TY - JOUR
T1 - Input Decoupling of Lagrangian Systems via Coordinate Transformation
T2 - General Characterization and its Application to Soft Robotics
AU - Pustina, Pietro
AU - Santina, Cosimo Della
AU - Boyer, Frederic
AU - De Luca, Alessandro
AU - Renda, Federico
PY - 2024
Y1 - 2024
N2 - Suitable representations of dynamical systems can simplify their analysis and control. On this line of thought, this article aims to answer the following question: Can a transformation of the generalized coordinates under which the actuators directly perform work on a subset of the configuration variables be found? We not only show that the answer to this question is yes but also provide necessary and sufficient conditions. More specifically, we look for a representation of the configuration space such that the right-hand side of the dynamics in Euler-Lagrange form becomes [\boldsymbol{I}\; \boldsymbol{O}]{T}\boldsymbol{u}, being \boldsymbol{u} the system input. We identify a class of systems, called collocated, for which this problem is solvable. Under mild conditions on the input matrix, a simple test is presented to verify whether a system is collocated or not. By exploiting power invariance, we provide necessary and sufficient conditions that a change of coordinates decouples the input channels if and only if the dynamics is collocated. In addition, we use the collocated form to derive novel controllers for damped underactuated mechanical systems. To demonstrate the theoretical findings, we consider several Lagrangian systems with a focus on continuum soft robots.
AB - Suitable representations of dynamical systems can simplify their analysis and control. On this line of thought, this article aims to answer the following question: Can a transformation of the generalized coordinates under which the actuators directly perform work on a subset of the configuration variables be found? We not only show that the answer to this question is yes but also provide necessary and sufficient conditions. More specifically, we look for a representation of the configuration space such that the right-hand side of the dynamics in Euler-Lagrange form becomes [\boldsymbol{I}\; \boldsymbol{O}]{T}\boldsymbol{u}, being \boldsymbol{u} the system input. We identify a class of systems, called collocated, for which this problem is solvable. Under mild conditions on the input matrix, a simple test is presented to verify whether a system is collocated or not. By exploiting power invariance, we provide necessary and sufficient conditions that a change of coordinates decouples the input channels if and only if the dynamics is collocated. In addition, we use the collocated form to derive novel controllers for damped underactuated mechanical systems. To demonstrate the theoretical findings, we consider several Lagrangian systems with a focus on continuum soft robots.
KW - Dynamics
KW - Mechanical systems
KW - Modeling, Control, and Learning for Soft Robots
KW - Motion Control
KW - Robot kinematics
KW - Robots
KW - Soft robotics
KW - Sufficient conditions
KW - Symmetric matrices
KW - Underactuated Robots
KW - Vectors
UR - http://www.scopus.com/inward/record.url?scp=85187023719&partnerID=8YFLogxK
U2 - 10.1109/TRO.2024.3370089
DO - 10.1109/TRO.2024.3370089
M3 - Article
AN - SCOPUS:85187023719
SN - 1552-3098
VL - 40
SP - 2098
EP - 2110
JO - IEEE Transactions on Robotics
JF - IEEE Transactions on Robotics
ER -