Analytical representation of the state-dependent coefficients in the SDRE/SDDRE scheme for multivariable systems

“…In addition, we denote (•) ⊥ as the orthogonal complement of a vector space, V x = ∇V = (∂ V /∂x) the row vector of the partial derivatives of V : R n → R, C 1 the set of continuously differentiable functions, e 1 (resp., e 2 ) the first (resp., second) standard basis vector in R n , e n+1 the (n + 1)-th standard basis vector in R n+1 , R ≤0 the set of real numbers that are less than or equal to zero, and sgn(x) the sign function (R\{0} → {±1}) that maps to {1}, if x > 0; {−1}, otherwise. Moreover, in accordance with [23], letξ ∈ R n , we defineξ ⊥ ∈ R (n−1)×n as a matrix with orthonormal rows andξ ⊥ξ = 0. Finally, in agreement with [2,4], denote M 0 (resp., M 0), if a matrix M = M T ∈ R n×n is positive definite (resp., semidefinite).…”

“…(10) (resp.,V (x, t f ) in (22)). Recent literature toward this research direction includes [28], with an intention of mutual conversation for the common good [23]. To remain focused in this presentation, we reference the survey [11] for a general picture of the scheme, while the main result of this subsection (Theorem 4.2) gives a preliminary to the optimality recovery, as based on or motivated by more recent findings that, for example, preliminarily and analytically clarify/guarantee the property of global asymptotic stability using SDRE [18,19].…”

Convex Quadratic Equation

“…In addition, we denote (•) ⊥ as the orthogonal complement of a vector space, V x = ∇V = (∂ V /∂x) the row vector of the partial derivatives of V : R n → R, C 1 the set of continuously differentiable functions, e 1 (resp., e 2 ) the first (resp., second) standard basis vector in R n , e n+1 the (n + 1)-th standard basis vector in R n+1 , R ≤0 the set of real numbers that are less than or equal to zero, and sgn(x) the sign function (R\{0} → {±1}) that maps to {1}, if x > 0; {−1}, otherwise. Moreover, in accordance with [23], letξ ∈ R n , we defineξ ⊥ ∈ R (n−1)×n as a matrix with orthonormal rows andξ ⊥ξ = 0. Finally, in agreement with [2,4], denote M 0 (resp., M 0), if a matrix M = M T ∈ R n×n is positive definite (resp., semidefinite).…”

“…(10) (resp.,V (x, t f ) in (22)). Recent literature toward this research direction includes [28], with an intention of mutual conversation for the common good [23]. To remain focused in this presentation, we reference the survey [11] for a general picture of the scheme, while the main result of this subsection (Theorem 4.2) gives a preliminary to the optimality recovery, as based on or motivated by more recent findings that, for example, preliminarily and analytically clarify/guarantee the property of global asymptotic stability using SDRE [18,19].…”

Convex Quadratic Equation

“…It is worth mentioning that different works have taken advantage of the state-dependent Riccati Eq. (22) in the analysis and synthesis of nonlinear optimal control methodologies and their applications [30][31][32][33][34].…”

Reduced‐order Observer for State‐dependent Coefficient Factorized Nonlinear Systems

“…An alternative approach to solve nonlinear optimal control problems is the state-dependent Riccati equation (SDRE) control synthesis which dates back to 1962 [16]. The SDRE method entails factorization of the nonlinear dynamics into the product of a state-dependent matrix and the state vector thereby transforming the original nonlinear system into a pseudo-linear system [17][18][19][20][21]. In [22], a real-time LQR-based suboptimal approach for full six degree-of-freedom spacecraft control was proposed.…”

Fixed-time near-optimal control for repointing maneuvers of a spacecraft with nonlinear terminal constraints