Difference between revisions of "CDS 202, Winter 2009"
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'''Instructor:'''  
: Richard Murray, 109 Steele  
: murray@cds.caltech.edu  
  
'''Teaching Assistant:'''  
: Paul Skerritt  
  
'''Lectures:'''  
: TuTh 910:30a  
  
'''Office Hours:'''  
: TBD  
} __NOTOC__  
=== Course Description ===  
CDS 202. Geometry of Nonlinear Systems. 9 units (306); second term.  
Prerequisites: CDS 201 or AM 125 a. Basic diﬀerential geometry, oriented toward applications  
in control and dynamical systems. Topics include smooth manifolds and mappings, tangent and  
normal bundles. Vector ﬁelds and ﬂows. Distributions and Frobeniuss theorem. Matrix Lie groups  
and Lie algebras. Exterior diﬀerential forms, Stokes theorem.  
=== Course Schedule ===  === Course Schedule ===  
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{{cds202wi08 week1010 Mar12 MarIntegration on manifoldsmra8textNone}}  {{cds202wi08 week1010 Mar12 MarIntegration on manifoldsmra8textNone}}  
}  }  
=== Course Text ===  
The primary course text is the third edition of ''Manifolds, Tensor Analysis, and Applications'':  
* Marsden, Ratiu and Abraham, Manifolds, Tensor Analysis, and Applications (if you are registered for the course, send email to Richard Murray [murray@cds] for the password).  
In addition, students may find the following textbooks useful:  
* Boothby, An Introduction to Differential Manifolds and Riemannian Geometry, Revised second edition, 2002.  
=== Grading ===  
[[Category:Courses]]  [[Category:Courses]] 
Revision as of 18:57, 6 December 2008
Instructor:

Teaching Assistant:

Lectures:

Office Hours:

Course Description
CDS 202. Geometry of Nonlinear Systems. 9 units (306); second term. Prerequisites: CDS 201 or AM 125 a. Basic diﬀerential geometry, oriented toward applications in control and dynamical systems. Topics include smooth manifolds and mappings, tangent and normal bundles. Vector ﬁelds and ﬂows. Distributions and Frobeniuss theorem. Matrix Lie groups and Lie algebras. Exterior diﬀerential forms, Stokes theorem.
Course Schedule
Week  Lec 1  Lec 2  Topic  Reading  Homework 
1  N/A  8 Jan  Course introduction  None  None 
2  13 Jan  15 Jan  Point set topology  MTA Ch 1  HW #1 (solns) 
3  20 Jan  22 Jan  Inverse fcn thm, immersions, submersions  MTA Ch 2  HW #2 (solns) 
4  27 Jan  29 Jan  Manifolds, mappings, tangent space  MTA Ch 3  HW #3 (solns) 
5  3 Feb  5 Feb  Tangent bundle, vector fields  MTA Ch 4  HW #4 (solns) 
6  10 Feb  12 Feb  Distributions, Frobenius theorem  MTA Ch 4  HW #5 (solns) 
7  17 Feb  19 Feb  Lie groups and Lie algebras  MTA Ch 5  HW #6 (solns) 
8  24 Feb  26 Feb  Tensor fields  MTA Ch 6  HW #7 (solns) 
9  3 Mar  5 Mar  Differential forms  MTA Ch 7  HW #8 (solns) 
10  10 Mar  12 Mar  Integration on manifolds  MTA Ch 8  None 
Course Text
The primary course text is the third edition of Manifolds, Tensor Analysis, and Applications:
 Marsden, Ratiu and Abraham, Manifolds, Tensor Analysis, and Applications (if you are registered for the course, send email to Richard Murray [murray@cds] for the password).
In addition, students may find the following textbooks useful:
 Boothby, An Introduction to Differential Manifolds and Riemannian Geometry, Revised second edition, 2002.