Mathematics
Why study mathematics? Many of the new wonders that we take for granted in our modern technological society have mathematical ideas and applications as their basis, though this role is often hidden from view. Complex economic and planning decisions, scientific discoveries that improve our lives, and new technologies and products are often possible only after mathematical or statistical analysis, or a computer visualization, simulation, design and implementation based on mathematics. Therefore, mathematicians, as well as mathematically educated scientists, engineers and economists, make important daily contributions in the understanding and advancement of science, the improvement and discovery of new technology, and decision-making and planning in business, industry and government. Students interested in using their mathematical skills in solving real world problems are well prepared, by majoring or minoring in mathematics, for careers such as in the insurance industry, software design, data and systems analysis, scientific computing, combustion research, the animated movie industry, and cryptanalysis to name a few, or a graduate degree in a related technical field. Those students with a very strong interest in mathematics itself can pursue graduate study in mathematics in preparation for careers as university or college mathematics teachers and in the development of new mathematical and statistical concepts and methods as researchers in academia, government and industry.
The curriculum of the program in the Department of Mathematics is designed to provide a broad education in both theoretical and applied mathematics. It also develops the scientific knowledge and the problem solving, computing, and communications skills that are critical to a successful mathematically based career. This preparation is greatly enhanced by taking advantage of the wide variety of science and engineering courses available to students and developing good communications skills, both through technical courses and the strong humanities program. The program offers a solid grounding in the foundational areas of calculus, differential equations, linear algebra, discrete and combinatorial algebra, and probability and statistics. These basic courses are complemented by a varied selection of upper division courses for further elective study in areas such as numerical analysis, operations research, advanced statistics, mathematical modeling, optimization, and other advanced topics in mathematics. Students are encouraged to develop a strong background in an area of science or engineering through election of courses leading to a minor or double major. By appropriate course selection students may complete a double major in mathematics and another field such as computer science, physics, chemistry, applied biology, or economics.
PROGRAM GOALS AND OBJECTIVES
To provide a foundation for further learning as well as contributing to the general education of students, the programs at Rose-Hulman all have a heavy investment in mathematics and science in the first two years. The freshman and sophomore mathematics curriculum is designed to contribute to this foundation by ensuring that students are familiar with basic mathematical and statistical concepts, and mathematical and statistical reasoning and modeling. Students will also understand the use of mathematics in other disciplines as well as developing an appreciation of mathematics as a discipline in its own right. In addition, students will learn to be competent users of mathematics, especially in problem solving, and be able to effectively communicate mathematically. The curriculum makes strong use of computer methods to develop students’ mathematical understanding and to enhance their ability to use the computer in modeling, computation and problem solving.
For students seeking a major in mathematics, the curriculum prepares them for a mathematically based career after graduation or further graduate study. The major builds upon the goals and objectives of the freshman and sophomore curriculum. In addition to a deeper and broader study of mathematics, majors will further develop their ability to formulate and solve problems from a mathematical perspective, become familiar with the use of mathematics in other fields, and develop competence at the application of mathematics to at least one other field. Graduates will also be able to use technology effectively in mathematics and the application of mathematics. To complement these technical skills graduates will learn the professional skills of effective communication with both technical and non-technical audiences and the ability to work cooperatively with others.
DEGREE REQUIREMENTS
Major Concentrations: Mathematics majors choose to complete their program in one of four concentrations: Mathematics, Continuous Applied Mathematics, Discrete Applied Mathematics, or Statistics and Operations Research. The Mathematics concentration provides the foundational mathematical depth of a traditional mathematics major and is intended for students planning on graduate study in an area of mathematics. In applied mathematics there are two areas: the Continuous Applied Mathematics concentration and the Discrete Applied Mathematics concentration. Students selecting these concentrations may tailor their programs to interface with another major or to enhance industrial employment or graduate school opportunities. The Statistics and Operations Research concentration is recommended for students pursuing careers in actuarial science, graduate study in statistics, or employment in government or industry in a statistical capacity. It is strongly recommended that students considering graduate education in mathematics include MA 376 Abstract Algebra among their elective mathematics courses. Upon graduation a student may request the Head of the Mathematics Department to issue a letter attesting to the fact that the requirements in the chosen concentration have been completed.
