Multi-agent system based solution of the optimal reactive power dispatch problem in autonomously operated multi-area systems

Pham, Hoan Van; Ahmed, Sultan N.; Erlich, I.

doi:10.1109/ptc.2015.7232525

Cited by 2 publications

(2 citation statements)

References 16 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…For each of the areas, 24 Ward equivalents related to the 24 periods included in the multi-period analysis were calculated [23]. Communication between areas is performed through a multi-agent approach, which allows communication between each optimizer in each of the areas [42]. Multi-agent master-slave communication was implemented in this work as a system that allows coordination and communication between the different optimization processes involved.…”

Section: Communication Between Each Area Of the Systemmentioning

confidence: 99%

See 1 more Smart Citation

Multi-Area and Multi-Period Optimal Reactive Power Dispatch in Electric Power Systems

Sánchez-Mora,

Villa-Acevedo,

López-Lezama

2023

Energies

View full text Add to dashboard Cite

Factors such as persistent demand growth, expansion project delays, and the rising adoption of renewable energy sources highlight the importance of operating power systems within safe operational margins. The optimal reactive power dispatch (ORPD) seeks to find operating points that allow greater flexibility in reactive power reserves, thus ensuring the safe operation of power systems. The main contribution of this paper is a multi-area and multi-period ORPD (MA-MP-ORPD) model, which seeks the minimization of the voltage deviation in pilot nodes, the reactive power deviation of shunt elements, and the total reactive power generated, all taking into account the operational constraints for each area. The MA-MP-ORPD was implemented in the Python programming language using the Pyomo library; furthermore, the BONMIN solver was employed to solve this mixed-integer nonlinear programming problem. The problem was formulated from the standpoint of the system operator; therefore, it minimizes the variations of critical variables from the desired operative values; furthermore, the number of maneuvers of the reactive compensation elements was also minimized to preserve their lifetimes. The results obtained on IEEE test systems of 39 and 57 buses validated its applicability and effectiveness. The proposed approach allowed obtaining increases in the reactive power reserves of up to 59% and 62% for the 39- and 57-bus test systems, respectively, while ensuring acceptable operation values of the critical variables.

show abstract

Section: Communication Between Each Area Of the Systemmentioning

confidence: 99%

“…are the Ward equivalents in two different areas at time t. If these nodes have equal voltage, there is equivalence between the complete system and each of the areas. This measurement is performed after carrying out the optimization of each of the areas [42].…”

Section: Communication Between Each Area Of the Systemmentioning

confidence: 99%