Humanoid Cognitive Robots That Learn by Imitating: Implications for Consciousness Studies
James A. Reggia, Garrett E. Katz, Gregory P. Davis
Frontiers in Robotics and AI January 26, 2018 Peer reviewed DOI: 10.3389/frobt.2018.00001 via DOAJ
Summary
A humanoid robot learns tasks by imitating human demonstrations, using cause-effect reasoning to infer intentions rather than copying actions verbatim. Its cognitive system centers on top-down control of working memory, with gating mechanisms that retain explanatory interpretations during learning. The authors argue that these gating mechanisms are a potential computational correlate of consciousness, and that developing neurocognitive control systems for robots offers a credible route toward understanding and eventually creating a phenomenally conscious machine.
Study at a glance
| Design | review |
|---|---|
| Key finding | Top-down cognitive control of working memory, particularly its gating mechanisms, is an important potential computational correlate of consciousness in humanoid robots. |
Abstract
While the concept of a conscious machine is intriguing, producing such a machine remains controversial and challenging. Here, we describe how our work on creating a humanoid cognitive robot that learns to perform tasks via imitation learning relates to this issue. Our discussion is divided into three parts. First, we summarize our previous framework for advancing the understanding of the nature of phenomenal consciousness. This framework is based on identifying computational correlates of consciousness. Second, we describe a cognitive robotic system that we recently developed that learns to perform tasks by imitating human-provided demonstrations. This humanoid robot uses cause–effect reasoning to infer a demonstrator’s intentions in performing a task, rather than just imitating the observed actions verbatim. In particular, its cognitive components center on top-down control of a working memory that retains the explanatory interpretations that the robot constructs during learning. Finally, we describe our ongoing work that is focused on converting our robot’s imitation learning cognitive system into purely neurocomputational form, including both its low-level cognitive neuromotor components, its use of working memory, and its causal reasoning mechanisms. Based on our initial results, we argue that the top-down cognitive control of working memory, and in particular its gating mechanisms, is an important potential computational correlate of consciousness in humanoid robots. We conclude that developing high-level neurocognitive control systems for cognitive robots and using them to search for computational correlates of consciousness provides an important approach to advancing our understanding of consciousness, and that it provides a credible and achievable route to ultimately developing a phenomenally conscious machine.