Transmission Expansion Planning using a Highly Accurate AC Optimal Power Flow Approximation

The objective of transmission network expansion planning is to find the optimal strategy that balances the investment and the operating costs, considering all generation and transmission constraints. Attempts to address this problem in a tractable manner have led researchers to develop different con...

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Bibliographic Details
Published in:2021 International Conference on Smart Energy Systems and Technologies (SEST) pp. 1 - 6
Main Authors: Heide, Otto, Sepetanc, Karlo, Pandzic, Hrvoje
Format: Conference Proceeding
Language:English
Published: IEEE 06.09.2021
Subjects:
Computational modeling
Costs
mixed-integer quadratically constrained quadratic program
Optimal power flow approximation
Planning
Power grids
Renewable energy sources
Taylor series
transmission expansion planning
Voltage
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Summary:The objective of transmission network expansion planning is to find the optimal strategy that balances the investment and the operating costs, considering all generation and transmission constraints. Attempts to address this problem in a tractable manner have led researchers to develop different convex relaxations and approximations. Due to the constant power grid evolution, new and improved approximation models are required to successfully handle the upcoming challenges. In this paper, we present a comprehensive approach to handle this highly complex problem both tractably and accurately. The model is based on a convex polar second-order Taylor expansion approximation of the AC power flows where both the voltage magnitudes and angles are quadratically constrained. The proposed approach achieves high accuracy due to the elimination of constraint relaxation errors, as determined by the presolve, which can occur due to the convexification process. The model demonstrated superior accuracy and similar computation times as the existing approximation models. In comparison to the exact formulations, our model shows similar accuracy while improving the computation time.
DOI:10.1109/SEST50973.2021.9543431