Gramians for a New Class of Nonlinear Control Systems Using Koopman and a Novel Generalized SVD

Abstract

Certified model reduction for high-dimensional nonlinear control systems remains challenging: unlike balanced truncation for LTI systems, most nonlinear reduction methods either lack computable worst-case error bounds or rely on intractable PDEs. Data-driven Koopman/DMDc surrogates improve tractability, but standard input lifting can distort the physical input-energy metric, so H∞ and Hankel-based bounds computed on the lifted model may be valid only in a lifted-input norm and need not certify the original system. We address this metric mismatch by a Generalized Singular Value Decomposition (GSVD)-based construction that represents general (including non-affine) input nonlinearities in an LTI-like lifted form with a pointwise norm-preserving input map v(x,u) satisfying \|v(x,u)\|2=\|u\|2 and constant matrices A,B. This preserves strict causality (constant B, no input-history augmentation) and yields computable Hankel-singular-value-based H∞ error certificates in the physical input norm for reduced-order surrogates. We illustrate the method on a 25-dimensional Hodgkin--Huxley network with saturating optogenetic actuation, reducing to a single dominant mode while retaining certified error bounds.