Physics 3320

Modern Introductory Mechanics

Physics 3320 Syllabus

Chapter 1: Mathematical Review

  • Trigonometry
  • Matrices
  • Orthogonal Transformations
  • Scalars and Vector Fields
  • Vector Algebra and Scalar Differentiation
  • Alternate Coordinate Systems
  • Angular Velocity
  • Differential Operator and the Leibnitz Rule
  • Complex Variables
  • Problems

Chapter 2: Newtonian Mechanics

  • Review of Newton’s Laws
  • Simple Examples using Newton’s Laws
  • Single Particle Conservation Theorems
  • Potential Energy and Particle Motion
  • Equilibrium and Stability in One Dimension
  • Equilibrium and Stability in D Dimensions
  • Problems

Chapter 3: Linear Oscillations

  • General Restoring Forces in One and Two Dimensions
  • Damped Oscillations
  • Circuit/Oscillator analogy
  • Driven Harmonic Oscillations
  • Fourier Series Methods
  • Green Function Methods
  • Problems

Chapter 4: Nonlinear Oscillations

  • The Anharmonic Oscillator
  • The Plane Pendulum
  • Phase Diagrams for Nonlinear Oscillations
  • The Logistic Difference Equation
  • Fractals
  • Chaos in Physical Systems
  • Dissipative Phase Space
  • Lyapunov Exponents
  • The Intermittant Transition to Chaos
  • Problems

Chapter 5: Gravitation

  • Newton’s Law of Gravitation
  • Gravitational Potential
  • Modifications for Extended Objects
  • Eötvös Experiment on Composition Dependence of Gravitational Forces
  • Problems

Chapter 6: Calculus of Variations

  • Euler-Lagrange ERquation
  • “Second form” of Euler’s Equation
  • Brachistochrone Problem
  • The Case of More than One Dependent Variable
  • The Case of More than One Independent Variable
  • Constraints
  • Lagrange Multipliers
  • Isoperimetic Problems
  • Variation of the end points of integration
  • Problems

Chapter 7: Lagrangian and Hamiltonian Mechanics

  • The Action and Hamilton’s Principle
  • Generalized Coordinates
  • Examples of the Formalism
  • Two Points about Lagrangian Methods
  • Types of Constraints
  • Endpoint Invariance: Multiparticle Conservation Laws
  • Consequences of Scale Invariance
  • When does H=T+U?
  • Investigation into the Meaning of dE/dt=0
  • Hamilton’s Equations
  • Holonomic Constraints in Hamiltonian Formalism
  • Problems