We discussed the Pythagorean Theorem. We learned the Bride's Chair proof found in Euclid's Elements, and the simpler dissection proof of Thabit ibn Qurra.

Pythagorean triples!

Rational points on the unit circle. Chord and tangent method. Rational parametrizations of conics.

We gave a geometric algorithm for determining commensurability. (Construct an a×b rectangle and repeatedly delete maximal square subregions. The algorithm terminates iff a and b are commensurable, as we showed using the Euclidean algorithm.) We used this algorithm to show that the Golden Ratio is not rational.

We used reductio ad absurdum to show that √2 is irrational.

We discussed the difference between theorems and definitions. We discussed the use of the deductive method in Euclid's Elements.

Straightedge and compass constructions, part 1.

Straightedge and compass constructions, part 4.
Constructible numbers are algebraic, hence Liouville's number is not constructible, e is not constructible (Hermite, 1873), and π is not constructible (Lindemann, 1882).
The minimal polynomial of a constructible number has degree that is a power of 2, hence ∛2 is not constructible. Moreover, cos(π/3) IS constructible, while cos(π/9) is NOT constructible.

(Extended) Euclidean algorithm. Bezout's Identity. Linear diophantine equations.

Pell's equation. (Associated names: Archimedes, Diophantus, Brahmagupta, Bhaskara II, Lord Brouncker, Lagrange.) The cattle problem. Continued fractions method for solving Pell's Equation.

Dissection versus the method of exhaustion, 1.

Number theory in Asia. We began discussing modular arithmetic. We proved that congruence modulo n is compatible with addition and multiplication. We gave a necessary and sufficient condition for a linear congruence ax≡c(mod b) to be solvable, and we described a method of solution. (Method=reduce to a linear diophantine equation.)

Professor Edward B. Burger
Baylor University & Williams College

We discussed Brahmagupta's problem of determining which rational triangles have rational area.

We explained how to solve the quartic equation.

We discussed the Newton-Girard Identities for kth power sums of the roots of a polynomial of degree n in the cases k≤n.

We surveyed some of the major developments in mathematics during 1600's-1800's (Calculus, diff. eqns., calculus of variations, development of analysis, non-Euclidean geometry and its effect on the development of logic, set theory and its effect on the development of the foundations of mathematics).

Hilbert's Problems
Problem #1: the Continuum Hypothesis, part 3.
Ordinal arithmetic. As an example, we showed that every ordinal below ω² equals ωj+k for natural numbers j and k.
We showed that the CSB Theorem implies that equipotence classes of ordinals are intervals. For each ordinal α, there is an ordinal β such that |α|<|β|. Cardinal numbers are defined to be initial ordinals. Every set is equipotent with a unique cardinal number.

Hilbert's Problems
Problem #1: the Continuum Hypothesis, part 4.
"Aleph" notation. The difference between ℵ_α and ω_α. Cantor diagonalization. |A|<|P(A)| for any A.

Hilbert's Problems
Problem #2: the consistency of arithmetic.
Meaning of "consistency", "arithmetic". Gödel's Theorem, Gentzen's Theorem.

(i) a Dehn symbol (L,α) equals zero iff L=0 or α is a rational multiple of π.
(ii) α is a rational multiple of π iff the number z = cos(α)+i*sin(α) is a root of unity.
(iii) roots of unity are algebraic integers.

We gave some techniques for showing that some numbers are NOT algebraic integers. These can be used to show that some angles are NOT rational multiples of π. (In particular, we showed that if tan(α)=√2, then α is not a rational multiple of π. Also, we showed that if cos(α) = -1/3, then α is not a rational multiple of π.)

I circulated the take-home final. Remember, you may use any book while working on the exam, but you are not allowed help from any person other than me.