Power Quality 24 h Verification in Smart Load Scheduling Based on Differentiate, Deep, and Assembly Statistics in NWP Processing
Detachable smart systems contingent on unsteady renewable energy (RE) require timely planning and control in power demand and storage on daily scheduling. Power quality (PQ) denotes the fault-free operation of the grids in various modes of household use. The great variability in detached system stat...
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Wiley
2025-01-01
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| Series: | International Transactions on Electrical Energy Systems |
| Online Access: | http://dx.doi.org/10.1155/etep/8703225 |
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| author | Ladislav Zjavka |
| author_facet | Ladislav Zjavka |
| author_sort | Ladislav Zjavka |
| collection | DOAJ |
| description | Detachable smart systems contingent on unsteady renewable energy (RE) require timely planning and control in power demand and storage on daily scheduling. Power quality (PQ) denotes the fault-free operation of the grids in various modes of household use. The great variability in detached system states and exponential increase in combinatorial load under uncertain environment make optimisation difficulties. Statistical artificial intelligence (AI) helps model the characteristics of undefined systems in local atmospheric and terrain uncertainties. Algebraic equations cannot fully define the exact relations between the PQ parameters of the observational data. The RE production and operational conditions primarily determine the first plans of power consumption, which are re-evaluated and optimised secondary to PQ. User needs are accommodated and balanced with daily energy and charge potential in acceptable terms. The main question is the first efficient algorithmising of load scheduling tasks and their consequent day-to-day verification in the proposed two-stage PQ irregularity reveling tool. A new unconventional neurocomputing strategy, called Differential Learning (DfL), allows modelling high dynamical PQ characteristics without behavioural knowledge, considering only input-output data. The DfL results were evaluated with deep and stochastic learning. After an initial preprocessing of the training series, the detected weather and binary-coded load combination time interval samples are used in the training. AI statistics allow processing entire 24 h forecast series, replacing related real-valued quantities available in learning stage, to compute final PQ targets at the corresponding prediction times. Parametric C++ software including measured system and environment observation data is accessible in public data archives to allow for additional experimental comparisons and investigation. |
| format | Article |
| id | doaj-art-e800cc715fa040ae9399644d194ae064 |
| institution | DOAJ |
| issn | 2050-7038 |
| language | English |
| publishDate | 2025-01-01 |
| publisher | Wiley |
| record_format | Article |
| series | International Transactions on Electrical Energy Systems |
| spelling | doaj-art-e800cc715fa040ae9399644d194ae0642025-08-20T03:15:47ZengWileyInternational Transactions on Electrical Energy Systems2050-70382025-01-01202510.1155/etep/8703225Power Quality 24 h Verification in Smart Load Scheduling Based on Differentiate, Deep, and Assembly Statistics in NWP ProcessingLadislav Zjavka0Department of Computer ScienceDetachable smart systems contingent on unsteady renewable energy (RE) require timely planning and control in power demand and storage on daily scheduling. Power quality (PQ) denotes the fault-free operation of the grids in various modes of household use. The great variability in detached system states and exponential increase in combinatorial load under uncertain environment make optimisation difficulties. Statistical artificial intelligence (AI) helps model the characteristics of undefined systems in local atmospheric and terrain uncertainties. Algebraic equations cannot fully define the exact relations between the PQ parameters of the observational data. The RE production and operational conditions primarily determine the first plans of power consumption, which are re-evaluated and optimised secondary to PQ. User needs are accommodated and balanced with daily energy and charge potential in acceptable terms. The main question is the first efficient algorithmising of load scheduling tasks and their consequent day-to-day verification in the proposed two-stage PQ irregularity reveling tool. A new unconventional neurocomputing strategy, called Differential Learning (DfL), allows modelling high dynamical PQ characteristics without behavioural knowledge, considering only input-output data. The DfL results were evaluated with deep and stochastic learning. After an initial preprocessing of the training series, the detected weather and binary-coded load combination time interval samples are used in the training. AI statistics allow processing entire 24 h forecast series, replacing related real-valued quantities available in learning stage, to compute final PQ targets at the corresponding prediction times. Parametric C++ software including measured system and environment observation data is accessible in public data archives to allow for additional experimental comparisons and investigation.http://dx.doi.org/10.1155/etep/8703225 |
| spellingShingle | Ladislav Zjavka Power Quality 24 h Verification in Smart Load Scheduling Based on Differentiate, Deep, and Assembly Statistics in NWP Processing International Transactions on Electrical Energy Systems |
| title | Power Quality 24 h Verification in Smart Load Scheduling Based on Differentiate, Deep, and Assembly Statistics in NWP Processing |
| title_full | Power Quality 24 h Verification in Smart Load Scheduling Based on Differentiate, Deep, and Assembly Statistics in NWP Processing |
| title_fullStr | Power Quality 24 h Verification in Smart Load Scheduling Based on Differentiate, Deep, and Assembly Statistics in NWP Processing |
| title_full_unstemmed | Power Quality 24 h Verification in Smart Load Scheduling Based on Differentiate, Deep, and Assembly Statistics in NWP Processing |
| title_short | Power Quality 24 h Verification in Smart Load Scheduling Based on Differentiate, Deep, and Assembly Statistics in NWP Processing |
| title_sort | power quality 24 h verification in smart load scheduling based on differentiate deep and assembly statistics in nwp processing |
| url | http://dx.doi.org/10.1155/etep/8703225 |
| work_keys_str_mv | AT ladislavzjavka powerquality24hverificationinsmartloadschedulingbasedondifferentiatedeepandassemblystatisticsinnwpprocessing |