We consider the problem of learning the dynamics of autonomous linear systems (i.e., systems that are not affected by external control inputs) from observations of multiple trajectories of those systems, with finite sample guarantees. Existing results on learning rate and consistency of autonomous linear system identification rely on observations of steady state behaviors from a single long trajectory, and are not applicable to unstable systems. In contrast, we consider the scenario of learning system dynamics based on multiple short trajectories, where there are no easily observed steady state behaviors. We provide a finite sample analysis, which shows that the dynamics can be learned at a rate $\mathcal{O}(\frac{1}{\sqrt{N}})$ for both st...
An interlaced method to learn and control nonlinear system dynamics from a set of demonstrations is ...
Linear time-invariant systems are very popular models in system theory and applications. A fundament...
Abstract—This paper presents a methodology for learning arbitrary discrete motions from a set of dem...
The problem of system identification is to learn the system dynamics from data. While classical syst...
We initiate a study of supervised learning from many independent sequences ("trajectories") of non-i...
Despite the recent widespread success of machine learning, we still do not fully understand its fund...
We propose a principled method for projecting an arbitrary square matrix to the non-convex set of as...
We consider a networked linear dynamical system with $p$ agents/nodes. We study the problem of learn...
This work addresses the problem of reference tracking in autonomously learning robots with unknown, ...
Learning algorithms play an ever increasing role in modern engineering solutions. However, despite m...
We consider a class of stochastic dynamical networks whose governing dynamics can be modeled using a...
We extend the methodology in [Yang et al., 2023] to learn autonomous continuous-time dynamical syste...
Learning controllers from data for stabilizing dynamical systems typically follows a two step proces...
Willems et al.'s fundamental lemma asserts that all trajectories of a linear system can be obtained ...
This paper presents a method for learning discrete robot motions from a set of demonstrations. We mo...
An interlaced method to learn and control nonlinear system dynamics from a set of demonstrations is ...
Linear time-invariant systems are very popular models in system theory and applications. A fundament...
Abstract—This paper presents a methodology for learning arbitrary discrete motions from a set of dem...
The problem of system identification is to learn the system dynamics from data. While classical syst...
We initiate a study of supervised learning from many independent sequences ("trajectories") of non-i...
Despite the recent widespread success of machine learning, we still do not fully understand its fund...
We propose a principled method for projecting an arbitrary square matrix to the non-convex set of as...
We consider a networked linear dynamical system with $p$ agents/nodes. We study the problem of learn...
This work addresses the problem of reference tracking in autonomously learning robots with unknown, ...
Learning algorithms play an ever increasing role in modern engineering solutions. However, despite m...
We consider a class of stochastic dynamical networks whose governing dynamics can be modeled using a...
We extend the methodology in [Yang et al., 2023] to learn autonomous continuous-time dynamical syste...
Learning controllers from data for stabilizing dynamical systems typically follows a two step proces...
Willems et al.'s fundamental lemma asserts that all trajectories of a linear system can be obtained ...
This paper presents a method for learning discrete robot motions from a set of demonstrations. We mo...
An interlaced method to learn and control nonlinear system dynamics from a set of demonstrations is ...
Linear time-invariant systems are very popular models in system theory and applications. A fundament...
Abstract—This paper presents a methodology for learning arbitrary discrete motions from a set of dem...