Modern nonlinear control theory seeks to endow systems with properties of stability and safety, and have been deployed successfully in multiple domains. Despite this success, model uncertainty remains a significant challenge in synthesizing safe controllers, leading to degradation in the properties provided by the controllers. This paper develops a machine learning framework utilizing Control Barrier Functions (CBFs) to reduce model uncertainty as it impact the safe behavior of a system. This approach iteratively collects data and updates a controller, ultimately achieving safe behavior. We validate this method in simulation and experimentally on a Segway platform
The ability to learn and execute optimal control policies safely is critical to the realization of c...
We propose new methods to synthesize control barrier function (CBF)-based safe controllers that avoi...
Safe reinforcement learning (RL) with assured satisfaction of hard state constraints during training...
Modern nonlinear control theory seeks to endow systems with properties of stability and safety, and ...
Modern nonlinear control theory seeks to develop feedback controllers that endow systems with proper...
Reinforcement Learning (RL) algorithms have found limited success beyond simulated applications, and...
The increasing impact of data-driven technologies across various industries has sparked renewed inte...
In this letter we seek to quantify the ability of learning to improve safety guarantees endowed by C...
Real-world autonomous systems are often controlled using conventional model-based control methods. B...
Safety is an important aim in designing safe-critical systems. To design such systems, many policy i...
Correct-by-construction techniques, such as control barrier functions (CBFs), can be used to guarant...
The problem of safely learning and controlling a dynamical system - i.e., of stabilizing an original...
This paper develops a model-based reinforcement learning (MBRL) framework for learning online the va...
Control design for nonlinear dynamical systems is an essential field of study in a world growing eve...
Control barrier functions (CBF) are widely used in safety-critical controllers. However, the constru...
The ability to learn and execute optimal control policies safely is critical to the realization of c...
We propose new methods to synthesize control barrier function (CBF)-based safe controllers that avoi...
Safe reinforcement learning (RL) with assured satisfaction of hard state constraints during training...
Modern nonlinear control theory seeks to endow systems with properties of stability and safety, and ...
Modern nonlinear control theory seeks to develop feedback controllers that endow systems with proper...
Reinforcement Learning (RL) algorithms have found limited success beyond simulated applications, and...
The increasing impact of data-driven technologies across various industries has sparked renewed inte...
In this letter we seek to quantify the ability of learning to improve safety guarantees endowed by C...
Real-world autonomous systems are often controlled using conventional model-based control methods. B...
Safety is an important aim in designing safe-critical systems. To design such systems, many policy i...
Correct-by-construction techniques, such as control barrier functions (CBFs), can be used to guarant...
The problem of safely learning and controlling a dynamical system - i.e., of stabilizing an original...
This paper develops a model-based reinforcement learning (MBRL) framework for learning online the va...
Control design for nonlinear dynamical systems is an essential field of study in a world growing eve...
Control barrier functions (CBF) are widely used in safety-critical controllers. However, the constru...
The ability to learn and execute optimal control policies safely is critical to the realization of c...
We propose new methods to synthesize control barrier function (CBF)-based safe controllers that avoi...
Safe reinforcement learning (RL) with assured satisfaction of hard state constraints during training...