Waves and Oscillations

Module Co-ordinator: TKouloukas@lincoln.ac.uk (Dr Theodoros Kouloukas)

Course Components §

1. Coursework Assignment (10%)
2. Cengage Numerical Assignment x4 (15%)
3. In-Class Assessment (25%)
4. Final Exams (50%)

Current percentage (rounded up): 88%

Learning Outcomes §

• LO1 Mathematically solve simple problems of waves.
• LO2 Construct multi-step solutions of problems of waves.
• LO3 Formulate main laws of waves.

Summary Content §

Waves and Oscillations Summary Notes - created closely alongside practical session solutions. Waves and Oscillations Summary Questions - created from all questions given by the lecturer. Waves and Oscillations Practice Tests - created by extrapolating question style into novel content.

Flashcards §

Waves and Oscillations Flashcards (Anki) - created during lectures. Waves and Oscillations Flashcards (Physical) - refined flashcards for long-time revision.

Notes §

1. Dynamics of Periodic and Simple Harmonic Motion §

1.1 Fundamentals of Simple Harmonic Motion (SHM) §

• Basic Principles of Simple Harmonic Motion (SHM): Introduction to the defining characteristics and equations of simple harmonic motion.
• Objects Attached to Springs: Analysis of motion for objects connected to springs under SHM.
• Amplitude and Initial Phase: Exploration of amplitude and phase angle in the context of SHM.

1.2 Energy in Simple Harmonic Motion §

• Kinetic and Potential Energy in Simple Harmonic Motion (SHM): Understanding the interplay of kinetic and potential energies in SHM systems.
• Energy Conservation in Simple Harmonic Motion (SHM): Examination of energy conservation principles specific to SHM.

2. Wave Motion §

2.1 Nature and Types of Waves §

• Transverse and Longitudinal Waves: Differentiating between transverse and longitudinal wave forms.
• One Dimensional Wave Motion: Investigating wave propagation in one-dimensional media.

2.2 Mathematical Modelling of Waves §

• The Wave Equation: Derivation and implications of the wave equation in different contexts.
• Strain in Solid Bars Due to Wave Motion: Analysis of strain effects in solid bars due to wave motion.

3. Harmonic Propagating Waves §

3.1 Characteristics of Harmonic Waves §

• Properties of Harmonic Waves: Exploring the fundamental properties and behaviour of harmonic waves.

3.2 Doppler Effect in Wave Motion §

• Understanding the Doppler Effect: Comprehensive study of the Doppler effect in various media.

4. Superposition of Waves and Group Velocity §

4.1 Interference and Superposition of Waves §

• Principles of Wave Interference: Examining how waves interact when they meet.
• Simple Wave Packets: Understanding the formation and properties of simple wave packets.

4.2 Group Velocity Concepts §

• Group Velocity in Wave Mechanics: Analysis of group velocity and its significance in wave motion.

5. Standing Waves and Oscillations §

5.1 Formation and Properties of Standing Waves §

• Fixed Boundary Conditions and Standing Waves: Studying the formation of standing waves under fixed boundary conditions.

5.2 Normal Modes and Oscillations §

• Normal Modes in Oscillatory Systems: Exploring the concept of normal modes in systems exhibiting standing waves.