Distribution Network Reconfiguration Using Selective Firefly Algorithm and a Load Flow Analysis Criterion for Reducing the Search Space

Gerez, Cassio; Silva, Lindenberg I.; Belati, Edmarcio Antônio; Filho, Alfeu J. Sguarezi; Costa, Éder Silva

doi:10.1109/access.2019.2918480

Cited by 68 publications

(60 citation statements)

References 49 publications

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“…This algorithm is inspired from the natural courtship signal transfer exhibited by the fireflies wherein a firefly with maximum brightness attracts other fireflies the most regardless of their sex . FAs are proposed to solve optimal DGs allocation problem by minimising active and reactive power losses and improving line loading . Nadhir et al differently used FA for finding optimal sizes and locations of multiple DGs on a balanced radial network aimed at minimising power loss.…”

Section: Optimisation Algorithms For Dg Allocation Planningmentioning

confidence: 99%

“…217 FAs are proposed to solve optimal DGs allocation problem by minimising active and reactive power losses and improving line loading. 218,219 Nadhir et al 220,221 differently used FA for finding optimal sizes and locations of multiple DGs on a balanced radial network aimed at minimising power loss. Othman et al 222 modified the traditional FA to efficiently solve constrained optimisation problems.…”

Section: Firefly Algorithmmentioning

confidence: 99%

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Towards maximising the integration of renewable energy hybrid distributed generations for small signal stability enhancement: A review

2020

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Summary Integrating renewable energy hybrid distributed generation (REHDG) into distribution network systems (DNSs) has become increasingly important because of various technical, economic, and environmental advantages accruing from it. However, the output power of REHDGs from photovoltaic (PV) and wind is highly variable because of its dependency on intermittent parameters such as solar irradiance, temperature, and wind speed. Such variability of generated power from large‐scale REHDGs or load introduces small signal instabilities (oscillations). Meanwhile, different locations of integration and sizes of REHDGs in the DNS affect the system oscillation modes by either improving or depriving the small‐signal stability (SSS) of the network. Consequently, a significant number of research has been conducted on the planning of optimal allocation of REHDGs in DNS. In this regard, this paper reviews the existing planning models, optimisation techniques, and resources' uncertainty modelling employed in REHDGs allocations in terms of their capability in obtaining optimal solutions and enhancing SSS of the system. Planning models with optimisation algorithms are evaluated for modelling renewable resource uncertainties and curtailing SSS variables. Research works on planning of optimal allocation of these generations attain minimum cost, but were unable to satisfy the SSS requirements of the system. The existing models for the planning and design of optimal timing, sizing, and placement of REHDGs will need to be improved to optimally allocate REHDGs and satisfy the SSS of the DNS after the integration.

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Section: Optimisation Algorithms For Dg Allocation Planningmentioning

confidence: 99%

Section: Firefly Algorithmmentioning

confidence: 99%

Towards maximising the integration of renewable energy hybrid distributed generations for small signal stability enhancement: A review

2020

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“…These may result in significant power losses in distribution systems, which may cost electric utilities millions of dollars per day. Not only that, but also poor service quality may cause severe damage to many modern electrical devices due to its sensitivity to voltage variations [4]. In such stressed circumstances, the distribution systems planners and operators must face such challenges and provide quantitative as well as qualitative power service to satisfy consumers' satisfaction and reduce dissipated energy.…”

Section: Introductionmentioning

confidence: 99%

“…A number of meta-heuristic techniques has been introduced in literatures such as; one rank cuckoo search algorithm [27], which is formulated with multi-objectives of power loss minimization, voltage deviation minimization and voltage stability improvement; grey wolf optimizer [28]; stochastic fractal search algorithm [29]; particle swarm optimization [7]; multi-objective chaotic differential evolution [30]. As well, numerous meta-heuristic techniques have been introduced for DNR to enhance the distribution system performance such as; fireworks algorithm [31]; cuckoo search algorithm [32]; genetic algorithm with varying population [33], [34]; harmony search algorithm [6]; selective firefly algorithm [4]. Combining CBs, DGs and DNR with each other greatly improves the performance of distribution systems, but in return the number of control variables is increased, which increases the complexity of this problem.…”

