TY - JOUR
T1 - Enhancing the Force Transparency of the Energy-Reflection-Based Time-Domain Passivity Approach
AU - Panzirsch, Michael
AU - Singh, Harsimran
AU - Xu, Xiao
AU - Dietrich, Alexander
AU - Hulin, Thomas
AU - Steinbach, Eckehard
AU - Albu-Schaeffer, Alin
N1 - Publisher Copyright:
© 1993-2012 IEEE.
PY - 2024
Y1 - 2024
N2 - The time-domain passivity approach (TDPA) was developed and applied to tackle a variety of control challenges such as noncollocated force sensing, authority scaling, or delayed coupling in robotic applications. Specifically for delay, recently, the energy-reflection-based TDPA (TDPA-ER) was proposed to improve position tracking and force-feedback quality. In contrast to the conventional TDPA, the TDPA-ER intrinsically prevents position drift, thus substantially increasing the coupling rigidity. Here, we extend the TDPA-ER to further enhance the force transparency perceived by the operator in teleoperation scenarios. The extension is based on two independent control strategies that, among others, reorganize the energy distribution of TDPA-ER and ensure more continuous force profiles through the deflection-domain passivity approach (DDPA). Experiments confirm the improvement of force-feedback quality and force continuity with regard to TDPA-ER. Furthermore, it is shown that interactions with dynamic objects and active environments can be handled robustly with the proposed teleoperation control strategies.
AB - The time-domain passivity approach (TDPA) was developed and applied to tackle a variety of control challenges such as noncollocated force sensing, authority scaling, or delayed coupling in robotic applications. Specifically for delay, recently, the energy-reflection-based TDPA (TDPA-ER) was proposed to improve position tracking and force-feedback quality. In contrast to the conventional TDPA, the TDPA-ER intrinsically prevents position drift, thus substantially increasing the coupling rigidity. Here, we extend the TDPA-ER to further enhance the force transparency perceived by the operator in teleoperation scenarios. The extension is based on two independent control strategies that, among others, reorganize the energy distribution of TDPA-ER and ensure more continuous force profiles through the deflection-domain passivity approach (DDPA). Experiments confirm the improvement of force-feedback quality and force continuity with regard to TDPA-ER. Furthermore, it is shown that interactions with dynamic objects and active environments can be handled robustly with the proposed teleoperation control strategies.
KW - Deflection-domain control
KW - teleoperation
KW - telerobotics
UR - http://www.scopus.com/inward/record.url?scp=85206269970&partnerID=8YFLogxK
U2 - 10.1109/TCST.2024.3458831
DO - 10.1109/TCST.2024.3458831
M3 - Article
AN - SCOPUS:85206269970
SN - 1063-6536
JO - IEEE Transactions on Control Systems Technology
JF - IEEE Transactions on Control Systems Technology
ER -