A flexible and differentiable coil proxy for stellarator equilibrium optimization
Abstract: Balancing plasma performance and coil cost is a significant challenge when designing a stellarator power plant. Most present stellarator designs are produced by two-stage optimization: the first for the equilibrium and the second for a coil design reproducing its magnetic configuration. It is challenging to find a compromise between plasma and coils with this approach. In recent years, single-stage approaches have gained popularity, which attempt to optimize both the plasma and coils simultaneously to improve the plasma-coil balance. In exchange, it can substantially increase the problem's dimensionality and introduce the ill-posedness of filamentary coil optimization to equilibrium optimization. This paper introduces a new ``quasi-single-stage'' method representing a flexible and differentiable coil proxy that directly predicts coil complexity during equilibrium optimization. The proxy is based on the adjoint differentiation of a winding surface coil subproblem. Our proxy can balance coil and plasma performance without introducing new degrees of freedom or ill-posedness. We present initial numerical results that demonstrate the proxy's effectiveness for single-stage optimization.
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