We propose a novel Branch-and-Bound method for reachability analysis of neural networks in both open-loop and closed-loop settings. Our idea is to first compute accurate bounds on the Lipschitz constant of the neural network in certain directions of interest offline using a convex program. We then use these bounds to obtain an instantaneous but conservative polyhedral approximation of the reachable set using Lipschitz continuity arguments. To reduce conservatism, we incorporate our bounding algorithm within a branching strategy to decrease the over-approximation error within an arbitrary accuracy. We then extend our method to reachability analysis of control systems with neural network controllers. Finally, to capture the shape of the reach...
In this paper, we consider the computational complexity of bounding the reachable set of a Linear Ti...
Hybrid zonotopes generalize constrained zonotopes by introducing additional binary variables and pos...
We present POLAR (The source code can be found at https://github.com/ChaoHuang2018/POLAR_Tool. The f...
Applying neural networks as controllers in dynamical systems has shown great promises. However, it i...
Neural network controllers (NNCs) have shown great promise in autonomous and cyber-physical systems....
Safety certification of data-driven control techniques remains a major open problem. This work inves...
This is the final version. Available from IJCAI via the DOI in this recordVerifying correctness of d...
This paper presents a new reachability analysis approach to compute interval over-approximations of ...
In this paper, we present a data-driven framework for real-time estimation of reachable sets for con...
Verifying correctness of deep neural networks (DNNs) is challenging. We study a generic reachability...
International audienceA forward reachability analysis method for the safety verification of nonlinea...
The increasing prevalence of neural networks (NNs) in safety-critical applications calls for methods...
We investigate the complexity of the reachability problem for (deep) neuralnetworks: does it compute...
We develop a novel model for studying agent-environment systems, where the agents are implemented vi...
As neural networks (NNs) become more prevalent in safety-critical applications such as control of ve...
In this paper, we consider the computational complexity of bounding the reachable set of a Linear Ti...
Hybrid zonotopes generalize constrained zonotopes by introducing additional binary variables and pos...
We present POLAR (The source code can be found at https://github.com/ChaoHuang2018/POLAR_Tool. The f...
Applying neural networks as controllers in dynamical systems has shown great promises. However, it i...
Neural network controllers (NNCs) have shown great promise in autonomous and cyber-physical systems....
Safety certification of data-driven control techniques remains a major open problem. This work inves...
This is the final version. Available from IJCAI via the DOI in this recordVerifying correctness of d...
This paper presents a new reachability analysis approach to compute interval over-approximations of ...
In this paper, we present a data-driven framework for real-time estimation of reachable sets for con...
Verifying correctness of deep neural networks (DNNs) is challenging. We study a generic reachability...
International audienceA forward reachability analysis method for the safety verification of nonlinea...
The increasing prevalence of neural networks (NNs) in safety-critical applications calls for methods...
We investigate the complexity of the reachability problem for (deep) neuralnetworks: does it compute...
We develop a novel model for studying agent-environment systems, where the agents are implemented vi...
As neural networks (NNs) become more prevalent in safety-critical applications such as control of ve...
In this paper, we consider the computational complexity of bounding the reachable set of a Linear Ti...
Hybrid zonotopes generalize constrained zonotopes by introducing additional binary variables and pos...
We present POLAR (The source code can be found at https://github.com/ChaoHuang2018/POLAR_Tool. The f...