Section: Introductionmentioning

confidence: 99%

Optimal Control and Operation of Fully Automated Distribution Networks Using Improved Tunicate Swarm Intelligent Algorithm

Fetouh

Elsayed

2020

IEEE Access

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Simultaneous control and operation of Capacitor Banks (CBs) and Distributed Generators (DGs) with Distribution Network Reconfiguration (DNR) is the most important modern trend for distribution systems performance enhancement. The complexity and variety of the control variables of this problem represent a challenge for distribution systems planners and operators as well as interested researchers. Optimal solution can provides quantitative as well as qualitative power service to satisfy consumers' satisfaction and reduces dissipated energy. Furthermore, performance enhancement of distribution systems is very vital where improving their performance directly affects the performance of transmission and generation systems. For solving the considered problem, an improved Tunicate Swarm Algorithm (ITSA), which imitates the swarming behaviors of the marine tunicates and their jet propulsions during its navigation and foraging procedure, is proposed. In ITSA, Lévy flight distributions are emerged in the traditional Tunicate Swarm Algorithm (TSA), which improves the diversification searching abilities of the TSA and consequently avoids the stagnation possibilities. The proposed ITSA is applied and tested for optimal DNR simultaneously with optimal control of the switched CBs and dispatchable DGs taking into account daily load variations. The ITSA is compared with other techniques on the standard 33-bus, 69-bus and the large-scale 119-bus distribution systems considering different automation scenarios of the distribution systems. The simulation results reveal that significant enhancement in distribution system performance is obtained through the application of the proposed automation process using the ITSA. ITSA can efficiently search for the optimal solutions of the problem and outperforms the other existing algorithms in the literatures.

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“…Intelligent search (IS) based methods are differently employed to solve the optimal sizing and placement of DGs problems. IS methods utilize artificial intelligence (AI) algorithms like the genetic algorithm (GA) [21,22], particle swarm optimization (PSO) [23,24], simulated annealing (SA) [25][26][27], harmony search (HS) [28,29], big bang crunch (BBC) [30,31], the fireworks algorithm (FA) [32,33], and the water drop algorithm (WDA) [34,35].…”

Section: Introductionmentioning

confidence: 99%

Optimal Allocation of Renewable Energy Hybrid Distributed Generations for Small-Signal Stability Enhancement

2019

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This paper solves the allocation planning problem of integrating large scale renewable energy hybrid distributed generations and capacitor banks into the distribution systems. Extraordinarily, the integration of renewable energy hybrid distributed generations such as solar photovoltaic, wind, and biomass takes into consideration the impact assessment of variable generations from PV and wind on the distribution networks’ long term dynamic voltage and small-signal stabilities. Unlike other renewable distributed generations, the variability of power from solar PV and wind generations causes small-signal instabilities if they are sub-optimally allocated in the distribution network. Hence, the variables related to small-signal stability are included and constrained in the model, unlike what is obtainable in the current works on the planning of optimal allocation of renewable distributed generations. Thus, the model is motivated to maximize the penetration of renewable powers by minimizing the net present value of total cost, which includes investment, maintenance, energy, and emission costs. Consequently, the optimization problem is formulated as a stochastic mixed integer linear program, which ensures limited convergence to optimality. Numerical results of the proposed model demonstrate a significant reduction in electricity and emission costs, enhancement of system dynamic voltage and small-signal stabilities, as well as improvement in welfare costs and environmental goodness.

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Distribution Network Reconfiguration Using Selective Firefly Algorithm and a Load Flow Analysis Criterion for Reducing the Search Space

Cited by 68 publications

References 49 publications

Towards maximising the integration of renewable energy hybrid distributed generations for small signal stability enhancement: A review

Towards maximising the integration of renewable energy hybrid distributed generations for small signal stability enhancement: A review

Optimal Control and Operation of Fully Automated Distribution Networks Using Improved Tunicate Swarm Intelligent Algorithm

Optimal Allocation of Renewable Energy Hybrid Distributed Generations for Small-Signal Stability Enhancement

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