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22 results on '"Tosatto, Samuele"'

1. Investigating the Benefits of Nonlinear Action Maps in Data-Driven Teleoperation

Author

Przystupa, Michael, Gidel, Gauthier, Taylor, Matthew E., Jagersand, Martin, Piater, Justus, and Tosatto, Samuele

Subjects
Computer Science - Robotics
Abstract

As robots become more common for both able-bodied individuals and those living with a disability, it is increasingly important that lay people be able to drive multi-degree-of-freedom platforms with low-dimensional controllers. One approach is to use state-conditioned action mapping methods to learn mappings between low-dimensional controllers and high DOF manipulators -- prior research suggests these mappings can simplify the teleoperation experience for users. Recent works suggest that neural networks predicting a local linear function are superior to the typical end-to-end multi-layer perceptrons because they allow users to more easily undo actions, providing more control over the system. However, local linear models assume actions exist on a linear subspace and may not capture nuanced actions in training data. We observe that the benefit of these mappings is being an odd function concerning user actions, and propose end-to-end nonlinear action maps which achieve this property. Unfortunately, our experiments show that such modifications offer minimal advantages over previous solutions. We find that nonlinear odd functions behave linearly for most of the control space, suggesting architecture structure improvements are not the primary factor in data-driven teleoperation. Our results suggest other avenues, such as data augmentation techniques and analysis of human behavior, are necessary for action maps to become practical in real-world applications, such as in assistive robotics to improve the quality of life of people living with w disability., Comment: 13 Pages, 7 Figures, presented at Collaborative AI and Modeling of Humans AAAI Bridge Program Submission

Published
2024

2. Deep Probabilistic Movement Primitives with a Bayesian Aggregator

Author

Przystupa, Michael, Haghverd, Faezeh, Jagersand, Martin, and Tosatto, Samuele

Subjects
Computer Science - Robotics, Computer Science - Machine Learning
Abstract

Movement primitives are trainable parametric models that reproduce robotic movements starting from a limited set of demonstrations. Previous works proposed simple linear models that exhibited high sample efficiency and generalization power by allowing temporal modulation of movements (reproducing movements faster or slower), blending (merging two movements into one), via-point conditioning (constraining a movement to meet some particular via-points) and context conditioning (generation of movements based on an observed variable, e.g., position of an object). Previous works have proposed neural network-based motor primitive models, having demonstrated their capacity to perform tasks with some forms of input conditioning or time-modulation representations. However, there has not been a single unified deep motor primitive's model proposed that is capable of all previous operations, limiting neural motor primitive's potential applications. This paper proposes a deep movement primitive architecture that encodes all the operations above and uses a Bayesian context aggregator that allows a more sound context conditioning and blending. Our results demonstrate our approach can scale to reproduce complex motions on a larger variety of input choices compared to baselines while maintaining operations of linear movement primitives provide.

Published
2023

3. Dynamic Decision Frequency with Continuous Options

Author

Karimi, Amirmohammad, Jin, Jun, Luo, Jun, Mahmood, A. Rupam, Jagersand, Martin, and Tosatto, Samuele

Subjects
Computer Science - Machine Learning, Computer Science - Artificial Intelligence
Abstract

In classic reinforcement learning algorithms, agents make decisions at discrete and fixed time intervals. The duration between decisions becomes a crucial hyperparameter, as setting it too short may increase the problem's difficulty by requiring the agent to make numerous decisions to achieve its goal while setting it too long can result in the agent losing control over the system. However, physical systems do not necessarily require a constant control frequency, and for learning agents, it is often preferable to operate with a low frequency when possible and a high frequency when necessary. We propose a framework called Continuous-Time Continuous-Options (CTCO), where the agent chooses options as sub-policies of variable durations. These options are time-continuous and can interact with the system at any desired frequency providing a smooth change of actions. We demonstrate the effectiveness of CTCO by comparing its performance to classical RL and temporal-abstraction RL methods on simulated continuous control tasks with various action-cycle times. We show that our algorithm's performance is not affected by the choice of environment interaction frequency. Furthermore, we demonstrate the efficacy of CTCO in facilitating exploration in a real-world visual reaching task for a 7 DOF robotic arm with sparse rewards., Comment: Appears in the Proceedings of the 2023 International Conference on Intelligent Robots and Systems (IROS). Source code at https://github.com/amir-karimi96/continuous-time-continuous-option-policy-gradient.git

Published
2022

4. A Temporal-Difference Approach to Policy Gradient Estimation

Author

Tosatto, Samuele, Patterson, Andrew, White, Martha, and Mahmood, A. Rupam

Subjects
Computer Science - Machine Learning, Computer Science - Artificial Intelligence
Abstract