Mathematics Coursework Requirements: All mathematics majors must complete a common core consisting of 39 credit hours of mathematics coursework, which provides breadth across the main areas of mathematics. A mathematics major must also complete an additional 12 credit hours of mathematics coursework specified for the selected major concentration plus an additional 12 credit hours earned in free elective mathematics or biomathematics courses. In addition, a mathematics major must complete 8 credit hours of either a senior thesis or project, meant as a capstone experience to the major. A total of 71 credit hours of mathematics courses is required for the major. None of the credits in the 71 hours above may be taken from the courses MA190, MA351-MA356, MA450 or MA223 (unless approved by the department head). These courses (except MA190) may be taken as free electives. Finally, a student taking a degree program in which mathematics is the primary major must also take MA190. A student whose second major is mathematics is not required to take MA 190, but is strongly encouraged to do so.
Common Required Core |
39 hrs. |
---|---|
MA 111, 112, 113 Calculus I, II, III | 15 hrs. |
MA 211 Differential Equations | 4 hrs. |
MA 212 Matrix Algebra and Systems of Differential Equations | 4 hrs. |
MA 275 Discrete and Combinatorial Algebra I | 4 hrs. |
MA 366 Functions of a Real Variable | 4 hrs. |
MA 371 Linear Algebra I | 4 hrs. |
MA 381 Introduction to Probability with Applications to Statistics | 4 hrs. |
Mathematics Concentration Core |
12 hrs. |
|
---|---|---|
Three courses selected as follows: | ||
MA 367 | Functions of a Complex Variable |
4 hrs. |
MA 376 | Abstract Algebra |
4 hrs. |
One of the following |
4 hrs. |
|
MA 433 | Numerical Analysis | |
MA 436 | Introduction to Partial Differential Equations | |
MA 446 | Combinatorial Optimization | |
MA 481 | Introduction to Mathematical Statistics |
Continuous Applied Mathematics Concentration Core | 12 hrs. | |
---|---|---|
Three courses selected per the list below. Students completing the Continuous Applied Mathematics Concentration are strongly urged to complete mathematics coursework in statistics as elective coursework. | ||
MA 330 | Vector Calculus | 4 hrs. |
MA 336 | Boundary Value Problems | 4 hrs. |
MA 433 | Numerical Analysis | 4 hrs. |
Discrete Applied Mathematics Concentration Core | 12 hrs. | |
---|---|---|
Three courses selected per the list below. Students completing the Discrete Applied Mathematics Concentration are strongly urged to complete mathematics coursework in statistics as elective coursework. | ||
MA 375 | Discrete and Combinatorial Algebra II | 4 hrs. |
MA 444 | Deterministic Models in Operations Research | 4 hrs. |
One of the following | 4 hrs. | |
MA 376 | Abstract Algebra | |
MA 475 | Topics in Discrete Mathematics | |
MA 476 | Algebraic Codes | |
MA 477 | Graph Theory |
Statistics and Operations Research Concentration Core |
12 hrs. |
|
---|---|---|
Three courses selected per the list below. Students completing the Statistics and Operations Research Concentration are strongly urged to complete mathematics coursework in applied mathematics as elective coursework. | ||
MA 382 | Introduction to Statistics with Probability | 4 hrs. |
MA 444 | Deterministic Models in Operations Research |
4 hrs. |
One of the Following | 4 hrs. | |
MA 445 | Stochastic Models in Operations Research | |
MA 446 | Combinatorial Optimization | |
MA 481 | Introduction to Mathematical Statistics | |
MA 485 | Applied Regression Analysis and Introduction to Time Series | |
MA 487 | Design of Experiments | |
It is strongly suggested that the student take as many of the above courses as possible. |
Free Mathematics Electives—12 hrs.
Additional mathematics and biomathematics coursework in courses numbered 300 or above (MA 351- MA 356, MA 450, BMTH496-498 not allowed).
