Accurate estimation of modern power system harmonics using a novel LSA hybridized recursive least square technique
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Ashok Bhoi
,
Gayadhar Panda
Abstract
This paper purposes a new type of hybrid technique depends on lightning search algorithm (LSA) and recursive least square (RLS) named as LSA-RLS to overcome the harmonic estimation issues in time varying modern power system signals buried with noises. LSA is based on a natural phenomenon of lightning. It consists of three types of projectiles: transition, space and lead projectiles. Transition projectiles create population, space projectiles do the exploration and the lead projectiles do the work of exploitation and find the optimal solution. The basic LSA algorithm is mixed with RLS algorithm in an adaptive way to estimate the states of the harmonic signals. Simulation and validation are made with real time data obtained from a converter fed D.C motor drive. The efficacy of the proposed algorithm is verified by comparing the simulation results of recently reported algorithms such as particle swarm optimization (PSO), differential evolution (DE), bacteria foraging optimization (BFO), gravity search algorithm hybridized recursive least square method (GSA-RLS). It is verified that proposed (LSA-RLS) technique is the best in terms of computational time, convergence, accuracy.
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Author contributions: All the authors have accepted responsibility for the entire content of this submitted manuscript and approved submission.
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Research funding: None declared.
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Conflict of interest statement: The authors declare no conflicts of interest regarding this article.
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© 2021 Walter de Gruyter GmbH, Berlin/Boston
Articles in the same Issue
- Frontmatter
- Research Articles
- Torque ripple minimization of multi-level inverter fed PMSM drive using modified MPTC
- Blockchain insisted resilience enhancement of power electricity markets using distributed energy trading
- A novel Confidential Consortium Blockchain framework for peer to peer energy trading
- Experimental verification of DSTATCOM for various non-linear load
- Grid integration of hybrid renewable energy source using Aligned Multilevel Inverter
- Frequency regulation of wind energy integrated power system using a novel optimized type II fuzzy tilted integral derivative controller
- Power quality improvement using model predictive control based shunt connected custom power device in a single phase system
- A reliable islanding identification mechanism for DC microgrid using PCC transient signal
- Intrinsic time decomposition based differential protection with adaptive threshold for UPFC compensated transmission line
- Advanced energy management and frequency control of distributed microgrid using multi-agent systems
- Accurate estimation of modern power system harmonics using a novel LSA hybridized recursive least square technique
Articles in the same Issue
- Frontmatter
- Research Articles
- Torque ripple minimization of multi-level inverter fed PMSM drive using modified MPTC
- Blockchain insisted resilience enhancement of power electricity markets using distributed energy trading
- A novel Confidential Consortium Blockchain framework for peer to peer energy trading
- Experimental verification of DSTATCOM for various non-linear load
- Grid integration of hybrid renewable energy source using Aligned Multilevel Inverter
- Frequency regulation of wind energy integrated power system using a novel optimized type II fuzzy tilted integral derivative controller
- Power quality improvement using model predictive control based shunt connected custom power device in a single phase system
- A reliable islanding identification mechanism for DC microgrid using PCC transient signal
- Intrinsic time decomposition based differential protection with adaptive threshold for UPFC compensated transmission line
- Advanced energy management and frequency control of distributed microgrid using multi-agent systems
- Accurate estimation of modern power system harmonics using a novel LSA hybridized recursive least square technique
