Real-time neural identification and inverse optimal control for a tracked robot

Abstract: This work presents the implementation in real-time of a neural identifier based on a recurrent high-order neural network which is trained with an extended Kalman filter-based training algorithm and an inverse optimal control applied to a tracked robot. The recurrent high-order neural network identifier is developed without the knowledge of the plant model or its parameters; on the other hand, the inverse optimal control is designed for tracking velocity references. This article includes simulation and real-tim… Show more

“…A tracked robot consists of the following state variables [17,26,27] position x, position y, position θ, velocity 1, velocity 2, current 1 and current 2. In this work, we focus on the controller tracking performance for x, y and θ ( Figure 5) for given references x r , y r and θ r .…”

“…In this work, we focus on the controller tracking performance for x, y and θ ( Figure 5) for given references x r , y r and θ r . The objective is to improve the NIOC results presented in [17] by using GCO to find the optimal parameters of the controller. These parameters are included in the matrices P 1 and P 2 defined in (11) and (12) respectively.…”

“…These parameters are included in the matrices P 1 and P 2 defined in (11) and (12) respectively. The P 1 and P 2 are symmetric positive definite matrices, therefore we can define the set of variables {ψ 1 , ψ 2 , ψ 3 , ψ 4 , ψ 5 } for the optimization problem with the definition in (17).…”

“…For the following experiments we use a GCO algorithm in five dimension running 150 iterations using 30 B-cells (4500 executions) for a test of 10 seconds; we set the parameters F = 1.25 and CR = 0.7. We include graphics for one simulation test using the all-terrain robot model presented in [17], and the results of one experimental test using the modified HD2 R Treaded ATR Tank Robot Platform with wireless communication (Figure 3) presented in [17].…”

“…The control scheme consisting of a neural identifier and an inverse optimal control technique is named neural inverse optimal control (NIOC), this control scheme has shown good results in the literature for trajectory tracking [15][16][17]. However, the designer has to tune the appropriate value of some parameters of the controller discuss later in this work, the quality of the controller depends directly on this selection.…”

Germinal Center Optimization Applied to Neural Inverse Optimal Control for an All-Terrain Tracked Robot

“…A tracked robot consists of the following state variables [17,26,27] position x, position y, position θ, velocity 1, velocity 2, current 1 and current 2. In this work, we focus on the controller tracking performance for x, y and θ ( Figure 5) for given references x r , y r and θ r .…”

“…In this work, we focus on the controller tracking performance for x, y and θ ( Figure 5) for given references x r , y r and θ r . The objective is to improve the NIOC results presented in [17] by using GCO to find the optimal parameters of the controller. These parameters are included in the matrices P 1 and P 2 defined in (11) and (12) respectively.…”

“…These parameters are included in the matrices P 1 and P 2 defined in (11) and (12) respectively. The P 1 and P 2 are symmetric positive definite matrices, therefore we can define the set of variables {ψ 1 , ψ 2 , ψ 3 , ψ 4 , ψ 5 } for the optimization problem with the definition in (17).…”

“…For the following experiments we use a GCO algorithm in five dimension running 150 iterations using 30 B-cells (4500 executions) for a test of 10 seconds; we set the parameters F = 1.25 and CR = 0.7. We include graphics for one simulation test using the all-terrain robot model presented in [17], and the results of one experimental test using the modified HD2 R Treaded ATR Tank Robot Platform with wireless communication (Figure 3) presented in [17].…”

“…The control scheme consisting of a neural identifier and an inverse optimal control technique is named neural inverse optimal control (NIOC), this control scheme has shown good results in the literature for trajectory tracking [15][16][17]. However, the designer has to tune the appropriate value of some parameters of the controller discuss later in this work, the quality of the controller depends directly on this selection.…”

Germinal Center Optimization Applied to Neural Inverse Optimal Control for an All-Terrain Tracked Robot

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