MA 190 – Contemporary Mathematical Problems (2 hrs.) A student taking a degree program in which mathematics is the primary major must also take MA 190. A student whose second major is mathematics is not required to take MA190, but is strongly encouraged to do so.
Senior Project or Thesis (8 hrs.) A student must complete either a Senior Project, equivalent to the 8 credit hours of MA 491 – 494, or a Senior Thesis, equivalent to the 8 credit hours of MA 496 – 498. The project and thesis are each important capstone experiences for the mathematics major, representing sustained efforts to solve a complex problem from industry, mathematics modeling or application, or mathematical research.
Senior Project Option: Students seeking to do a senior project must complete a written project involving effort equivalent to the 8 credit hours of MA491 – 494. Specifically,
- MA 493 and MA 494 must be taken in separate terms.
- The requirement of MA 491-492 may be fulfilled through some project experience (such as an internship) and another 300-level or above mathematics course (4 hours), as approved by the project advisor. The course substitution procedure must be used.
- The project must involve work done by the student(s) to solve a problem presented by an external sponsor or a problem with a substantial mathematical modeling, application and/or computational content. The written project submission must be approved by the advisor and/or sponsor and must be presented publicly to the department.
Senior Thesis Option: Students seeking to do a senior thesis must complete a written thesis involving effort equivalent to the 8 credit hours of MA496 – MA 498. Specifically,
- MA 497 and MA 498 must be taken in separate terms.
- The requirement of MA 496 may be fulfilled through some undergraduate research experience and an additional 300-level or above mathematics course (4 hours), as approved by the thesis advisor. The course substitution procedure must be used.
- The thesis must involve creative work done by the student and a significant portion of this work must have been done by the student individually (not as part of a team).
- The approved written thesis must be submitted to the department for archiving and must be publicly presented to the department.
Summary of Requirements | |||
---|---|---|---|
Mathematics Coursework - core, concentration and electives (MA351-MA356, MA450, BMTH496-498 not allowed) | 63 hrs. | ||
Mathematics Senior Project/Thesis | 8 hrs. | ||
MA 190 - Contemporary Mathematical Problems (primary major only) |
2 hrs. | ||
Physical and Life Sciences* | 24 hrs. | ||
Computer Science** | 8 hrs. | ||
Humanities and Social Science (standard requirement, one course must be RH330) | 36 hrs. | ||
Technical Electives*** | 24 hrs. | ||
Free Electives | 28 hrs. | ||
Miscellaneous**** | 2 hr. | ||
Total hours required for graduation |
195 hrs. |
||
* | PH 111, 112, and 113 — Physics I, II, and III | 12 hrs. | |
BIO 101 — Essential Biology (or higher-level BIO course) | 4 hrs. | ||
CHEM 111 — General Chemistry I | 4 hrs. | ||
4 additional credit hours in Physical or Life Sciences | 4 hrs. | ||
** | CSSE 120 — Introduction to Software Development | 4 hrs. | |
CSSE 220 — Object-Oriented Software Development | 4 hrs. | ||
MA 332 - Introduction to Computational Science - may be taken instead of CSSE 220 but then MA 332 cannot be counted towards the 63 hours of mathematics coursework | |||
*** | 200 level or above coursework, approved by the major advisor, in areas of science, engineering, or economics in which 12 credit hours constitute a coherent set of three courses representing a specific area of technical depth and 12 credit hours represent technical breadth. Coursework in mathematics and biomathematics is not allowed. | 24 hrs. | |
**** | CLSK 100 — College and Life Skills MA 200 - Career Preparation (primary major only) |
1 hr. 1 hr. |
SUGGESTED SCHEDULE
The schedule (Course Sequence) on the right is a suggested schedule only. Scheduling of courses may be altered, subject to the approval of the advisor, in order to take advantage of advanced placement or to accommodate a second major, area minor or other special program. However, note that some courses are offered only at certain times during the year, and all prerequisites must be met. In the schedule an MA elective is either a concentration elective or free math elective, as described above, and a science elective is a physical or life science elective as defined on this page.
