Minimal Information Control Invariance via Vector Quantization
Ege Yuceel, Teodor Tchalakov, Sayan Mitra
TLDR
This paper introduces a vector-quantized autoencoder to significantly reduce control signal complexity for safety-critical autonomous systems while preserving invariance.
Key contributions
- Formalizes minimal control signals needed for forward invariance using invariance entropy.
- Proposes a vector-quantized autoencoder to learn state partitions and finite control codebooks.
- Develops an iterative forward certification algorithm using Lipschitz enclosures and sum-of-squares.
- Achieves 157x reduction in control codebook size for a quadrotor while maintaining safety.
Why it matters
This work addresses the critical gap between complex learning-based controllers and the minimal information required for safe autonomous systems. By significantly reducing control complexity, it enables more efficient and resource-constrained deployment of safety-critical applications.
Original Abstract
Safety-critical autonomous systems must satisfy hard state constraints under tight computational and sensing budgets, yet learning-based controllers are often far more complex than safe operation requires. To formalize this gap, we study how many distinct control signals are needed to render a compact set forward invariant under sampled-data control, connecting the question to the information-theoretic notion of invariance entropy. We propose a vector-quantized autoencoder that jointly learns a state-space partition and a finite control codebook, and develop an iterative forward certification algorithm that uses Lipschitz-based reachable-set enclosures and sum-of-squares programming. On a 12-dimensional nonlinear quadrotor model, the learned controller achieves a $157\times$ reduction in codebook size over a uniform grid baseline while preserving invariance, and we empirically characterize the minimum sensing resolution compatible with safe operation.
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