5705 description

Mathematics 5285-6 Honors (Fundamental Structures of Algebra I and II)

Description for prospective students

This is a junior-senior level one-year sequence in abstract algebra, or what is often called a "groups, rings, and fields" course.

It is intended for students who intended to go on to study more abstract mathematics, and who will either need or enjoy a solid understanding of algebra at a rigorous level. The expectations of mathematical maturity and ability to handle rigor are about as high it gets in our math undergraduate classes, on a par with the Honors Analysis sequence Math 5615-6. The exposition often involves lots of "definition-example-theorem-proof".

Topics covered in the class often include

linear algebra (vector spaces, determinants, and possibly Jordan canonical form),
group theory (including subgroups, normal subgroups, quotient groups, Sylow's theorems, permutation groups, finite abelian groups, matrix groups)
ring theory (ideals, quotient rings, principal ideal domains, factorization, modular arithmetic, polynomial rings)
field theory (finite, algebraic, and transcendental extensions, extension degree, compass/straightedge constructions, solvability by radicals, finite fields)

CAUTION: It is not wise to jump into the second-semester Math 5286 without having just taken Math 5285, even if one has taken a single semester of a "groups, and rings, and fields" course before-- the content in such a single semester can vary greatly. In such a situation, it is best to consult the instructor about whether one has the necessary background.

Note that the Math 5285-6 sequence fulfills a math major's algebra requirement (part of "Column X") ) as described here .

To suggest some flavor of Math 5285-6, a student might learn ...

how the 5 Platonic solids relate to the classification of finite groups of rotations in 3-dimensional space
why a finite group whose size is divisible by some power p^d of a prime p will always have at least one subgroup of size p^d
how to tell, relatively quickly, whether or not two square matrices A,B are similar, meaning that B = PAP^-1 for some invertible matrix P
what all finite fields look like, and how they are constructed
why it is ultimately impossible, using only a compass and straightedge, to do the 3 things that frustrated the ancient Greeks:
- to trisect an arbitrary angle,
- to "duplicate" a cube,
- to "square" a circle
why the quadratic formula, which does have a generalization solving 3rd and 4th degree polynomial equations, will never have a generalization for 5th degree equations.

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