Alternate Science Schedule: The recommended science schedule of six science courses starts with PH 111. If CHEM 111 is required in the fall quarter because of a double major or minor, then the alternate science sequence may be completed by taking the second science course in each place where a choice is given. Two science courses are to be taken in the winter quarter of freshman year.
COMPUTATIONAL SCIENCE MAJOR (CPLS) (Second Major Only)
Computational methods are widely employed in science and engineering for simulation, experimentation, analysis, and design. In many areas the use of high-performance computing is essential. The Computational Science major provides Rose-Hulman students with the opportunity to add to their primary major a second major that increases their knowledge and skill in applied scientific and engineering computation.
Requirements for a second major in Computational Science (71 credit hours)
The second major in Computational Science is open to all students. It requires 71 credit hours, including a 51 credit hour core and a 20 credit hour specialization. The courses used to satisfy the requirements in the Advanced Core may not be counted toward any other major or minor. All Computational Science programs of study are subject to approval by the Chair of the Computational Science Steering Committee.
Computational Science Core (51 credit hours)
Fundamentals (31 credit hours)
- MA 111, 112, 113 Calculus I, II, III
- MA 211 Differential Equations
- MA 212 Matrix Algebra and Systems of Differential Equations
- CSSE 120 Introduction to Software Development, or any of BE 100, CE 111 (plus 2 cr.), CHE 110 (plus 2 cr.), ME 123
- MA 332 Introduction to Computational Science
Advanced (20 credit hours; these courses may not be counted toward any other major or minor)
- CSSE/MA 335 Introduction to Parallel Computing
- MA 336 Boundary Value Problems
- MA 342 Computational Modeling
- MA 435 or ME 422 Finite Difference Methods, Finite Element Methods for Engineering Applications
Any course from the list of Approved Computational Science Electives (or another upper-level course if approved by the Chair of the Computational Science Steering Committee):
- BE 340 Biomedical Signal Processing
- BE 510 Biomedical Signal and Image Processing
- BMTH 312 Bioinformatics
- BMTH 413 Computational Biology
- CHE 310 Numerical Methods for Chemical Engineers
- CE 310 Computer Applications in Civil Engineering
- CSSE 304 Programming Language Concepts
- ECE 480/OE 437 Introduction to Image Processing
- ECE 483 DSP System Design
- EMGT 534/MA 534 Management Science
- MA 323 Geometric Modeling
- MA 384 Data Mining
- MA 433 Numerical Analysis
- MA 434 Topics in Numerical Analysis
- MA 435 Finite Difference Methods
- MA 439 Mathematical Methods of Image Processing
- MA 444 Deterministic Models in Operations Research
- MA 446 Combinatorial Optimization
- ME 422 Finite Element Methods for Engineering Applications
- ME 427 Introduction to Computational Fluid Dynamics
- ME 430 Mechatronic Systems
- ME 522 Advanced Finite Elements Analysis
- ME 536 Computational Intelligence in Control Engineering
- PH 540 Computer Physics
Area of Concentration (20 credit hours): Each student must complete 20 credit hours of advanced work reflecting an Area of Concentration within Computational Science. Courses used to satisfy the core requirements may not be used to satisfy the area of concentration requirements. The 20 credit hours shall consist of at least 16 credit hours within a single Area of Concentration, as specified below, and an additional 4 credit hours from any of the Areas of Concentration, or from the list of Approved Computational Science Electives. Exceptions may be made on occasion (e.g. when an appropriate special topics course has been taken).
