Semi-Supervised Haptic Material Recognition for Robots using Generative Adversarial Networks

Material recognition enables robots to incorporate knowledge of material properties into their interactions with everyday objects. For instance, material recognition opens up opportunities for clearer communication with a robot, such as "bring me the metal coffee mug", and having the ability to recognize plastic versus metal is crucial when using a microwave or oven. However, collecting labeled training data can be difficult with a robot, whereas many forms of unlabeled data could be collected relatively easily during a robot's interactions. We present a semi-supervised learning approach for material recognition that uses generative adversarial networks (GANs) with haptic features such as force, temperature, and vibration. Our approach achieves state-of-the-art results and enables a robot to estimate the material class of household objects with ~90% accuracy when 92% of the training data are unlabeled. We explore how well this generative approach can recognize the material of new objects and we discuss challenges facing this generalization. In addition, we have released the dataset used for this work which consists of time-series haptic measurements from a robot that conducted thousands of interactions with 72 household objects.