Flying over the reality gap: From simulated to real indoor airships

Zufferey, Jean-Christophe; Guanella, Alexis; Beyeler, Antoine; Floreano, Dario

doi:10.1007/s10514-006-9718-8

Cited by 67 publications

(38 citation statements)

References 18 publications

(16 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…To obtain a realistic movement of the system a normal distributed noise term was added to the control commands to simulate outer influence like gust of wind. The system dynamics of the blimp were derived based on standard physical aeronautic principles [13] and the parameters were optimized based on a series of trajectories flown with the real blimp. To evaluate the predictive accuracy, we used 500 randomly sampled points and determined the mean squared error (RMS) of the predictive mean of the corresponding GP model relative to the ground truth prediction calculated by the simulator.…”

Section: Resultsmentioning

confidence: 99%

Learning Non-stationary System Dynamics Online Using Gaussian Processes

Rottmann

Burgard

2010

Lecture Notes in Computer Science

View full text Add to dashboard Cite

Abstract. Gaussian processes are a powerful non-parametric framework for solving various regression problems. In this paper, we address the task of learning a Gaussian process model of non-stationary system dynamics in an online fashion. We propose an extension to previous models that can appropriately handle outdated training samples by decreasing their influence onto the predictive distribution. The resulting model estimates for each sample of the training set an individual noise level and thereby produces a mean shift towards more reliable observations. As a result, our model improves the prediction accuracy in the context of non-stationary function approximation and can furthermore detect outliers based on the resulting noise level. Our approach is easy to implement and is based upon standard Gaussian process techniques. In a real-world application where the task is to learn the system dynamics of a miniature blimp, we demonstrate that our algorithm benefits from individual noise levels and outperforms standard methods.

show abstract

Section: Resultsmentioning

confidence: 99%

Learning Non-stationary System Dynamics Online Using Gaussian Processes

Rottmann

Burgard

2010

Lecture Notes in Computer Science

View full text Add to dashboard Cite

show abstract

“…The equations (1) and (2) can be applied for ocean or marine vehicles as well as for airships during indoor experiments. Such examples can be found: (1) for underwater vehicles in [12,17], (2) for surface vessels in [7,18] or hovercrafts in [13,21], (3) for indoor airships in [23,31]. The control strategy is based on transformed equations of motion with the identity inertia matrix.…”

Section: Remarkmentioning

confidence: 99%

Velocity Controller for a Class of Vehicles

Herman

Adamski

2017

Foundations of Computing and Decision Sciences

View full text Add to dashboard Cite

Abstract. This paper addresses the problem of velocity tracking control for various fully-actuated robotic vehicles. The presented method, which is based on transformation of equations of motion allows one to use, in the control gain matrix, the dynamical couplings existing in the system. Consequently, the dynamics of the vehicle is incorporated into the control process what leads to fast velocity error convergence. The stability of the system under the controller is derived based on Lyapunov argument. Moreover, the robustness of the proposed controller is shown too. The general approach is valid for 6 DOF models as well as other reduced models of vehicles. Simulation results on a 6 DOF indoor airship validate the described velocity tracking methodology.

show abstract

“…This is why airships are usually very sensitive to wind and cannot travel efficiently at high speeds. However, because of their ability to naturally float in the air, small airships (also called blimps when there is no rigid structure inside the hull) have been widely used as research platforms in aerial robotics (Bermudez i Badia et al, 2005;Iida, 2003;Van Der Zwaan et al, 2002;Zhang and Ostrowski, 1998;Zufferey et al, 2006a). In particular, Melhuish and Welsby (2002) have been using small indoor blimps to demonstrate flocking behaviours (Fig.…”

Section: Platformsmentioning

confidence: 99%

Underwater Robot Swarms: Challenges and Opportunities

2013

Handbook of Collective Robotics

View full text Add to dashboard Cite

Flying over the reality gap: From simulated to real indoor airships

Cited by 67 publications

References 18 publications

Learning Non-stationary System Dynamics Online Using Gaussian Processes

Learning Non-stationary System Dynamics Online Using Gaussian Processes

Velocity Controller for a Class of Vehicles

Underwater Robot Swarms: Challenges and Opportunities

Contact Info

Product

Resources

About