A finite‐time adaptive Taylor series tracking control of electrically‐driven wheeled mobile robots

Abstract: This research seeks to address a new integrated kinematic/dynamic adaptive Taylor series‐based control design for the robust tracking of electrically‐driven differential drive wheeled mobile robots (WMRs). This control design includes two loops, namely the outer loop (a kinematic control law) and the inner loop (a dynamic controller). Being capable of compensating for far initial conditions from a desired trajectory, a new kinematic control law is designed to make the posture tracking error converge to zero as… Show more

“…Theorem 1. The sliding surface S i → 0 as t → ∞, for i = 1, … , n using the control law (37) and the adaptation laws (44) utilized on system (16). Proof: The Barbalat Lemma is used to prove S → 0 as t → ∞.…”

“…Proof: The Barbalat Lemma is used to prove S → 0 as t → ∞. The closed-loop system (38) is formed by substituting the control law (37) with adaptation laws (44) into system (16). Then, choosing the Lyapunov function (39) results in (46).…”

“…In order to completely overcome the chattering phenomenon, the sign-function may be removed in the close vicinity of the sliding surface S = 0 as the uncertainty estimation is solely performed by the Taylor expansion. Consequently, a new Taylor-based boundary layer ASMC scheme is derived from the control laws ( 36) and (37) as…”

“…In this section, the proposed control law expressed by the Taylor-based ASMC scheme in (37) is denoted as PCL (37) and the time delay ASMC [20] expressed by ( 59) is denoted as TASMC (59). The control design parameters for the PCL (37) are shown in Table 1.…”

“…Taylor expansion has found various applications in control methods such as model predictive control [33], near-optimal control [34,35], model-based proportional integral derivative control [36], and Taylor-based adaptive control [30,31,37]. It is pointed out that the Taylor expansion can only be applied for a differentiable function around a given point.…”

Taylor‐based adaptive sliding mode control method for robot manipulators

“…Theorem 1. The sliding surface S i → 0 as t → ∞, for i = 1, … , n using the control law (37) and the adaptation laws (44) utilized on system (16). Proof: The Barbalat Lemma is used to prove S → 0 as t → ∞.…”

“…Proof: The Barbalat Lemma is used to prove S → 0 as t → ∞. The closed-loop system (38) is formed by substituting the control law (37) with adaptation laws (44) into system (16). Then, choosing the Lyapunov function (39) results in (46).…”

“…In order to completely overcome the chattering phenomenon, the sign-function may be removed in the close vicinity of the sliding surface S = 0 as the uncertainty estimation is solely performed by the Taylor expansion. Consequently, a new Taylor-based boundary layer ASMC scheme is derived from the control laws ( 36) and (37) as…”

“…In this section, the proposed control law expressed by the Taylor-based ASMC scheme in (37) is denoted as PCL (37) and the time delay ASMC [20] expressed by ( 59) is denoted as TASMC (59). The control design parameters for the PCL (37) are shown in Table 1.…”

“…Taylor expansion has found various applications in control methods such as model predictive control [33], near-optimal control [34,35], model-based proportional integral derivative control [36], and Taylor-based adaptive control [30,31,37]. It is pointed out that the Taylor expansion can only be applied for a differentiable function around a given point.…”

Taylor‐based adaptive sliding mode control method for robot manipulators

Adaptive tracking control of two-wheeled mobile robots under Denial-of-Service attacks

Reinforcement learning‐based finite‐time cross‐media tracking control for a cross‐media vehicle under unknown dynamics and disturbances