Fundamentals of mechanical vibration; vibration responses to harmonic and random excitations; vibration of single-degree-of-freedom and multiple-degree-of-freedom; modal analysis and resonance; optimum control theories and examples; state-space representation; applications of the optimum feedback control; compensator design using Separation Principle. Credits 3. 3 Lecture Hours.
Fundamentals of mechanical vibration; vibration responses to harmonic and random excitations; vibration of single-degree-of-freedom and multiple-degree-of-freedom; modal analysis and resonance; optimum control theories and examples; state-space representation; applications of the optimum feedback control; compensator design using Separation Principle. Credits 3. 3 Lecture Hours.
