TY - JOUR
T1 - Immobilization-based control of spider-like robots in tunnel environments
AU - Shapiro, Amir
AU - Rimon, Elon
AU - Shoval, Shraga
PY - 2001/3
Y1 - 2001/3
N2 - This paper presents an immobilization-based control method for spider-like robots that move quasi-statically in tunnel environments. The control method is based on a recent immobilization theory of bodies in contact. This theory ensures that when a spider-like mechanism is bracing against the environment at an immobile posture, the naturally occurring compliance at the contacts stabilizes the mechanism as a single body. Based on this result, we present two versions of a position control law for general k-limbed robots. We show that if the controller's stiffness (i.e., proportional gain) is above a lower limit determined by the robot and environment parameters, stability of the closed-loop spider system is guaranteed. Next, we present dynamic simulations of a spider robot moving in a tunnel under the influence of the immobilization-based control law. The simulations show excellent convergence properties of the control algorithm. A four-legged spider prototype has been built, and we conclude with a description of initial experiments with this prototype.
AB - This paper presents an immobilization-based control method for spider-like robots that move quasi-statically in tunnel environments. The control method is based on a recent immobilization theory of bodies in contact. This theory ensures that when a spider-like mechanism is bracing against the environment at an immobile posture, the naturally occurring compliance at the contacts stabilizes the mechanism as a single body. Based on this result, we present two versions of a position control law for general k-limbed robots. We show that if the controller's stiffness (i.e., proportional gain) is above a lower limit determined by the robot and environment parameters, stability of the closed-loop spider system is guaranteed. Next, we present dynamic simulations of a spider robot moving in a tunnel under the influence of the immobilization-based control law. The simulations show excellent convergence properties of the control algorithm. A four-legged spider prototype has been built, and we conclude with a description of initial experiments with this prototype.
KW - Immobilization
KW - Locomotion control
KW - Multilegged robots
UR - http://www.scopus.com/inward/record.url?scp=0035269531&partnerID=8YFLogxK
U2 - 10.1177/02783640122067363
DO - 10.1177/02783640122067363
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AN - SCOPUS:0035269531
SN - 0278-3649
VL - 20
SP - 209
EP - 227
JO - International Journal of Robotics Research
JF - International Journal of Robotics Research
IS - 3
ER -