Polynomial Scaling is Possible For Neural Operator Approximations of Structured Families of BSDEs
Abstract
Neural operator (NO) architectures learn nonlinear maps between infinite-dimensional function spaces and are widely used to accelerate simulation and enable data-driven model discovery. While universality results ensure expressivity, they do not address complexity: for broad operator classes described only through regularity (e.g.\ uniform continuity or Cr-regularity), information-theoretic lower bounds imply that minimax-optimal NO approximation rates scale exponentially in the reciprocal accuracy 1/. This has shifted the focus of NO theory toward identifying additional problem-specific structure, beyond regularity, under which suitably tailored NO architectures can leverage to unlock polynomial scaling in 1/. We exhibit the first polynomial-scaling regime for NO approximations of solution operators in stochastic analysis; by identifying structured families of non-Markovian BSDEs with randomized terminal condition parameterized by the Sobolev-regular terminal condition and by Sobolev-regular additive nonlinear perturbations of the generator. We prove that their solution operator can be approximated (uniformly over the family) by a tailored NO whose number of trainable parameters grows polynomially in 1/. We unlock this polynomial scaling regime by informing the NO's inductive bias by factoring out the singular part of the associated semilinear elliptic PDE Green's function and by incorporating the Dol\'eans--Dade exponential of the BSDE's common non-Markovian factor into the NO's decoding layers. As a byproduct, we extend polynomial-scaling guarantees from families of linear elliptic PDEs on regular domains to the semilinear setting.
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