Sliding Speed Influences Electrovibration-Induced Finger Friction Dynamics on Touchscreens

Electrovibration technology can render tactile textures on capacitive touchscreens by modulating friction between the finger and the screen through electrostatic attraction force generated by applying an alternating voltage signal to the screen. This signal should be carefully calibrated for realistic and robust texture rendering. However, this process is challenging due to variations in sliding speed, applied force, and individual skin mechanics, which affect friction in complex and unpredictable ways. Here, we investigate how exploration conditions affect electrovibration-induced finger friction on touchscreens and the role of skin mechanics in this process. Ten participants slid their index fingers across an electrovibration-enabled touchscreen at five sliding speeds ($20\sim100$ mm/s) and applied force levels ($0.2\sim0.6$ N) while we measured contact forces and skin accelerations. The touchscreen was excited with amplitude-modulated voltage signals across frequencies relevant to touch. We modeled the finger-touchscreen friction response as a first-order system and the skin mechanics as a mass-spring-damper system. Our results showed that the sliding speed influenced the cutoff frequency of the friction response as well as the moving mass and stiffness of the finger for the tested exploration ranges. Specifically, for every 1 mm/s increase in speed, the cutoff frequency, the finger moving mass, and stiffness increased by $13.8$ Hz, $3.23\times 10^{-5}$ kg, and $4.04$ N/m, respectively. Further correlation analysis revealed that finger stiffness affected the cutoff frequency more than the moving mass. Finally, we developed a practical model for electrovibration-induced finger friction on touchscreens that accounts for sliding speed variations, paving the way for delivering consistent haptic feedback through electrovibration.