The policy gradient theorem (Sutton et al., 2000) prescribes the usage of a cumulative discounted state distribution under the target policy to approximate the gradient. Most algorithms based on this theorem, in practice, break this assumption, introducing a distribution shift that can cause the convergence to poor solutions. In this paper, we propose a new approach of reconstructing the policy gradient from the start state without requiring a particular sampling strategy. The policy gradient calculation in this form can be simplified in terms of a gradient critic, which can be recursively estimated due to a new Bellman equation of gradients. By using temporal-difference updates of the gradient critic from an off-policy data stream, we develop the first estimator that sidesteps the distribution shift issue in a model-free way. We prove that, under certain realizability conditions, our estimator is unbiased regardless of the sampling strategy. We empirically show that our technique achieves a superior bias-variance trade-off and performance in presence of off-policy samples.

Published
2022

5. An Alternate Policy Gradient Estimator for Softmax Policies

Author

Garg, Shivam, Tosatto, Samuele, Pan, Yangchen, White, Martha, and Mahmood, A. Rupam

Subjects
Computer Science - Machine Learning, Computer Science - Artificial Intelligence
Abstract

Policy gradient (PG) estimators are ineffective in dealing with softmax policies that are sub-optimally saturated, which refers to the situation when the policy concentrates its probability mass on sub-optimal actions. Sub-optimal policy saturation may arise from bad policy initialization or sudden changes in the environment that occur after the policy has already converged. Current softmax PG estimators require a large number of updates to overcome policy saturation, which causes low sample efficiency and poor adaptability to new situations. To mitigate this problem, we propose a novel PG estimator for softmax policies that utilizes the bias in the critic estimate and the noise present in the reward signal to escape the saturated regions of the policy parameter space. Our theoretical analysis and experiments, conducted on bandits and various reinforcement learning environments, show that this new estimator is significantly more robust to policy saturation., Comment: Accepted to AISTATS 2022. 60 pages, 50 figures. This updated version has an additional experiment and minor corrections

Published
2021

6. Model-free Policy Learning with Reward Gradients

Author

Lan, Qingfeng, Tosatto, Samuele, Farrahi, Homayoon, and Mahmood, A. Rupam

Subjects
Computer Science - Machine Learning, Computer Science - Artificial Intelligence
Abstract

Despite the increasing popularity of policy gradient methods, they are yet to be widely utilized in sample-scarce applications, such as robotics. The sample efficiency could be improved by making best usage of available information. As a key component in reinforcement learning, the reward function is usually devised carefully to guide the agent. Hence, the reward function is usually known, allowing access to not only scalar reward signals but also reward gradients. To benefit from reward gradients, previous works require the knowledge of environment dynamics, which are hard to obtain. In this work, we develop the \textit{Reward Policy Gradient} estimator, a novel approach that integrates reward gradients without learning a model. Bypassing the model dynamics allows our estimator to achieve a better bias-variance trade-off, which results in a higher sample efficiency, as shown in the empirical analysis. Our method also boosts the performance of Proximal Policy Optimization on different MuJoCo control tasks., Comment: AISTATS 2022 camera-ready (fixed a bug)

Published
2021

7. Batch Reinforcement Learning with a Nonparametric Off-Policy Policy Gradient

Author

Tosatto, Samuele, Carvalho, João, and Peters, Jan

Subjects
Computer Science - Machine Learning, Computer Science - Artificial Intelligence
Abstract

Off-policy Reinforcement Learning (RL) holds the promise of better data efficiency as it allows sample reuse and potentially enables safe interaction with the environment. Current off-policy policy gradient methods either suffer from high bias or high variance, delivering often unreliable estimates. The price of inefficiency becomes evident in real-world scenarios such as interaction-driven robot learning, where the success of RL has been rather limited, and a very high sample cost hinders straightforward application. In this paper, we propose a nonparametric Bellman equation, which can be solved in closed form. The solution is differentiable w.r.t the policy parameters and gives access to an estimation of the policy gradient. In this way, we avoid the high variance of importance sampling approaches, and the high bias of semi-gradient methods. We empirically analyze the quality of our gradient estimate against state-of-the-art methods, and show that it outperforms the baselines in terms of sample efficiency on classical control tasks., Comment: arXiv admin note: substantial text overlap with arXiv:2001.02435

Published
2020

8. Contextual Latent-Movements Off-Policy Optimization for Robotic Manipulation Skills

Author

Tosatto, Samuele, Chalvatzaki, Georgia, and Peters, Jan

Subjects
Computer Science - Robotics, Computer Science - Machine Learning
Abstract

