Abstract
This paper presents a general framework based on lifting technique for sampled-data systems with input time delays. By analyzing the properties of operator-valued matrices of lifted systems with input time delays, an extended lifting technique is obtained. It is then shown that, with the proposed lifting technique, the complex behavior of the system can be illustrated by two simple lifted systems, which construct the extended lifted system. The extended lifted system has the same induced norm as that of the original system with an input time delay, since the proposed lifting technique is an isometric isomorphism. Through applying the proposed lifting technique to sampled-data systems with input time delays, the time-invariant discrete-time system with infinite-dimensional input and output spaces is obtained. The equivalent discrete-time system, which is derived from the extended lifted system, can satisfy the problem of H 2 sampled-data control systems with input time delays. Simulation results are given to show that the proposed method can guarantee a more stable system response than the conventional H 2 sampled-data controller for the sampled-data systems with the various input time delays.
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Park, K.S., Park, J.B., Choi, Y.H. et al. Design of H 2 Controllers for Sampled-Data Systems with Input Time Delays. Real-Time Systems 26, 231–260 (2004). https://doi.org/10.1023/B:TIME.0000018245.94136.d0
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DOI: https://doi.org/10.1023/B:TIME.0000018245.94136.d0