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Lesson n. 1: Definition of Dynamical System
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Lesson n. 2: The Class of Systems under study
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Lesson n. 3: An introduction to the methodologies
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Lesson n. 4: Approximate representations
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Lesson n. 5: Linear representations: Analysis in the time domain
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Lesson n. 6: The transition matrix
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Lesson n. 7: Free modes for continuous time systems
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Lesson n. 8: Discrete time systems: time domain analysis
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Lesson n. 9: The Laplace Transform in the study of continuous time systems
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Lesson n. 10: The steady state response and the frequency behavior
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Lesson n. 11: Analysis in the complex domain for continuous time systems
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Lesson n. 12: Bode Diagrams
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Lesson n. 13: The Zeta transform in the study of discrete time systems
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Lesson n. 14: Analysis in the complex domain for discrete time systems
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Lesson n. 15: Analysis in the complex domain: the general case
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Lesson n. 16: From the input-output model to the state representation
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Lesson n. 17: Further issues on the state representation
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Lesson n. 18: Stability: definitions and conditions
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Lesson n. 19: Internal Stability for linear systems
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Lesson n. 20: Lyapunov methods for the stability analysis
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Lesson n. 21: Structural properties: reachability and observability
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Lesson n. 22: Kalman decomposition
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Lesson n. 23: Interconnected systems: elementary connections and their properties
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Lesson n. 24: Interconnected systems: on the computation of the associated transfer function and state representation
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Lesson n. 25: A synthesis
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