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PHYS 5103: Advanced Mechanics

PHYS 5103: Advanced Mechanics (Fall 2016, University of Arkansas). 2016 Fall Physics Lectures from the University of Arkansas - Fayetteville, AR. These videos are a component of the graduate course PHYS 5103 - "Advanced Mechanics" using the text "Classical Mechanics with a Bang!", both developed by Prof. William G. Harter. The class provides a geometric approach to classical mechanics. Geometry helps to clarify the calculus and physics of mechanics and shows that the symmetry principles behind classical theory also underlie quantum theory.

Lecture 17 - Riemann-Christoffel Equations and Covariant Derivative

Lecture Slides
Lecture 17. Riemann-Christoffel Equations and Covariant Derivative

Go to the Course Home or watch other lectures:

Lecture 01 - 1st Axioms and Theorems of Classical Mechanics
Lecture 02 - Analysis of 1D 2-Body Collisions I
Lecture 03 - Analysis of 1D 2-Body Collisions II: Reflection Groups
Lecture 04 - Kinetic Derivation of 1D Potentials and Force Fields
Lecture 05 - Dynamics of Potentials and Force Fields
Lecture 06 - Geometry of Common Power-law Potentials
Lecture 07 - Kepler Geometry of Isotropic Harmonic Oscillator (IHO) Elliptical Orbits
Lecture 08 - Quadratic Form Geometry and Development of Mechanics of Lagrange and Hamilton
Lecture 09 - Equations of Lagrange and Hamilton Mechanics in Generalized Curvilinear Coordinates (GCC)
Lecture 10 - Hamiltonian vs. Lagrange Mechanics in Generalized Curvilinear Coordinates (GCC)
Lecture 11 - Poincare, Lagrange, Hamiltonian, and Jacobi Mechanics
Lecture 12 - Complex Variables, Series, and Field Coordinates I
Lecture 13 - Complex Variables, Series, and Field Coordinates II
Lecture 14 - Introducing GCC Lagrangian a la Trebuchet Dynamics
Lecture 15 - GCC Lagrange and Riemann Equations for Trebuchet
Lecture 16 - Hamilton Equations for Trebuchet and Other Things
Lecture 17 - Riemann-Christoffel Equations and Covariant Derivative
Lecture 18 - Electromagnetic Lagrangian and Charge-field Mechanics
Lecture 19 - Classical Constraints: Comparing Various Methods
Lecture 20 - Introduction to Classical Oscillation and Resonance
Lecture 21 - Introduction to Coupled Oscillation and Eigenmodes
Lecture 22 - Introduction to Spinor-Vector Resonance Dynamics
Lecture 23 - U(2)~R(3) Algebra/Geometry in Classical or Quantum Theory
Lecture 24 - Parametric Resonance and Multi-particle Wave Modes
Lecture 25 - Introduction to Orbital Dynamics
Lecture 26 - Geometry and Symmetry of Coulomb Orbital Dynamics I
Lecture 27 - Geometry and Symmetry of Coulomb Orbital Dynamics II
Lecture 28 - Multi-particle and Rotational Dynamics
Lecture 29
Lecture 30 - Relawavity and a Novel Introduction to Relativistic Mechanics I
Lecture 31 - Relawavity and a Novel Introduction to Relativistic Mechanics II