Rethinking Social Robot Navigation: Leveraging the Best of Two Worlds

Empowering robots to navigate in a socially com- pliant manner is essential for the acceptance of robots moving in human-inhabited environments. Previously, roboticists have developed geometric navigation systems with decades of em- pirical validation to achieve safety and efficiency. However, the many complex factors of social compliance make geometric navigation systems hard to adapt to social situations, where no amount of tuning enables them to be both safe (people are too unpredictable) and efficient (the frozen robot problem). With recent advances in deep learning approaches, the common reaction has been to entirely discard these classical navigation systems and start from scratch, building a completely new learning-based social navigation planner. In this work, we find that this reaction is unnecessarily extreme: using a large- scale real-world social navigation dataset, SCAND, we find that geometric systems can produce trajectory plans that align with the human demonstrations in a large number of social situations. We, therefore, ask if we can rethink the social robot navigation problem by leveraging the advantages of both geometric and learning-based methods. We validate this hybrid paradigm through a proof-of-concept experiment, in which we develop a hybrid planner that switches between geometric and learning- based planning. Our experiments on both SCAND and two physical robots show that the hybrid planner can achieve better ∗Equally contributing authors. 1 George Mason University. 2The University of Texas at Austin. 3Sony AI. {araj20, apayande, xiao}@gmu.edu, {zichao, haresh.miriyala, rchandra, luisa.mao}@utexas.edu, {pstone, joydeepb}@cs.texas.edu social compliance compared to using either the geometric or learning-based approach alone.