Karol Hausman scite author profile

Large language models can encode a wealth of semantic knowledge about the world. Such knowledge could be extremely useful to robots aiming to act upon high-level, temporally extended instructions expressed in natural language. However, a significant weakness of language models is that they lack real-world experience, which makes it difficult to leverage them for decision making within a given embodiment. For example, asking a language model to describe how to clean a spill might result in a reasonable narrative, but it may not be applicable to a particular agent, such as a robot, that needs to perform this task in a particular environment. We propose to provide real-world grounding by means of pretrained skills, which are used to constrain the model to propose natural language actions that are both feasible and contextually appropriate. The robot can act as the language model's "hands and eyes," while the language model supplies high-level semantic knowledge about the task. We show how low-level skills can be combined with large language models so that the language model provides high-level knowledge about the procedures for performing complex and temporally extended instructions, while value functions associated with these skills provide the grounding necessary to connect this knowledge to a particular physical environment. We evaluate our method on a number of real-world robotic tasks, where we show the need for real-world grounding and that this approach is capable of completing long-horizon, abstract, natural language instructions on a mobile manipulator. The project's website and the video can be found at say-can.github.io. (a) Large Language Models (LLMs) (b) SayCan

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Gradient Surgery for Multi-Task Learning

Yu¹,

Kumar²,

Gupta³

et al. 2020

Preprint

136

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Force estimation and slip detection/classification for grip control using a biomimetic tactile sensor

et al. 2015

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Dynamics-Aware Unsupervised Discovery of Skills

Sharma¹,

Gu²,

Levine³

et al. 2019

Preprint

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Conventionally, model-based reinforcement learning (MBRL) aims to learn a global model for the dynamics of the environment. A good model can potentially enable planning algorithms to generate a large variety of behaviors and solve diverse tasks. However, learning an accurate model for complex dynamical systems is difficult, and even then, the model might not generalize well outside the distribution of states on which it was trained. In this work, we combine model-based learning with model-free learning of primitives that make model-based planning easy. To that end, we aim to answer the question: how can we discover skills whose outcomes are easy to predict? We propose an unsupervised learning algorithm, Dynamics-Aware Discovery of Skills (DADS), which simultaneously discovers predictable behaviors and learns their dynamics. Our method can leverage continuous skill spaces, theoretically, allowing us to learn infinitely many behaviors even for high-dimensional state-spaces. We demonstrate that zero-shot planning in the learned latent space significantly outperforms standard MBRL and model-free goal-conditioned RL, can handle sparse-reward tasks, and substantially improves over prior hierarchical RL methods for unsupervised skill discovery. Video demonstration of our results are available at: https://sites.google.com/view/dads-skill Figure 1: A humanoid agent discovers diverse locomotion primitives without any reward using DADS. We show zero-shot generalization to downstream tasks by composing the learned primitives using model predictive control, enabling the agent to follow an online sequence of goals (green markers) without any additional training. * Work done as a member of Google AI Residency Program (g.co/airesidency).Preprint. Under review.

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Karol Hausman

Interactive Perception: Leveraging Action in Perception and Perception in Action

Do As I Can, Not As I Say: Grounding Language in Robotic Affordances

Gradient Surgery for Multi-Task Learning

Force estimation and slip detection/classification for grip control using a biomimetic tactile sensor

Dynamics-Aware Unsupervised Discovery of Skills

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