Topic 13. Modal Analysis of Multi-DOF System: Orthonormality of Modal Vectors

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Topic 13 covers: the core principles of modal analysis for linear undamped multi-degree-of-freedom (MDOF) systems; the theoretical foundation and properties of modal vectors; and the orthonormalization of mode shapes relative to the mass and stiffness matrices.

Modal analysis plays a central role in vibration engineering by transforming coupled differential equations into a decoupled form using modal coordinates. This allows each vibrational mode to be analyzed independently, revealing the system’s natural frequencies and mode shapes—key characteristics that govern its dynamic response.

This chapter introduces the eigenvalue problem in the context of MDOF systems and explores the orthogonality and normalization properties of modal vectors. These mathematical tools form the foundation for simplifying the vibration analysis of complex mechanical systems and are essential for applications in structural dynamics, design optimization, and vibration control.

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