Parameterized movement primitives have been extensively used for imitation learning of robotic tasks. However, the high-dimensionality of the parameter space hinders the improvement of such primitives in the reinforcement learning (RL) setting, especially for learning with physical robots. In this paper we propose a novel view on handling the demonstrated trajectories for acquiring low-dimensional, non-linear latent dynamics, using mixtures of probabilistic principal component analyzers (MPPCA) on the movements' parameter space. Moreover, we introduce a new contextual off-policy RL algorithm, named LAtent-Movements Policy Optimization (LAMPO). LAMPO can provide gradient estimates from previous experience using self-normalized importance sampling, hence, making full use of samples collected in previous learning iterations. These advantages combined provide a complete framework for sample-efficient off-policy optimization of movement primitives for robot learning of high-dimensional manipulation skills. Our experimental results conducted both in simulation and on a real robot show that LAMPO provides sample-efficient policies against common approaches in literature.

Published
2020

9. Dimensionality Reduction of Movement Primitives in Parameter Space

Author

Tosatto, Samuele, Stadtmueller, Jonas, and Peters, Jan

Subjects
Computer Science - Robotics, Computer Science - Machine Learning, Statistics - Machine Learning
Abstract

Movement primitives are an important policy class for real-world robotics. However, the high dimensionality of their parametrization makes the policy optimization expensive both in terms of samples and computation. Enabling an efficient representation of movement primitives facilitates the application of machine learning techniques such as reinforcement on robotics. Motions, especially in highly redundant kinematic structures, exhibit high correlation in the configuration space. For these reasons, prior work has mainly focused on the application of dimensionality reduction techniques in the configuration space. In this paper, we investigate the application of dimensionality reduction in the parameter space, identifying principal movements. The resulting approach is enriched with a probabilistic treatment of the parameters, inheriting all the properties of the Probabilistic Movement Primitives. We test the proposed technique both on a real robotic task and on a database of complex human movements. The empirical analysis shows that the dimensionality reduction in parameter space is more effective than in configuration space, as it enables the representation of the movements with a significant reduction of parameters.

Published
2020

10. An Upper Bound of the Bias of Nadaraya-Watson Kernel Regression under Lipschitz Assumptions

Author

Tosatto, Samuele, Akrour, Riad, and Peters, Jan

Subjects
Statistics - Machine Learning, Computer Science - Machine Learning
Abstract

The Nadaraya-Watson kernel estimator is among the most popular nonparameteric regression technique thanks to its simplicity. Its asymptotic bias has been studied by Rosenblatt in 1969 and has been reported in a number of related literature. However, Rosenblatt's analysis is only valid for infinitesimal bandwidth. In contrast, we propose in this paper an upper bound of the bias which holds for finite bandwidths. Moreover, contrarily to the classic analysis we allow for discontinuous first order derivative of the regression function, we extend our bounds for multidimensional domains and we include the knowledge of the bound of the regression function when it exists and if it is known, to obtain a tighter bound. We believe that this work has potential applications in those fields where some hard guarantees on the error are needed

Published
2020

11. A Nonparametric Off-Policy Policy Gradient

Author

Tosatto, Samuele, Carvalho, Joao, Abdulsamad, Hany, and Peters, Jan

Subjects
Computer Science - Machine Learning, Statistics - Machine Learning
Abstract

Reinforcement learning (RL) algorithms still suffer from high sample complexity despite outstanding recent successes. The need for intensive interactions with the environment is especially observed in many widely popular policy gradient algorithms that perform updates using on-policy samples. The price of such inefficiency becomes evident in real-world scenarios such as interaction-driven robot learning, where the success of RL has been rather limited. We address this issue by building on the general sample efficiency of off-policy algorithms. With nonparametric regression and density estimation methods we construct a nonparametric Bellman equation in a principled manner, which allows us to obtain closed-form estimates of the value function, and to analytically express the full policy gradient. We provide a theoretical analysis of our estimate to show that it is consistent under mild smoothness assumptions and empirically show that our approach has better sample efficiency than state-of-the-art policy gradient methods.

Published
2020

12. An Upper Bound of the Bias of Nadaraya-Watson Kernel Regression under Lipschitz Assumptions

Author

Tosatto, Samuele, Akrour, Riad, Peters, Jan, Tosatto, Samuele, Akrour, Riad, and Peters, Jan

Abstract

The Nadaraya-Watson kernel estimator is among the most popular nonparameteric regression technique thanks to its simplicity. Its asymptotic bias has been studied by Rosenblatt in 1969 and has been reported in several related literature. However, given its asymptotic nature, it gives no access to a hard bound. The increasing popularity of predictive tools for automated decision-making surges the need for hard (non-probabilistic) guarantees. To alleviate this issue, we propose an upper bound of the bias which holds for finite bandwidths using Lipschitz assumptions and mitigating some of the prerequisites of Rosenblatt’s analysis. Our bound has potential applications in fields like surgical robots or self-driving cars, where some hard guarantees on the prediction-error are needed.

