grasshopper Optimizer (GO) [69], Genetic Algorithm (GA) [70], Differential Harmony Search Approach (DHSA) [71], Imperialist Competitive Approach (ICA) [72], Teaching-Learning Algorithm (TLA) [73], Novel Bat Optimization (NBO) [74], and adapted GA [75]. As can be illustrated from Table 3, the proposed IKOT obtained the minimum FC among the original KOT and other approaches.…”

Section: Results Of Ieee 30 Bus Systemmentioning

confidence: 99%

“…FCs (USD/h) Method FCs (USD/h) Proposed IKOT 799.0824 IMFO [63] 800.3848 KOT 799.0835 SOS [60] 801.5733 MSA [66] 800.5099 ICA [72] 801.843 NBO [74] 799.7516 CSO [61] 799.8266 Developed GWO [64] 800.433 TLA [73] 800.4212 GO [69] 800.9728 Adaptive GO [69] 800.0212 JFS [76] 799.1065 ECHT-DE [67] 800.4148 Improved EOA [65] 799.688 DHSA [40] 802.2966 MCSO [62] 799.3332 GA [70] 802.1962 BHBOA [40] 799.9217 Adaptive constraint DE [77] 800.4113 pbest-DE [52] 800.4115 Self-adaptive penalty-DE [52] 800.4293 Ensemble constraint handling-DE [52] 800.4148 Self-adaptive feasibility-DE [52] 800.4131…”

Section: Methodsmentioning

confidence: 99%

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Enhanced Kepler Optimization Method for Nonlinear Multi-Dimensional Optimal Power Flow

Alqahtani,

Almutairi,

Shaheen

et al. 2024

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Multi-Dimensional Optimal Power Flow (MDOPF) is a fundamental task in power systems engineering aimed at optimizing the operation of electrical networks while considering various constraints such as power generation, transmission, and distribution. The mathematical model of MDOPF involves formulating it as a non-linear, non-convex optimization problem aimed at minimizing specific objective functions while adhering to equality and inequality constraints. The objective function typically includes terms representing the Fuel Cost (FC), Entire Network Losses (ENL), and Entire Emissions (EE), while the constraints encompass power balance equations, generator operating limits, and network constraints, such as line flow limits and voltage limits. This paper presents an innovative Improved Kepler Optimization Technique (IKOT) for solving MDOPF problems. The IKOT builds upon the traditional KOT and incorporates enhanced local escaping mechanisms to overcome local optima traps and improve convergence speed. The mathematical model of the IKOT algorithm involves defining a population of candidate solutions (individuals) represented as vectors in a high-dimensional search space. Each individual corresponds to a potential solution to the MDOPF problem, and the algorithm iteratively refines these solutions to converge towards the optimal solution. The key innovation of the IKOT lies in its enhanced local escaping mechanisms, which enable it to explore the search space more effectively and avoid premature convergence to suboptimal solutions. Experimental results on standard IEEE test systems demonstrate the effectiveness of the proposed IKOT in solving MDOPF problems. The proposed IKOT obtained the FC, EE, and ENL of USD 41,666.963/h, 1.039 Ton/h, and 9.087 MW, respectively, in comparison with the KOT, which achieved USD 41,677.349/h, 1.048 Ton/h, 11.277 MW, respectively. In comparison to the base scenario, the IKOT achieved a reduction percentage of 18.85%, 58.89%, and 64.13%, respectively, for the three scenarios. The IKOT consistently outperformed the original KOT and other state-of-the-art metaheuristic optimization algorithms in terms of solution quality, convergence speed, and robustness.

