Benjamin Flamm scite author profile

We present an approximate method for solving nonlinear control problems over long time horizons, in which the full nonlinear model is preserved over an initial part of the horizon, while the remainder of the horizon is modeled using a linear relaxation. As this approximate problem may still be too large to solve directly, we present a Benders decomposition-based solution algorithm that iterates between solving the nonlinear and linear parts of the horizon. This extends the Dual Dynamic Programming approach commonly employed for optimization of linearized hydro power systems. We prove that the proposed algorithm converges after a finite number of iterations, even when the nonlinear initial stage problems are solved inexactly. We also bound the suboptimality of the split-horizon method with respect to the original nonlinear problem, in terms of the properties of a map between the linear and nonlinear stateinput trajectories. We then apply this method to a case study concerning a multiple reservoir hydro system, approximating the nonlinear head effects in the second stage using McCormick envelopes. We demonstrate that near-optimal solutions can be obtained in a shrinking horizon setting when the full nonlinear model is used for only a short initial section of the horizon. For this example, the approach is shown to be more practical than both conventional dynamic programming and a multi-cell McCormick envelope approximation from literature.

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Price arbitrage using variable-efficiency energy storage

Flamm

Eichler

Smith

et al. 2019

J. Phys.: Conf. Ser.

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Economic Model Predictive Control of Energy Storage

Flamm¹

2020

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Benjamin Flamm

Electrolyzer modeling and real-time control for optimized production of hydrogen gas

Dual Dynamic Programming for Nonlinear Control Problems over Long Horizons

Two-Stage Dual Dynamic Programming With Application to Nonlinear Hydro Scheduling

Price arbitrage using variable-efficiency energy storage

Economic Model Predictive Control of Energy Storage

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