2000
DOI: 10.1017/s0263574799001988
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Adaptive set–point control of robotic manipulators with amplitude–limited control inputs

Abstract: This paper addresses the link position setpoint control problem of n–link robotic manipulators with amplitude-limited control inputs. We design a global-asymptotic exact model knowledge controller and a semi-global asymptotic controller which adapts for parametric uncertainty. Explicit bounds for these controllers can be determined; hence, the required input torque can be calculated a priori so that actuator saturation can be avoided. We also illustrate how the proposed control algorithm in this paper can be… Show more

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Cited by 63 publications
(78 citation statements)
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“…Property 2: The function in (24) denotes a normal projection algorithm, which ensures that the following inequality is satisfied (for further details, see [32]- [35]): (26) where , denote known, constant lower and upper bounds, respectively, of . After substituting the time derivative of (22) into (20), the closed-loop error system can be determined as (27) where denotes the parameter estimation error defined as (28) 2 Since the measurable regression matrix Y (1) contains only the reference trajectories x and _ x , the expression in (24) can be integrated by parts to prove that the adaptive estimate (t) can be generated using only measurements of e (t) (i.e., no r (t) measurements, and hence, no _ x(t) measurements are required).…”
Section: Closed-loop Error Systemmentioning
confidence: 99%
“…Property 2: The function in (24) denotes a normal projection algorithm, which ensures that the following inequality is satisfied (for further details, see [32]- [35]): (26) where , denote known, constant lower and upper bounds, respectively, of . After substituting the time derivative of (22) into (20), the closed-loop error system can be determined as (27) where denotes the parameter estimation error defined as (28) 2 Since the measurable regression matrix Y (1) contains only the reference trajectories x and _ x , the expression in (24) can be integrated by parts to prove that the adaptive estimate (t) can be generated using only measurements of e (t) (i.e., no r (t) measurements, and hence, no _ x(t) measurements are required).…”
Section: Closed-loop Error Systemmentioning
confidence: 99%
“…In Loria (1997), a controller is proposed involving a gravity compensation term plus a saturating function through which the position errors pass. A velocity and position feedback method with adaptive gravity compensation is reported in Zergeroglu (2000) in which the velocity and position errors separately pass through two nonlinear saturating functions and the outputs are then added to an adaptive gravity compensation term. In Zavala (2006), a brief review of PD plus gravity compensation controllers is provided.…”
Section: Introductionmentioning
confidence: 99%
“…Solutions without considering velocity measurements and with gravity compensation are treated in (Loria et al, 1997). A full-state (position and velocity) feedback solution with adaptive gravity compensation is presented in (Zergeroglu et al, 2000). More recently, new schemes dealing with this regulation problem of robot manipulators with bounded inputs have been presented by Zavala & Santibañez (2006), Zavala & Santibañez (2007), Dixon (2007), Alvarez -Ramirez et al, (2003), and Alvarez- Ramirez et al, (2008).…”
Section: Introductionmentioning
confidence: 99%