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- Quadrate matrix inequality region 二次矩陣不等式區域
- The guaranteed cost controllers can be obtained by solving the linear matrix inequality, which makes the closed-loop systems quadratic stable for all admissible uncertainties, as well as guarantying the cost is bounded in a limitation. 通過求解相應的線性矩陣不等式就可得到魯棒保成本控制,所設計的保成本控制器對所有容許的不確定性不僅使得相應的閉環系統達到二次穩定,也能保證閉環成本函數不超過一個確定的界。
- These conditions are expressed via the linear matrix inequality(LMI). 基於線性矩陣不等式(LMI)處理方法,給出了分散控制器存在的充分條件。
- The sufficient condition equals to the solvability of a kind of linear matrix inequality (LMI). 此充分條件等價於一類線性矩陣不等式(LMI)的可解性。
- Firstly, a new delay-dependent passivity condition in terms of linear matrix inequality is proved. 針對標稱系統,利用線性矩陣不等式給出其時滯依賴無源性條件;
- Stabilization conditions in the form of linear matrix inequality(LMI) are established. 建立了可由線性矩陣不等式(LMI)表示的鎮定條件。
- Once this condition is feasible, a strict linear matrix inequality (LMI) design approach is developed with an explicit expression for decentralized state feedback controller. 當這組條件可解時,給出了分散狀態反饋控制器的嚴格線性矩陣不等式設計方法和控制律的表達式。
- By using Lyapunov stable theory, the gain of the observer can be obtained by solving a line matrix inequality (LMI) in Matlab LMI toolbox. 應用Lyapunov穩定性理論,觀測器的增益藉助於Matlab中的LMI工具箱求解線性矩陣不等式得到。
- By using a saturated feedback control structure, the control law is obtained by solving a linear matrix inequality (LMI) optimization problem on-line. 初始時刻優化問題的可行性保證了閉環控制系統的魯棒穩定性。
- The solvable condition of this optimization problem and further the solutions are derived by employing linear matrix inequality techniques. 應用線性矩陣不等式技術,給出並證明了該解存在條件和求解方法。
- The proposed criterion is formulated in terms of a linear matrix inequality (LMI) with some model transformation techniques and decomposition method. 主要結果可估測延遲時間且為時延相關穩定準則。
- Then, the Lyapunov function and linear matrix inequality (LMI) methods are used to derive a sufficient condition for the asymptotical stability of the hybrid system. 然後採用李亞普諾夫函數、線性矩陣不等式的方法推導出了該混合系統漸近穩定的一個充分條件。
- Then, the Lyapunov function, linear matrix inequality (LMI) methods were used to derive a sufficient condition, which could ensure that the NCS was asymptotically stable. 然後採用李亞普諾夫函數、線性矩陣不等式的方法推導出了該網路化控制系統漸近穩定的充分條件。
- The concept of parallel distributed compensation (PDC) and linear matrix inequality (LMI) are employed to design an output feedback controller for T-S fuzzy models. 然後採用平行分佈補償法(PDC)和線性矩陣不等式方法(LMI),研究了該類輸出反饋控制器的解析設計方法。
- For the external disturbances and the approximation errors, a linear matrix inequality (LMI) problem is then solved to guarantee the robustness of the closed-loop. 對於系統不確定外界干擾和模糊系統的逼近誤差,通過求解一個線性矩陣不等式來保證閉環系統的魯棒穩定性。
- Based on the impulsive theory and linear matrix inequality technique, a sufficient condition for the impulsive synchronization of chaotic dynamical systems is derived. 利用脈衝控制理論和線性矩陣不等式的方法,得到了關於混沌系統脈衝同步的一個充分條件。
- The Lyapunov function,linear matrix inequality(LMI) methods are used to derive a sufficient condition,which can guarantee that the NCS is asymptotically stable. 採用李亞普諾夫函數、線性矩陣不等式的方法推導出一類網路化控制系統漸近穩定的充分條件。
- Then, by Lyapunov function and linear matrix inequality (LMI), the sufficient conditions are given to make the singular networked control system exponentially stable. 利用李雅普諾夫函數方法和線性矩陣不等式方法,給出了廣義網路控制系統指數穩定的充分條件。
- Greatest common divisor quadratic matrix 最大公因數平方矩陣
- By using linear matrix inequality (LMI) approach,a good region is presented fo r the upper bound index of state variance which is consistent with the prespecif ied pole region. 利用線性矩陣不等式(LMI)方法,得到了與指定極點區域相容的狀態方差上界指標的較好取值範圍。
