Current as Touch

Proprioceptive Contact Feedback for Compliant Dexterous Manipulation

Chenyang Ma*, Yunchao Yao*, Zhenyu Wei*, Ruogu Li, Daniel Szafir, Mingyu Ding

University of North Carolina at Chapel Hill

Current as Touch teaser overview.

Abstract

Compliance is essential for dexterous manipulation, yet existing solutions often rely on external tactile or force sensors that are costly, fragile, and difficult to deploy on low-cost robot hands. We propose a proprioception-driven framework that learns tactile-like contact feedback from motor current and joint states. Since motor current is closely related to actuator torque, it provides an intrinsic signal for perceiving contact force, object resistance, and grasp stability without additional sensing hardware. Rather than estimating external wrenches or commanding torque, our method predicts a compliance reference position: an ideal joint-position target for a standard PD controller whose induced position error generates appropriate grasping force. This position-based formulation is compatible with mainstream teleoperation and policy-learning pipelines, while enabling the robot to adapt interaction forces from real-time proprioceptive feedback. Thus, motor current serves not only as a force proxy but also as a learnable proprioceptive contact signal for compliance reference prediction. Experiments on multiple dexterous hands and contact-rich tasks, including fragile object handling, sustained surface contact, thin-object retrieval, and dynamic load adaptation, show stable compliant grasping, safer and more efficient teleoperation, and improved downstream policy learning without external tactile sensors.

Model Framework

Current-conditioned compliance reference prediction model framework.

Overview Video

Experiments

Contact-Rich Manipulation Tasks

Teleoperation

Foam-Cup Stacking

Current-conditioned compliance reference prediction reduces object damage while preserving fast teleoperation.

w/o Current15.0%

novice cup deformation

w/ Current0.0%

novice cup deformation

Foam cup grasping without current.
w/o Current
Foam cup grasping with current.
w/ Current

Teleoperation

Whiteboard Wiping

Motor current helps maintain sustained surface contact against changing board interaction.

w/o Current46.7%

novice success

w/ Current100%

novice success

Whiteboard wiping without current.
w/o Current
Whiteboard wiping with current.
w/ Current

Policy Learning

Single-Card Picking

Current provides contact evidence for retrieving exactly one thin object instead of over-pressing the deck.

w/o Current55.8%

strict success

w/ Current76.9%

strict success

Single-card picking without current.
w/o Current
Single-card picking with current.
w/ Current

Policy Learning

Dynamic Bottle Holding

Load-sensitive motor current lets the grasp adapt as water is poured into the bottle.

w/o Current16.7%

stable at 250 g

w/ Current100%

stable at 250 g

Dynamic bottle holding without current.
w/o Current
slipped to table
Dynamic bottle holding with current.
w/ Current