Computational Methods
- MA 371 or MA 373 Linear Algebra I, Applied Linear Algebra for Engineers
- MA 433 Numerical Analysis
- Eight credit hours chosen from BMTH 413, CSSE 304, CSSE/MA 473, MA 384, MA 386, MA 434, MA 435, MA439, MA 444, MA 446, MA 485, ME 422
Computational Mechanics
- MA 435 or ME 422 Finite Difference Methods, Finite Element Methods for Engineering Applications
- ME 401 Foundations of Fluid Mechanics
- ME 427 Introduction to Computational Fluid Dynamics
- ME 522 Advanced Finite Element Analysis
Computational Signals and Image Processing
- ECE 380 Discrete-Time Signals and Systems
- ECE 480/OE 437 Introduction to Image Processing
- ECE 483 DSP System Design
- MA 439 Mathematical Methods of Image Processing
Computational Physics and Chemistry
- CHEM 361 Physical Chemistry I
- CHEM 362 Physical Chemistry II
- CHEM 363 Quantum Chemistry & Molecular Specroscopy
- OE 570 Nanomedicine
- PH 540 Computer Physics
Computational Biomedics
- BE 482/MA 482 Bioengineering Statistics
- BE 535/OE 535 Biomedical Optics
- BE 541/ECE 584 Medical Imaging
- BMTH 310 Mathematical Biology
- BMTH 413 Computational Biology
MINOR IN MATHEMATICS
Any student not pursuing a major or second major in either mathematics or in biomathematics may obtain a minor in mathematics by taking 10 or more mathematics courses as follows:
- Six courses in foundational mathematics
- Calculus, Differential Equations and Matrix Algebra: MA 111, MA 112, MA 113, MA 211, MA 212
- Basic Probability and Statistics or Basic Statistics: one of MA 223, MA 381, or MA382
- Sixteen additional credit hours of “upper division” courses:
- Courses selected from MA 275, all MA courses numbered 300 or higher (except MA351-356 and MA450, MA492-494, and MA496-498), all BMTH courses numbered 300 or higher (except BMTH 496-498), or other MA courses approved by the minor advisor for mathematics. Computer Science majors cannot use either MA 473 or MA 474 to satisfy both their computer science major requirements and the requirements of the mathematics minor.
Approval and Math Minor Form
All minors must be approved by the area minor advisor and the student’s advisor. The department has a form for the planning and approval of a mathematics minor.
Notes and Limitations on Requirements:
- Almost all students are required to take six foundational courses as a requirement for their major; therefore only four "extra courses" are required for most students.
- Only MA111, MA112, MA113, MA211, MA212 and one of MA223, MA381, or MA382 can be counted towards any combination of the multiple minors offered by the mathematics department.
- No student can take both MA 371 and MA 373 for credit.
- No student can take both MA223 and MA382 for credit
- Except as noted above, if MA 381 is being counted towards the four additional courses then, MA 223 may be taken and counted towards the Basic Probability and Statistics.
- Science and engineering, especially the most recent "high tech" developments, have sophisticated mathematical and statistical concepts and methodologies as their foundation. Thus a well chosen set of courses for a mathematics minor (or a second major in mathematics) will greatly enhance a student's analytical and computational skills. Students thinking of going on to graduate school should especially give consideration to this option.
AREA MINOR IN COMPUTATIONAL SCIENCE
Any student may obtain an area minor in Computational Science by taking the following courses:
- Five courses in foundational mathematics: MA111, MA112, MA113, MA211, MA212
- Basic computing course: CSSE 120 or departmental equivalent of at least 4 credit hours
- Introductory Computational Science courses:
- MA332 Introduction to Computational Science
- MA342 Computational Modeling
- Four credit hours of applied Computational Science course from list A
- Four credit hours of additional Computational Science course from list B
List A: Applied Computational Science courses
- MA323 – Geometric Modeling
- MA439 – Mathematical Methods of Image Processing
- MA444 – Deterministic Models in Operations Research
- CSSE351 – Computer Graphics
- CSSE451 - Advanced Computer Graphics
- CSSE413 – Artificial Intelligence
- CSSE453 – Topics in Artificial Intelligence
- CSSE461 – Computer Vision
- CSSE463 - Image Recognition
- CE522 - Advanced Finite Element Analysis
- ME422 – Finite Elements for Engineering Applications
- ME427 - Introduction to Computational Fluid Dynamics
- ME511 - Numerical Methods for Dynamic Systems Analysis
- ME522 - Advanced Finite Elements Analysis
- 4XX – Introduction to MEMS:Fabrication and Applications
- 5XX – Advanced Topics in MEMS
- CHE521 – Advanced Chemical Engineering Computation
- BE510 – Biomedical Signal and Image Processing
- EMGT526 - Technology Forecasting
- MA534/EMGT534 - Management. Science
- ECE420 - Nonlinear Control Systems
- ECE480//PH437 – Introduction to Image Processing
- ECE582/PH537 – Advanced Image Processing
- ECE483 - DSP System Design
List B: Additional Computational Science courses
- MA/CSSE335 - Introduction to Parallel Computing
- MA433 - Numerical Analysis
- MA434 – Topics in Numerical Analysis
- MA348 - Continuous Optimization
- MA446 - Combinatorial Optimization
- CSSE304 - Programming Language Concepts
- CSSE371 - Software Requirements and Specification
Electives not on list A or B may be substituted with other courses with the approval of the area minor advisor.