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Section: Results Of Ieee 30 Bus Systemmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Enhanced Kepler Optimization Method for Nonlinear Multi-Dimensional Optimal Power Flow

Alqahtani,

Almutairi,

Shaheen

et al. 2024

Axioms

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show abstract

“…pf to be within their bounds during the optimization process. For constraints (11), ( 12), ( 15) and ( 16), the penalty function approach is used to transform the constrained problem into an unconstrained one [53,54]. In this approach, a simple way to penalize infeasible solutions is to apply a constant penalty, consists of a penalty parameter multiplied by a measure of violation of the constraints, to those solutions that violate feasibility in any way.…”

Section: Dg Umentioning

confidence: 99%

“…This means that fewer iterations are required for the proposed algorithm, and therefore it is faster than the original one. Moreover, in order to compare the solution quality and robustness of the CHSFA with that of the HSA, deviation of the best and worst solutions from the corresponding average result are calculated by the following equations [53]:…”

Section: The Deterministic Der Planning Problemmentioning

confidence: 99%

Robust optimization framework for dynamic distributed energy resources planning in distribution networks

Jeddi

Vahidinasab

Ramezanpour

et al. 2019

International Journal of Electrical Power & Energy Systems

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This study relies on a dynamic reliability-based model for distributed energy resources (DER) planning in electric energy distribution networks (EEDN) with the aim of maximizing the profit of EEDN companies by increasing income and reducing costs. Load uncertainty is considered in the proposed planning model and the robust optimization (RO) approach is employed to cope with the uncertainty. The developed methodology is illustrated using real-world voltage-dependent load models, including residential, commercial and industrial types. These load models are used in evaluating the reliability cost and energy selling for customers. The reliability cost is calculated based on the total unsupplied load after an outage. Furthermore, a new modified harmony search algorithm is proposed to solve the formulated robust dynamic DER planning problem. The solution of the proposed optimization model provides the size, location, and power factor of DER. Furthermore, the need for transformers or lines upgrades and the best year for DER installation are other decision variables determined by the model. The effectiveness and capability of the developed model have been demonstrated with the aid of a case study based on a typical EEDN. The obtained results indicate that installing DER in EEDNs can relieve congestion on feeders; therefore, it can mitigate or defer upgrade investment. Moreover, if carefully planned, other benefits of DER integration such as reliability improvement and energy loss reduction can be achieved.

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“…Instead, a set of Pareto solutions can be found. None of the solutions dominates others and each of them is a compromise between the two competing objectives [16].…”

Section: Multiobjective Formulationmentioning

confidence: 99%

Multiobjective Home Appliances Scheduling Considering Customer Thermal Discomfort: A Multistep Look-ahead ADP-Based Approach

Jeddi

Mishra

Ledwich

2019

2019 IEEE Milan PowerTech

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This paper proposes a multiobjective home energy management unit (MO-HEMU) to balance the electricity payment and thermal discomfort of a household by properly scheduling devices in a time-varying price environment. The thermal discomfort is measured by the deviation of indoor and hot water temperature from the user's ideal temperature. The home devices include solar Photovoltaics, a battery storage system, deferrable, and thermal appliances. The proposed MO-HEMU is formulated as a dynamic program and a method based on the approximated dynamic programming is used as the scheduling algorithm. The developed method, called multistep look-ahead algorithm, is an iterative algorithm that overcomes the curse of dimensionality of the exact DP by choosing a decision based on a limited number of stages ahead. The effectiveness of the proposed model is investigated through numerical simulations. The proposed MO-HEMU enables customers to find the desired trade-off between electricity payment and a discomfort level.Index Terms--Appliances scheduling, approximate dynamic programming, home energy management, multiobjective optimization, thermal discomfort.I.

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A novel multi-objective approach based on improved electromagnetism-like algorithm to solve optimal power flow problem considering the detailed model of thermal generators

Cited by 14 publications

References 63 publications

Enhanced Kepler Optimization Method for Nonlinear Multi-Dimensional Optimal Power Flow

Enhanced Kepler Optimization Method for Nonlinear Multi-Dimensional Optimal Power Flow

Robust optimization framework for dynamic distributed energy resources planning in distribution networks

Multiobjective Home Appliances Scheduling Considering Customer Thermal Discomfort: A Multistep Look-ahead ADP-Based Approach

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