The majority of Hamilton students who choose mathematics do so because they find it interesting in its own right rather than because they need it for some other goal. In recent years, between 40 and 50 students per year choose to concentrate in math, divided roughly equally among men and women.

The mathematics curriculum begins with a calculus sequence, followed by a range of abstract and applied courses. The concentration culminates in the Senior Seminar, taken by all majors in the fall of their senior year. These small seminars focus on different areas of mathematics and are primarily presentations by students. Some students elect to pursue a senior project in the spring under the guidance of a faculty advisor.

If you are planning on taking a calculus course we recommend the following:

Take Math 113 if you have had no calculus or less than a year of calculus.

Take Math 116 if you have had a year of calculus and an AB 4 or 5.

Take Math 216 if you have had a year of calculus and a BC 4 or 5.

If you have had a year of calculus, but do not fit in one of the above categories, we strongly recommend that you take the Calculus Placement Exam. If you still have questions email mathematics@hamilton.edu.

**
113 F,S
Calculus I.
**

Introduction to the differential and integral calculus of a single variable. Topics include limits, continuity, derivatives, max-min problems and integrals. For students matriculating in 2013 or later, this course may not be counted toward the concentration or minor.
(Quantitative and Symbolic Reasoning.)
Four hours of class.
The Department.

**
116 F,S
Calculus II.
**

116 F,S Calculus II – A continuation of the study begun in 113. Methods of integration, improper integrals, applications of integration to volume and arc length, parametric equations, sequences and series, power series, vectors, and an introduction to 3-dimensional coordinate systems with equations of lines and planes. Prerequisite, 113 or placement by the department. Not open to students who have taken 114. The Department.
(Quantitative and Symbolic Reasoning.)
Completion of 116 with a grade of C- or greater gives Hamilton credit for both 113 and 116 for those students placed into 116.
The Department.

**
216 F,S
Multivariable Calculus.
**

Introduction to functions of more than one variable, partial derivatives, multiple integrals in two and three dimensions, line and surface integrals, Green’s Theorem, curl, divergence, the Divergence Theorem and Stokes’ Theorem. Prerequisite 116 or placement by the department. Not open to students who have taken 114. The Department.
(Quantitative and Symbolic Reasoning.)
Completion of 216 with a grade of C- or greater carries credit for both 116 and 216 for those students placed into 216.
The Department.

**
224 F,S
Linear Algebra.
**

An introduction to linear algebra: matrices and determinants, vector spaces, linear transformations, linear systems and eigenvalues; mathematical and physical applications.
(Writing-intensive.)
(Quantitative and Symbolic Reasoning.)
Prerequisite, 116 or 216 or consent of instructor.
Maximum enrollment, 20.
The Department.

**
231 F
Linear Optimization.
**

An introduction to solving optimization problems involving linear functions subject to linear constraints (linear programming). Topics include the simplex method, duality theory, game theory and integer programming. Features applications to economics, computer science and other areas.
(Quantitative and Symbolic Reasoning.)
Prerequisite, 224.
Cockburn.

**
234 S
Counting and Codes.
**

Topics include enumeration and error correcting codes. Enumeration methods are used to count objects with a given description (used to compute probabilities and to estimate computer program running times). Error correcting codes are used to identify and fix small transmission errors (used in MP3 players, DVDs, cable TV). For each topic we will look at the big ideas, and apply them to small cases.
(Quantitative and Symbolic Reasoning.)
Prerequisite, 224.
Boutin.

**
235 F,S
Differential Equations.
**

Theory and applications of differential equations, including first-order equations, second-order linear equations, systems of equations, and qualitative and numerical methods.
(Quantitative and Symbolic Reasoning.)
(Speaking-Intensive.)
Prerequisite, 224.
Maximum enrollment, 20.
The Department.

