Study of Rota-Baxter Operators in Matrix C*-Algebras Motivated by Toeplitz Structures, and Applications to Sliding Mode Control

Abstract

This paper studies Rota-Baxter operators on the matrix C*-algebra Mn(C), motivated by the discrete Toeplitz algebra (whose role is purely heuristic; see Remark~rem:toeplitzscope). We provide a structural classification of such operators compatible with the C*-norm, analyze their induced Lie brackets, and apply them to deform system matrices in discrete-time delayed systems under sliding mode control. Lyapunov-based Bilinear Matrix Inequality conditions, together with a tractable linear reformulation via Q=X-1, guarantee asymptotic stability on the sliding manifold and L2-gain stability. The effective gain from uncertainty δ to state x is γ/μ with μ=λ(-M)>0 determined a posteriori; minimizing γ alone does not minimize this bound, which holds under zero extended initial conditions (V0=0). We work under the standing assumption m=n (square actuation); a supplementary non-degenerate example with m=1, n=2 illustrates LMI feasibility with ≠0. All algebraic results are proved directly in Mn(C); no infinite-dimensional reduction is used.