Inverse Design of Metainterfaces for Static Friction Control: Beyond the Hertzian Limit
Jacopo Bilotto, Arnav Singhal, Joaquin Garcia-Suarez, Gaëtan Cortes, Lucas Fourel, Jean-François Molinari
- Year
- 2026
- Access
- Open access
Abstract
Programming the static friction of mechanical interfaces is critical for soft robotics, haptics, and precision gripping. Static friction is governed by the real contact area, and standard rough surfaces exhibit a linear area-load scaling inherent to classical Archard and Greenwood-Williamson models, severely restricting their functional range. Here, we propose a framework for the inverse design of tribological metainterfaces engineered for programmable contact behaviors. By utilizing general axisymmetric asperities, we unlock nonlinear macroscopic responses unattainable by standard Hertzian contacts. To solve the inverse problem, we embed a fully differentiable contact mechanics engine within a neural network and a quadratic optimizer. We leverage regularized physical gradients to automatically discover non-standard topographies that reproduce complex target friction laws, with only a few asperities in unit cells. The predicted designs are strictly validated against high-fidelity Boundary Element Method (BEM) simulations. This framework bridges data-driven optimization and rigorous physics, offering a scale-invariant pathway for discovering functional tribological surfaces.
Keywords
Related papers
The Uncanny Valley [From the Field]
Masahiro Mori, Karl F. MacDorman, Norri Kageki
2012
Measurement Instruments for the Anthropomorphism, Animacy, Likeability, Perceived Intelligence, and Perceived Safety of Robots
Christoph Bartneck, Dana Kulić, Elizabeth A. Croft +1 more
2008
The development of Honda humanoid robot
Kazuo Hirai, Masato Hirose, Y. Haikawa +1 more
2002
A Meta-Analysis of Factors Affecting Trust in Human-Robot Interaction
Peter A. Hancock, Deborah R. Billings, Kristin E. Schaefer +3 more
2011