**
252 F,S
Statistical Analysis of Data.
**

An introduction to the principles and methods of applied statistics. Topics include exploratory data analysis, sampling distributions, confidence intervals, hypothesis testing, regression analysis, analysis of variance and categorical data analysis. Extensive reliance on statistical computer software and authentic data, with a focus on investigating issues of social, structural, and institutional hierarchies.
(Social, Structural, and Institutional Hierarchies.)
(Quantitative and Symbolic Reasoning.)
May not be taken by students who have taken Math 253, or have taken or are taking Econ 265 or Econ 166..
Maximum enrollment, 20.
The Department.

**
253 F,S
Statistical Analysis of Data.
**

An introduction to the principles and methods of applied statistics. Topics include exploratory data analysis, sampling distributions, confidence intervals, hypothesis testing, regression analysis, analysis of variance and categorical data analysis. Extensive reliance on authentic data and statistical computer software. Not open to students who have taken Math 252, or have taken or are taking Econ 265 or Econ 166.
(Quantitative and Symbolic Reasoning.)
Maximum enrollment, 25.
The Department.

**
254 F,S
Statistical Modeling and Applications.
**

A continuation and extension of the study of statistics begun in 252 or 253. Topics include simple and multiple regression, analysis of variance, categorical data analysis, logistic regression, and nonparametric methods designed to test hypotheses and construct confidence intervals.
(Quantitative and Symbolic Reasoning.)
Prerequisite, Math 252 or Math 253; students who have taken any introductory statistics course at Hamilton, or have a score of 4 or 5 in AP Statistics may enroll with the instructor’s permission. May not be taken by students who have taken or are taking Econ 400.
Maximum enrollment, 25.
Kuruwita.

**
313 S
Knot Theory.
**

An introduction to knot theory. Topics include classification of different types of knots, the relations between knots and surfaces, and applications of knots to a variety of fields.
(Quantitative and Symbolic Reasoning.)
Prerequisite, Math 224.
Ceniceros.

**
314 F,S
Real Analysis.
**

An introduction to analysis. Topics include completeness of the real numbers, cardinality, sequences, series, real-valued functions of a real variable, limits, and continuity.
(Writing-intensive.)
(Quantitative and Symbolic Reasoning.)
Prerequisite, 116 or 216, and 224.
Maximum enrollment, 20.
Kantrowitz, Dykstra.

**
[315 S]
Functional Analysis.
**

An introduction to functional analysis. Topics include metric and normed linear spaces, including sequence spaces, function spaces, Hilbert and Banach spaces; Fourier series, and bounded linear operators.
(Quantitative and Symbolic Reasoning.)
Prerequisite, 314 or consent of instructor.

**
318 S
Complex Analysis.
**

An introduction to the theory of analytic functions of a complex variable: Cauchy-Riemann equations, contour integration, Cauchy-Goursat theorem, Liouville theorem, Taylor and Laurent expansions, Residue theory.
(Quantitative and Symbolic Reasoning.)
Prerequisite, 314.
Kantrowitz.

**
322 S
Graph Theory.
**

An introduction to the theory and applications of graph theory. Topics include: trees; connectivity; Eulerian and Hamiltonian graphs; vertex-, edge- and map-colorings; digraphs; tournaments; matching theory; planarity and Ramsey numbers.
(Quantitative and Symbolic Reasoning.)
Prerequisite, 224 or CS 123.
Cockburn.

**
[324 S]
Linear Algebra II.
**

A continuation of 224, with emphasis on the study of linear operators on complex vector spaces, invariant subspaces, generalized eigenvectors and inner product spaces.
(Quantitative and Symbolic Reasoning.)
Prerequisite, 224.

**
325 F,S
Modern Algebra.
**

An introduction to the three fundamental structures of abstract algebra: groups, rings and fields.
(Writing-intensive.)
(Quantitative and Symbolic Reasoning.)
Prerequisite, 224.
Maximum enrollment, 20.
The Department.