The minor must be approved by the area minor advisor for Computational Science and the student's advisor. The department has a form for the planning and approval of a minor.
Notes and limitations on requirements
- Almost all students are required to take the five foundational courses as a requirement for their major
- Most majors should be able to apply the basic computing requirement and/or one of the elective courses towards their major.
- Math majors or double majors are not allowed to count MA332 and MA342 for both the minor and the major.
- A student may not apply the four upper-division courses toward both this minor and a math or statistics minor.
AREA MINOR IN STATISTICS
Any student not pursuing a major or second major in mathematics nor in biomathematics may obtain an area minor in statistics by taking ten or more mathematics courses (43 credit hours) including the following:
- 19 credit hours - Foundational Mathematics Courses:
- MA 111 Calculus I
- MA 112 Calculus II
- MA 113 Calculus III
- MA 212 Differential Equations and Matrix Algebra
- 8 credit hours - Required Statistics and Probability Courses
- MA 381 Introduction to Probability with Applications to Statistics
- One of the following:
- MA223 Engineering Statistics I
- MA382 Introduction to Statistics with Probability
- If MA 381 is taken before MA223/MA382, it will be strongly recommended the student take MA382 instead of MA223.
- 16 credit hours - Secondary Statistics Courses
- Four courses selected from the following list, at least two of which must be starred (*). Statistics courses not on this list may count towards the minor if approved by the statistics minor advisor.
- MA 383* Engineering Statistics II
- MA 385 Quality Methods
- MA 386* Statistical Programming
- MA 387 Statistical Methods in Six Sigma
- MA 445 Stochastic Models in Operations Research
- MA 481 Mathematical Statistics
- MA 482* Bioengineering Statistics
- MA 485* Applied Regression and Time Series Analysis
- MA 487* Design of Experiments
- MA 480 Topics in Probability and Statistics
All area minors in Statistics must be approved by the statistics minor advisor and the student's advisor. The department has a form for the planning and approval of a statistics minor.
Notes and Limitations on Requirements
- Almost all students are required to take the foundational mathematics courses plus one probability or statistics course as a requirement for their major; therefore, only five "extra courses” are required for most students.
- Only MA111, MA112, MA113, MA211, MA212 and one of MA223, MA381, or MA382 can be counted towards any combination of the multiple minors offered by the mathematics department.
- No student can take both MA223 and MA382 for credit.
Plan of Study
Notes:
*MA 332 - Introduction to Computational Science - may be taken instead of CSSE 220 but then MA 332 cannot be counted towards the 63 hours of mathematics coursework
**MA 200 - Career Preparation - may be taken in the winter quarter of the sophomore year
Notes and Definitions
- The suggested four year plan is a guideline.
- Close consultation with the advisor on electives is required, especially for electives after the freshman year, or if a double major or minor is planned.
The following definitions of electives are specific to the Mathematics Department.
- Math Elective: A course either required by the concentration or a true math elective.
- Science Elective: Any Physical or Life Sciences elective (not Computer Science) at any level.
- Technical Elective: Non-mathematics courses numbered 200 or above in Engineering, Science or Economics; coursework in mathematics and biomathematics is not allowed.
- Free Elective: Any course.