Published
2024

16. Variable Decision-Frequency Option Critic

Author

Karimi, Amirmohammad, Jin, Jun, Luo, Jun, Mahmood, A. Rupam, Jagersand, Martin, and Tosatto, Samuele

Subjects
FOS: Computer and information sciences, Computer Science - Machine Learning, Artificial Intelligence (cs.AI), Computer Science - Artificial Intelligence, Machine Learning (cs.LG)
Abstract

In classic reinforcement learning algorithms, agents make decisions at discrete and fixed time intervals. The duration between decisions becomes a crucial hyperparameter, as setting it too short may increase the difficulty of the problem by requiring the agent to make numerous decisions to achieve its goal, while setting it too long can result in the agent losing control over the system. However, physical systems do not necessarily require a constant control frequency, and for learning agents, it is often preferable to operate with a low frequency when possible and a high frequency when necessary. We propose a framework called Continuous-Time Continuous-Options (CTCO), where the agent chooses options as sub-policies of variable durations. These options are time-continuous and can interact with the system at any desired frequency providing a smooth change of actions. We demonstrate the effectiveness of CTCO by comparing its performance to classical RL and temporal-abstraction RL methods on simulated continuous control tasks with various action-cycle times. We show that our algorithm's performance is not affected by choice of environment interaction frequency. Furthermore, we demonstrate the efficacy of CTCO in facilitating exploration in a real-world visual reaching task for a 7 DOF robotic arm with sparse rewards., Comment: Appears in the Proceedings of the 2023 International Conference on Intelligent Robots and Systems (IROS). Source code at https://github.com/amir-karimi96/continuous-time-continuous-option-policy-gradient.git

Published
2022
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17. Off-Policy Reinforcement Learning for Robotics

Author

Tosatto, Samuele

Abstract

Nowadays, industrial processes are vastly automated by means of robotic manipulators. In some cases, robots occupy a large fraction of the production line, performing a rich range of tasks. In contrast to their tireless ability to repeatedly perform the same tasks with millimetric precision, current robotics exhibits low adaptability to new scenarios. This lack of adaptability in many cases hinders a closer human-robot interaction; furthermore, when one needs to apply some change to the production line, the robots need to be reconfigured by highly-qualified figures. Machine learning and, more particularly, reinforcement learning hold the promise to provide automated systems that can adapt to new situations and learn new tasks. Despite the overwhelming progress in recent years in the field, the vast majority of reinforcement learning is not directly applicable to real robotics. State-of-the-art reinforcement learning algorithms require intensive interaction with the environment and are unsafe in the early stage of learning when the policy perform poorly and potentially harms the systems. For these reasons, the application of reinforcement learning has been successful mainly on simulated tasks such as computer- and board-games, where it is possible to collect a vast amount of samples in parallel, and there is no possibility to damage any real system. To mitigate these issues, researchers proposed first to employ imitation learning to obtain a reasonable policy, and subsequently to refine it via reinforcement learning. In this thesis, we focus on two main issues that prevent the mentioned pipe-line from working efficiently: (i) robotic movements are represented with a high number of parameters, which prevent both safe and efficient exploration; (ii) the policy improvement is usually on-policy, which also causes inefficient and unsafe updates. In Chapter 3 we propose an efficient method to perform dimensionality reduction of learned robotic movements, exploiting redundancies in the movement spaces (which occur more commonly in manipulation tasks) rather than redundancies in the robot kinematics. The dimensionality reduction allows the projection to latent spaces, representing with high probability movements close to the demonstrated ones. To make reinforcement learning safer and more efficient, we define the off-policy update in the movement’s latent space in Chapter 4. In Chapter 5, we propose a novel off-policy gradient estimation, which makes use of a particular non-parametric technique named Nadaraya-Watson kernel regression. Building on a solid theoretical framework, we derive statistical guarantees. We believe that providing strong guarantees is at the core of a safe machine learning. In this spirit, we further expand and analyze the statistical guarantees on Nadaraya-Watson kernel regression in Chapter 6. Usually, to avoid challenging exploration in reinforcement learning applied to robotics, one must define highly engineered reward-function. This limitation hinders the possibility of allowing non-expert users to define new tasks. Exploration remains an open issue in high-dimensional and sparse reward. To mitigate this issue, we propose a far-sighted exploration bonus built on information-theoretic principles in Chapter 7. To test our algorithms, we provided a full analysis both on simulated environment, and in some cases on real world robotic tasks. The analysis supports our statement, showing that our proposed techniques can safely learn in the presence of a limited set of demonstration and robotic interactions.

Published
2021

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