Theory: Fundamental concepts and measurement technique. The effects of noise and vibrations on humans and equipment. Mathematical methods. The wave equation and its solutions in fluids. Reflections, transmissions and standing waves. The wave equations and their solutions in solids. Energy methods and room acoustics. Sound generation and radiation. Vibration isolations. Sound in ducts. Measurement and analysis of sounds and vibrations.
Exercises: Theory-based calculations, above all in order to illuminate how this knowledge may be applied. Measurement exercise: 1. Measurement and analysis of vibrations. 2. Measurement and analysis of noise.
The course aims to provide the fundamentals of engineering noise and vibration – basic principles and phenomena, analysis methods and control techniques to engineer quieter and less-vibrating vehicles, machines, products, operations and environment.
By the end of this course, students should be able to identify and examine real noise and vibration issues in general; specify and analyse the sources and propagation of sound and vibration, define and evaluate alternative solutions and suggest measures to solve noise and vibration problems.
In detail, the students should be able to:
- Describe fundamental concepts of engineering noise and vibration, measurement techniques and instruments. Explain the effect of noise and vibrations on humans and equipment. Give an overview of the international standards, laws and regulations in the field.
- Apply their knowledge in mechanics to develop lumped mass models of continuous systems and derive corresponding equations of motion and, using knowledge in mathematics, mathematically represent and calculate solutions. Apply Fourier analysis to solve coupled differential equations, calculate the frequency content of periodic and transient signals and implement this knowledge to analyse mechanical systems. Describe methods to distinguish between linear and non-linear mechanical systems.
- Describe the physical foundations of mathematical models of sound waves in fluids and solids, wave propagation, transmission and reflection. Calculate important parameters, such as wave speed in different media and natural frequencies and modes for enclosures and solid structures. Describe different mechanisms of structural damping, suggest and implement suitable experimental methods to determine loss factor in structures.
- Explain the physical foundations of statistical room acoustics. Apply mathematical models and experimental methods to define sound propagation, transmission and interaction in rooms, compartments and cabins.
- Identify, describe and analyse physical phenomena that generate sound and vibration in mechanical systems; apply mathematical models to analyse sound and vibration generation.
- Explain the fundamental mechanisms of vibration isolation, apply different solutions and calculate design parameters.
- Explain different methods to control sound propagation in ducts; evaluate the need for sound attenuation and design mufflers for different applications.