Prescribed robustness in optimal power flow

Robert Mieth; H. Vincent Poor

doi:10.1016/j.epsr.2024.110704

Prescribed robustness in optimal power flow

Robert Mieth, H. Vincent Poor

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

For a timely decarbonization of our economy, power systems need to accommodate increasing numbers of clean but stochastic resources. This requires new operational methods that internalize this stochasticity to ensure safety and efficiency. This paper proposes a novel approach to compute adaptive safety intervals for each stochastic resource that internalize power flow physics and optimize the expected cost of system operations, making them “prescriptive”. The resulting intervals are interpretable and can be used in a tractable robust optimal power flow problem as uncertainty sets. We use stochastic gradient descent with differentiable optimization layers to compute a mapping that obtains these intervals from a given vector of context parameters that captures the expected system state. We demonstrate and discuss the proposed approach on two case studies.

Original language	English (US)
Article number	110704
Journal	Electric Power Systems Research
Volume	235
DOIs	https://doi.org/10.1016/j.epsr.2024.110704
State	Published - Oct 2024
Externally published	Yes

All Science Journal Classification (ASJC) codes

Energy Engineering and Power Technology
Electrical and Electronic Engineering

Keywords

Differentiable optimization
Optimal power flow
Prescriptive analytics
Robust optimization
Stochastic optimization

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10.1016/j.epsr.2024.110704

Cite this

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title = "Prescribed robustness in optimal power flow",

abstract = "For a timely decarbonization of our economy, power systems need to accommodate increasing numbers of clean but stochastic resources. This requires new operational methods that internalize this stochasticity to ensure safety and efficiency. This paper proposes a novel approach to compute adaptive safety intervals for each stochastic resource that internalize power flow physics and optimize the expected cost of system operations, making them “prescriptive”. The resulting intervals are interpretable and can be used in a tractable robust optimal power flow problem as uncertainty sets. We use stochastic gradient descent with differentiable optimization layers to compute a mapping that obtains these intervals from a given vector of context parameters that captures the expected system state. We demonstrate and discuss the proposed approach on two case studies.",

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AU - Mieth, Robert

AU - Poor, H. Vincent

PY - 2024/10

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N2 - For a timely decarbonization of our economy, power systems need to accommodate increasing numbers of clean but stochastic resources. This requires new operational methods that internalize this stochasticity to ensure safety and efficiency. This paper proposes a novel approach to compute adaptive safety intervals for each stochastic resource that internalize power flow physics and optimize the expected cost of system operations, making them “prescriptive”. The resulting intervals are interpretable and can be used in a tractable robust optimal power flow problem as uncertainty sets. We use stochastic gradient descent with differentiable optimization layers to compute a mapping that obtains these intervals from a given vector of context parameters that captures the expected system state. We demonstrate and discuss the proposed approach on two case studies.

AB - For a timely decarbonization of our economy, power systems need to accommodate increasing numbers of clean but stochastic resources. This requires new operational methods that internalize this stochasticity to ensure safety and efficiency. This paper proposes a novel approach to compute adaptive safety intervals for each stochastic resource that internalize power flow physics and optimize the expected cost of system operations, making them “prescriptive”. The resulting intervals are interpretable and can be used in a tractable robust optimal power flow problem as uncertainty sets. We use stochastic gradient descent with differentiable optimization layers to compute a mapping that obtains these intervals from a given vector of context parameters that captures the expected system state. We demonstrate and discuss the proposed approach on two case studies.

KW - Differentiable optimization

KW - Optimal power flow

KW - Prescriptive analytics

KW - Robust optimization

KW - Stochastic optimization

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JO - Electric Power Systems Research

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ER -

Prescribed robustness in optimal power flow

Abstract

All Science Journal Classification (ASJC) codes

Keywords

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