TL;DR
LRT-NG introduces a novel, more accurate method for computing reachtubes in nonlinear dynamical systems, combining new metrics and intersection techniques to improve over previous approaches.
Contribution
It presents a new set of techniques and a toolset that significantly enhance the accuracy and efficiency of reachtube computation for nonlinear systems, surpassing prior methods.
Findings
LRT-NG produces tighter reachtubes than LRT, CAPD, and Flow*.
It effectively handles Neural ODE benchmarks.
The tool is standalone with an improved user interface.
Abstract
We introduce LRT-NG, a set of techniques and an associated toolset that computes a reachtube (an over-approximation of the set of reachable states over a given time horizon) of a nonlinear dynamical system. LRT-NG significantly advances the state-of-the-art Langrangian Reachability and its associated tool LRT. From a theoretical perspective, LRT-NG is superior to LRT in three ways. First, it uses for the first time an analytically computed metric for the propagated ball which is proven to minimize the ball's volume. We emphasize that the metric computation is the centerpiece of all bloating-based techniques. Secondly, it computes the next reachset as the intersection of two balls: one based on the Cartesian metric and the other on the new metric. While the two metrics were previously considered opposing approaches, their joint use considerably tightens the reachtubes. Thirdly, it avoids…
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