CDS 140, Winter 2016

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* Lectures: MWF, 1-1:55, 213 ANB
* Lectures: MWF, 1-1:55, 213 ANB
* Office hours:  
* Office hours:  
** DGM: Wed 2-3 pm (please e-mail to confirm)
** DGM: Mon 11:30-1pm, Wed 2-3 pm (please e-mail to confirm)
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'''Teaching Assistants'''
'''Teaching Assistants'''
* Benson Christalin (CDS)
* Benson Christalin (CDS)
* Contact:
* Contact:
* Office hours: TBD
* Office hours: Monday 2-3 pm
=== Announcements ===
* Homework will be due Wednesdays in class (or by 5pm to Benson).  HW 1 is posted below.
* If you have not received an email to sign up for Piazza, please email us!
=== Course Description ===
=== Course Description ===

Revision as of 22:04, 4 January 2016

Introduction to Dynamics


  • Douglas MacMartin,
  • John Doyle,
  • Lectures: MWF, 1-1:55, 213 ANB
  • Office hours:
    • DGM: Mon 11:30-1pm, Wed 2-3 pm (please e-mail to confirm)

Teaching Assistants

  • Benson Christalin (CDS)
  • Contact:
  • Office hours: Monday 2-3 pm


  • Homework will be due Wednesdays in class (or by 5pm to Benson). HW 1 is posted below.
  • If you have not received an email to sign up for Piazza, please email us!

Course Description

Analytical methods for the formulation and solution of initial value problems for ordinary differential equations. Basics in topics in dynamical systems in Euclidean space, including equilibria, stability, phase diagrams, Lyapunov functions, periodic solutions, Poincaré-Bendixon theory, Poincaré maps. Introduction to simple bifurcations, including Hopf bifurcations, invariant and center manifolds.

Lecture Schedule

Date Topic Reading Homework
4 Jan
6 Jan
Linear Differential Equations L1-1 LinSys notes
  • Course overview and administration
  • Linear differential equations
  • Matrix exponential, diagonalization
  • Stable and unstable spaces
  • S + N decomposition, Jordan form

Perko, 1.1-1.10

Due: 13 Jan (Wed)
11 Jan
13 Jan
Nonlinear differential equations
  • Existence and uniqueness
  • Flow of a differential equation
  • Linearization
Perko, 2.1-2.6 HW 2
Due: 20 Jan (Wed)
20 Jan
22 Jan
Behavior of differential equations
  • Stable and unstable manifolds
  • Stability of equilibrium points for planar systems
Perko, 2.7-2.10 HW 3
Due: 27 Jan (Wed)
25 Jan
Non-hyperbolic differential equations
  • Lyapunov functions
  • Center manifold theorem
Perko, 2.11-2.13 HW 4
Due: 3 Feb (Wed)
4 Feb
6 Feb
Global behavior
  • Limit sets and attractors
  • Krasovskii-Lasalle invariance principle (if time)
  • Periodic orbits and limit cycles
Perko, 3.1-3.3 HW 5
Due: 10 Feb (Wed)
9 Feb
11 Feb
Limit cycles
  • Poincare' map
  • Bendixson criterion for limit cycles in the plane
  • Describing functions (if time)
Perko, 3.4-3.5, 3.7 HW 6
Due: 17 Feb (Wed)
18 Feb
20 Feb
  • Sensitivity analysis
  • Structural stability
  • Bifurcation of equilibrium points
Perko 4.1-4.2

BFS 3.2 and 5.4 (PDF)

HW 7
Due: 24 Feb (Wed)
23 Feb
25 Feb?
27 Feb?
  • Hopf bifurcation
  • Application example: rotating stall and surge in turbomachinery
Perko 4.3-4.5 + notes HW 8
Due: 2 Mar (Wed)
2 Mar
6 Mar
Nonlinear control systems Template:Obc08, Chapter 1 OBC 1.3, 1.4ab, 1.5
Due: 9 Mar (Wed)
9 Mar
Course review Final exam
Due: 18 Mar (Wed). Pick up from Nikki Fountleroy, 107 Steele Lab


The primary text for the course (available via the online bookstore) is

 [Perko]  L. Perko, Differential Equations and Dynamical Systems, Third Edition. Springer, 2006.

The following additional texts may be useful for some students:

 [G&H]  J. Guckenheimer and P. Holmes, Nonlinear oscillations, dynamical systems, and bifurcations of vector fields. Springer-Verlag, 1990.
 [H&S]  M. Hirsch and S. Smale, Differential Equations, Dynamical Systems, and Linear Algebra. Springer-Verlag, 1990.
 [J&S]  D. Jordan and P. Smith, Nonlinear Ordinary Differential Equations: An Introduction for Scientists and Engineers, Fourth Edition. Oxford University Press, 2007. (On reserve in SFL)
 [Ver]  F. Verhulst, Nonlinear Differential Equations and Dynamical Systems, Second Edition. Springer, 2006. (On reserve in SFL)


The final grade will be based on homework and a final exam:

  • Homework (75%) - There will be 9 one-week problem sets, due in class approximately one week after they are assigned. Late homework will not be accepted without prior permission from the instructor.
  • Final exam (25%) - The final will be handed out the last day of class and is due back at the end of finals week. Open book, time limit to be decided (likely N hours over a 4-8N hour period).

The lowest homework score you receive will be dropped in computing your homework average. In addition, if your score on the final is higher than the weighted average of your homework and final, your final will be used to determine your course grade.

Collaboration Policy

Collaboration on homework assignments is encouraged. You may consult outside reference materials, other students, the TA, or the instructor. Use of solutions from previous years in the course or from other external sources is not allowed. All solutions that are handed should reflect your understanding of the subject matter at the time of writing.

You can use MATLAB, Mathematica or a similar programs, but you must show the steps that would be required to obtain your answers by hand (to make sure you understand the techniques).

No collaboration is allowed on the final exam. You will also not be allowed to use computers, but the problems should be such that extensive computation is not required.

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