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Send comments or questions to: ldurand@hep.wisc.edu
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Send comments or questions to: ldurand@hep.wisc.edu
PHYSICS 711, CLASSICAL THEORETICAL PHYSICS - DYNAMICS
FALL, 1998
The course is divided into three units with different themes and emphases:
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| Joseph-Louis Lagrange 1764 |
William Rowan Hamilton | Emmy Noether | ||
| Week | Lec. | Date | Subjects |
|---|---|---|---|
| 1 | 1 | Sept. 2 | Chap. 1. Introduction; motion under constraints, types of constraints, d'Alembert's principle. |
| 2 | 4 | Generalized forces, Lagrange's equations, the Lagrangian function. | |
| 2 | 3 | Sept. 9 | Velocity-dependent forces; examples of Lagrangian problems, shrinking pendulum, motion constrained to a surface; change of variables in the Lagrangian. |
| Hw. 1 | 4 | 11 | Change of variables; integrability of Lagrange's equations, Lagrangian constraints; Chap. 2. Variational principles. |
| 3 | 5 | Sept. 14 | Variational principles, Euler's variational equations, the brachistochrone. Hamilton's principle, the Euler-Lagrange equations. |
| 6 | 16 | Differential constraints; elimination of holonomic or nonholonomic differential constraints using Lagrange multipliers; integral constraints in variational problems. | |
| Hw. 2 | 7 | 18 | Examples of constrained problems; free motion with constraints; integrability conditions for differential constraints. |
| 4 | 8 | Sept. 21 | Jacobi's formulation of least action, geodesics, connection with dynamics. Constants of the motion, cyclic variables. |
| 9 | 23 | Symmetries and Noether's theorem; examples of symmetries; time translations and the Hamiltonian. | |
| Hw. 3 | 10 | 25 | The Hamiltonian, distinction from the energy; use of constants of the motion; examples; integrability of dynamical systems. Chap. 3: two-body problems. |
| 5 | 11 | Sept. 28 | Two-body problems, constants of the motion, the orbit and time equations. |
| 12 | 30 | Qualitative description of motion, the Kepler problem, scattering; n-body problems, the virial theorem. | |
| Hw. 4 | 13 | Oct. 2 | Chap. 6. Small oscillation problems, motions near equilibrium, quadratic Lagrangians, characteristic frequencies of oscillation. |
| 6 | 14 | Oct. 5 | Transformation to normal coordinates, examples; symmetries, uniform motions and "zero modes". |
| 15 | 7 | Perturbation methods; motions near a steady motion; stability of motion. | |
| END OF UNIT 1, START UNIT 2 | |||
| Hw. 5 | 16 | 9 | Chap. 4. Rotations, direction cosines, representation of rotations by orthogonal matrices, matrix algebra. |
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| Leonhard Euler 1736 |
Albert Einstein | |
| Week | Lec. | Date | Subjects |
|---|---|---|---|
| 7 | 17 | Oct. 12 | Transformations of matrices, diagonalization; reflections; examples for rotations. Euler angles. |
| 18 | 14 | HOUR EXAM IN CLASS ON THE MATERIAL IN UNIT 1, CHAPS. 1-3, 6 | |
| 19 | 16 | Fixed and moving axes, matrix representations of Euler rotations, SU(2) representation of rotations, spinors. | |
| 8 | 20 | Oct. 19 | SU(2) methods; infinitesimal rotations, angular velocities for Euler rotations, body and space axes. |
| 21 | 21 | Rotating coordinates, centrifugal and Coriolis forces. Examples with Coriolis forces. | |
| Hw. 6 | 22 | 23 | The groups SU(2) and SO(3), group generators, exponential representations. Chap. 5. Rotating rigid bodies, I, L, T. |
| 9 | 23 | Oct. 26 | Calculation of the moment tensor, principal moments of inertia, principal axes; Euler's equations of motion. |
| 24 | 28 | Free rotation, stability of motion near the principal axes; symmetrical rotator, qualitative description of the motion. | |
| Hw. 7 | 25 | 30 | Symmetries and the use of partially rotating coordinates, examples; Poinsot construction for the asymmetric rotator. |
| 10 | 26 | Nov. 2 | Symmetrical top, equations of motion, precession and nutation, examples. |
| 27 | 4 | Chap. 7. Relativity, Lorentz transformations, metric notation, invariants; matrix representations of Lorentz transformations. | |
| Hw. 8 | 28 | 6 | Boosts, rapidities, and addition of velocities; general Lorentz transformations; covariant vectors, index notation, differential operators and the wave equation. |
| 11 | 29 | Nov. 9 | Hyperbolic geometry, the light cone, invariants; particle motion, world lines, the free relativistic Lagrangian; four momentum, four velocity, and kinematics. |
| 30 | 11 | Relativistic particle Lagrangians, conservation laws; electromagnetic interactions, other examples, the no-interaction theorem. | |
| Hw. 9 | 31 | 13 | The Lorentz group; matrix generators, successive transformations, Thomas precession. |
| END OF UNIT 2, START UNIT 3 |
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| Simeon Denis Poisson 1808 |
Karl Gustav Jakob Jacobi 1843 |
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| Week | Lec. | Date | Subjects |
|---|---|---|---|
| 12 | 32 | Nov. 16 | Chap. 8. Legendre transformations and Hamilton's equations of motion; interpretation of Hamilton's equations; the variational principle. |
| 33 | 18 | HOUR EXAM IN CLASS ON THE MATERIAL IN UNIT 2, CHAPS. 4, 5, 7 and lecture material. | |
| 34 | 20 | Use of Hamilton's equations, motion near a steady motion, examples. | |
| 13 | 35 | Nov. 23 | Chap. 9. Canonical transformations: examples, invariance of Hamilton's equations, symplectic transformations. |
| Hw. 10 | 36 | 25 | Symplectic structure of Hamiltonian mechanics; symplectic invariants, Poisson and Lagrange brackets, tests for canonical transformations. |
| THANKSGIVING RECESS, Nov.26-29 | |||
| 14 | 37 | Nov. 30 | The variational principal and generating functions for canonical transformations; examples; infinitesimal canonical transformations. |
| 38 | Dec. 2 | Time development as a canonical transformation; symmetries in Hamiltonian mechanics, generators of infinitesimal symmetries, Noether's theorem and constants of the motion. | |
| Hw. 11 | 39 | 4 | Constants of the motion from Hamiltonian symmetry transformations, examples, symmetry algebras, finite transformations, Poisson brackets and differentiasl operators. |
| 15 | 40 | Dec. 7 | Chap. 10. Solution of problems by canonical transformation, Hamilton-Jacobi theory, Hamilton's principal function, connection with the action. |
| 41 | 9 | One dimensional problems; solution of the oscillator by the Hamilton-Jacobi method. Hamilton's characteristic function, separation of variables in the Hamilton-Jacobi equation. | |
| Hw. 12 | 42 | 11 | Separation of variables: examples. Phase plots, action and angle variables. |
| 16 | 43 | Dec. 14 | Use of action and angle variables, properties, examples. |
| END OF UNIT 3 | |||
| Final | Dec. 22 | FINAL EXAM TUESDAY, DECEMBER 22, 2:45 pm, EMPHASIS ON UNIT 3 | |
| WINTER RECESS DECEMBER 22-JANUARY 11. | |||
| SECOND SEMESTER: FIRST CLASS ON TUESDAY, JANUARY 20 | |||
| PHYSICS 722 STARTS WEDNESDAY, JANUARY 21 | |||