${\mathscr H}_\infty$ Problem with Nonstrict Inequality and All Solutions: Interpolation Approach

Stefanovski, Jovan

doi:10.1137/140968732

Cited by 14 publications

(10 citation statements)

References 24 publications

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“…Let H 2 (s)x = 0, for some s in ℜ[s] ≥ 0 and complex vector x. By algebraic manipulation with the realization (14) of H 2 , we obtain that x = Ky, where the vector y satisfies Ay = sy and  y = 0. Using iteratively the left formula in (B4), starting with i = − 1, and the condition > 0, we obtain C 1 y = 0, and y = 0 as a consequence of the detectability of (A, C 1 ).…”

Section: B4 Proof Of Lemmamentioning

confidence: 99%

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Almost fault‐tolerant tracking

Stefanovski

2020

Intl J Robust & Nonlinear

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Summary A new formulation of the problem of almost fault‐tolerant perfect tracking in presence of disturbances is presented, and necessary and sufficient existence conditions are found, as well as a controller, which consists of a feedback block and two feedforward blocks. The feedback block is aimed for almost disturbance and fault decoupling, and the feedforward blocks are aimed for almost perfect tracking. A two‐step control design procedure such that the feedback block is designed independently of the feedforward blocks is presented. In order to simplify the necessary and sufficient existence conditions, as well as to present a physical interpretation of the existence conditions, the dimension of disturbance and fault vectors is reduced. In order to find a feedback controller, the physical interpretation of the existence conditions is used so that the four‐block‐type problem is transformed to a two‐block‐type problem. Examples are given, which illustrate that the controller of the article is practically realizable.

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Section: B4 Proof Of Lemmamentioning

confidence: 99%

“…We can restrict Y so that ‖ Y ‖ ∞ =‖ T ur ‖ ∞ is minimal. Then we have to find a proper and stable RM Y such that

G_{12} Y = M and ‖ Y ‖_{\infty} is minimal .

Two algorithms to solve the latter problem in the unknown proper stable Y are given in References and .…”

Section: The First Group Of Necessary and Sufficient Conditionsmentioning

confidence: 99%

Almost fault‐tolerant tracking

Stefanovski

2020

Intl J Robust & Nonlinear

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“…Besides to the general bitangential interpolation problem, which can be regarded as a discrete problem, because of the interpolation points, the aBIP can be applied to the following "continuous" problems [21] (without "discrete points" in their formulations):…”

Section: Technical Details On the Abipmentioning

confidence: 99%

“…Introduce the matrices C 1F = C 1 − D 12 F, B 1L = B 1 − LD 21 , and B 2L = B 2 − LD 22 , and the following proper and stable rm's…”

Section: H ∞ Optimal Control With Jω Invariant Zerosmentioning

confidence: 99%

A reformulation of augmented basic interpolation problem and an application to H∞ control

Stefanovski

2015

Linear Algebra and its Applications

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MSC:In this paper we present a new formulation of the augmented basic interpolation problem (aBIP) with rational matrices, in terms of the stability of four rational matrices, so that the aBIP transforms into a purely linear-algebraic problem. Actually, the existing interpolation condition, given by an integral, is replaced by stability of a rational matrix. The new condition is applied to the H ∞ optimal control of one-block plants having imaginary axis invariant zeros. A new parameter in the parametrization of H ∞ optimal controllers is revealed, which is given in terms of the derivative of the closed-loop system at the imaginary axis invariant zeros of the plant. The H ∞ optimal control algorithm is illustrated by an example, and compared to the existing algorithms.

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“…Problem 2 is elaborated in [10] and [13], by considering the FE filter realization in an observer form, and formulating a matrix inequality that includes the unknown coefficients of the observer. It can also be solved by the algorithm of [18].…”

Section: Introductionmentioning

confidence: 99%

Input Estimation Over Frequency Region in Presence of Disturbances

Stefanovski¹,

Juričić

2019

IEEE Trans. Automat. Contr.

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A new formulation of the unknown input estimation problem in presence of unknown disturbances over a frequency region is presented. Necessary and sufficient conditions for existence of a solution are given and three estimation filters are given. The minimal attenuation is equal to the norm of a rational matrix over the frequency region. As a result, the minimum can be computed by solving linear matrix inequalities. An example is given, and the estimation with the proposed filters is illustrated by a numerical simulation and is compared with some state-of-the-art estimation filters.Index Terms-Generalized spectral factorization, inertia of Hermitian matrix, input estimation, para-Hermitian rational matrix.

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${\mathscr H}_\infty$ Problem with Nonstrict Inequality and All Solutions: Interpolation Approach

Cited by 14 publications

References 24 publications

Almost fault‐tolerant tracking

Almost fault‐tolerant tracking

A reformulation of augmented basic interpolation problem and an application to H∞ control

Input Estimation Over Frequency Region in Presence of Disturbances

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