**
[335 S]
Differential Equations II.
**

A continuation of 235, with emphasis on techniques for studying nonlinear dynamical systems. Topics include equilibria in nonlinear systems, bifurcations, limit sets, the Poincare-Bendixson theorem, strange attractors, discrete dynamical systems and symbolic dynamics.
(Quantitative and Symbolic Reasoning.)
Prerequisite, 235 and 314.

**
337 S
Partial Differential Equations.
**

Theory and applications of partial differential equations. Topics include separation of variables, Fourier series and transforms, and the Laplace, heat and wave equations.
(Quantitative and Symbolic Reasoning.)
Prerequisite, Math 224 and Math 235.
Dykstra.

**
351 F
Probability Theory and Applications.
**

An introduction to probability theory, including probability spaces, random variables, expected values, multivariate distributions and the central limit theorem, with applications to other disciplines and an emphasis on simulation as an exploratory tool.
(Quantitative and Symbolic Reasoning.)
Prerequisite, 116 or 216, and 224. 224 may be taken concurrently.
Boutin.

**
[352 S]
Mathematical Statistics and Applications.
**

Study of the mathematical theory underlying statistical methodology. Topics include the law of large numbers, estimation, hypothesis testing, linear models, experimental design, analysis of variance and nonparametric statistics, with applications to a variety of disciplines.
(Quantitative and Symbolic Reasoning.)
Prerequisite, 351.

**
355 F
Mathematics of Machine Learning.
**

An introduction to machine learning with a focus on the mathematics required to perform various algorithms. Topics include linear mappings, inner product spaces, orthogonality, matrix decompositions, gradients, supervised and unsupervised machine learning, principal components analysis, and artificial neural networks. Familiarity with rudimentary computer programming recommended.
(Quantitative and Symbolic Reasoning.)
Prerequisite, Math 216 and Math 224.
Stone.

**
[361 S]
Number Theory and Cryptography.
**

Number theory is the study of the properties of the positive integers. Topics include divisibility, congruences, quadratic reciprocity, numerical functions, Diophantine equations, continued fractions, distribution of primes. Applications will focus on cryptography, the practice of encrypting and decrypting messages, and cryptanalysis, the practice of developing secure encryption and decryption protocols and probing them for possible flaws.
(Quantitative and Symbolic Reasoning.)
Prerequisite, 325 or consent of instructor.

**
[363 S]
Differential Geometry.
**

Differential geometry is the study of geometric properties of curves, surfaces, and their higher dimensional analogues using the methods of calculus. This course is an introduction to the differential geometry of curves and surfaces in three dimensional Euclidean space. Topics include Frenet frames for curves, Gaussian and mean curvature, the first and second fundamental forms, geodesics, and Gauss’s Theorema Egregium.
(Quantitative and Symbolic Reasoning.)
Prerequisite, Math 216 and Math 224W.

**
498 S
Seminar on Mathematics in Social Context.
**

Examines the role mathematics plays in the construction and perpetuation of social stratification, as well as the influence of social categorization on the development of mathematics and mathematicians. Works such as *Hidden Figures* by Margot Lee Shetterly, *Weapons of Math Destruction* by Cathy O’Neil, and *Radical Equations: From Mississippi to the Algebra Project* by Bob Moses ‘56 may be included. One-half course credit. Open only to mathematics concentrators.
(Social, Structural, and Institutional Hierarchies.)
Maximum enrollment, 20.
The Department.

**
[501 F]
Senior Seminar in Algebra.
**

An introduction to group theory with an emphasis on group actions. Students are responsible for providing examples, counterexamples, and proofs of theorems and regularly present their work in class. The course concludes with the students researching a topic in group theory of their own choosing. The topics covered in the course will include symmetric groups, dihedral groups, (subgroups of) general linear groups, projective linear groups, Lagrange's theorem, Orbit-Stabilizer theorem, Cauchy's theorem, and Sylow's theorems.
(Quantitative and Symbolic Reasoning.)
Prerequisite, 325.
Maximum enrollment, 12.

