**Complex Analysis (Q)**

The calculus of complex-valued functions turns out to have unexpected simplicity and power. As an example of simplicity, every complex-differentiable function is automatically infinitely differentiable. As examples of power, the so-called "residue calculus" permits the computation of "impossible" integrals, and "conformal mapping" reduces physical problems on very general domains to problems on the round disc. The easiest proof of the Fundamental Theorem of Algebra, not to mention the first proof of the Prime Number Theorem, used complex analysis.

**lecture**

*Class Format:***evaluation will be based primarily on homework, classwork, and exams**

*Requirements/Evaluation:*

*Additional Info:*

*Additional Info2:***MATH 350 or MATH 351**

*Prerequisites:*

*Enrollment Preference:*

*Department Notes:*

*Material and Lab Fees:*

*Distribution Notes:***Division III,Quantitative and Formal Reasoning**

*Divisional Attributes:*

*Other Attributes:***40**

*Enrollment Limit:***30**

*Expected Enrollment:***3459**

*Class Number:*CLASSES | ATTR | INSTRUCTORS | TIMES | CLASS NUMBER |
---|---|---|---|---|

MATH 372 - 01 (S) LEC Complex Analysis (Q) | Cesar E. Silva |
MWF 12:00 PM-12:50 PM Bronfman 104 | 3459 |