**
[502 F]
Senior Seminar in Mathematical Modeling.
**

The description of biological, physical, and social phenomena using the language of mathematics. Focuses on the construction, analysis, and critique of mathematical models using a broad range of techniques.
(Quantitative and Symbolic Reasoning.)
Prerequisite, Math 235 or consent of instructor.
Maximum enrollment, 12.

**
503 F
Senior Seminar in Statistics.
**

A continuation of studies in mathematical statistics and the analysis of data. Topics include maximum likelihood estimation, regression, analysis of variance and design of experiments.
(Quantitative and Symbolic Reasoning.)
Prerequisite, Math 351 and (252 or 253 or 254 or 352 or Econ 266) or permission of instructor.
Maximum enrollment, 12.
Kuruwita.

**
504 F
Senior Seminar in Topology.
**

Students jointly produce a textbook based on an outline provided. Topics include topological spaces, continuity of maps and homeomorphism. Spaces are described as connected and Hausdorff. The fundamental group is computed and used to classify various spaces.
(Quantitative and Symbolic Reasoning.)
Prerequisite, Math 314W or Math 325W.
Maximum enrollment, 12.
.

**
[505 F]
Senior Seminar in Graph Symmetries.
**

Focuses on symmetries of simple and directed graphs. Graphs studied include the integer lattice, Kneser graphs, hypercubes, Cayley graphs. Given an outline containing definitions, theorems, and conjectures, students find examples, proofs and counterexamples, and create a course text with their results. No prior knowledge of graph theory is needed.
(Quantitative and Symbolic Reasoning.)
Prerequisite, Math 325W.
Maximum enrollment, 12.

**
506 F
Senior Seminar in Philosophical Foundations of Mathematics.
**

The first half of this seminar focuses on the set theoretical foundations of mathematics, including ordered sets, ordinal and cardinal numbers, and the classic set paradoxes. Students will be given definitions for which they must find examples and theorems for which they must find proofs. Readings includes classic papers in the philosophy of mathematics by such authors as Bertrand Russell, Kurt Gödel, David Hilbert, A. J. Ayer and Henri Poincaré. Final paper required.
Prerequisite, Math 314W.
Maximum enrollment, 12.

**
508 F
Senior Seminar in Dynamics.
**

Various topics from discrete dynamics are explored by working through a series of exploratory modules. Students work in teams and present their findings to the class. Topics include fixed points and their classifications, cycles and their classifications, fractal sets, sensitive dependence and chaos, symbolic dynamics and Sharkovskii’s periodic point theorem.
(Quantitative and Symbolic Reasoning.)
Prerequisite, Math 314W.
Maximum enrollment, 12.
LeMasurier.

**
509 F
Senior Seminar in Applied Statistics.
**

An exploration into the analysis of data, using techniques from Math 252/253. The seminar will undertake to formulate questions of interest and then use appropriate statistical techniques to answer them, incorporating new techniques as necessary. An emphasis on survey data is anticipated. Much of the work will be done in teams, and much of class time will be student presentations of student work. The seminar will be particularly relevant to students who anticipate needing to both understand and produce data-based analyses in applied areas.
(Quantitative and Symbolic Reasoning.)
Prerequisite, Math 224W and (252 or 253 or 254) or permission of instructor.
Maximum enrollment, 12.
L Knop.

**
510 F
Senior Seminar in Applied Network Analysis.
**

Our world is built of networks: the internet, social networks, transportation networks, communication networks, biological networks. Natural and useful question include "What makes a network robust?” "Can we predict where failures might occur?” “What can we do to slow propagation of viruses along a network?” This courses will cover abstract mathematical properties of networks that can help us answer these questions. These will be examined in the context of both theoretical and real world networks. Further, student groups will analyze and report on a real world network of their choice.
(Quantitative and Symbolic Reasoning.)
Prerequisite, 314 or 325.
Maximum enrollment, 12.
Boutin.