MS Imaging Science: Curriculum & Requirements
The M.S. in Imaging Science curriculum is a combination of five of
the seven graduate core courses in imaging science (see below) and
elective courses appropriate for the candidate's background and
interests. The M.S. in Imaging Science requires 45 total credits, 37
of which must be taken at RIT.
Several tracks (concentrations) have been established for the M.S.
in Imaging Science (consult the Graduate Coordinator and/or faculty
involved in research
in these areas, for further information): Digital Image Processing,
Medical Imaging, Electro-Optical Imaging Systems, Remote Sensing, Color
Imaging, and Hard Copy Materials and Processes. Additional tracks may
be created for interested students. Students must enroll in either the
research-thesis or graduate paper/project option at the beginning of
their studies. Candidates who wish to enter the program but lack
adequate preparation may have to take bridge courses in mathematics,
chemistry, or physics before matriculating with graduate status.
Research Thesis Option - The thesis is to be based on
experimental evidence obtained by the candidate in an appropriate field
as arranged between the candidate and his or her advisor. Nine credit hours of thesis research is required. Research may
be conducted by experiments in Institute laboratories or by work done
in other laboratories (such as the candidate's place of employment). In
the latter case, the results must be fully publishable, the candidate's
adviser must be approved by the graduate coordinator, and the thesis
must be based on the candidate's dependent, original work, as it would
be if the work were done in Institute laboratories.
A student's thesis committee is composed of a minimum of three
people: the student's adviser and two additional members who hold at
least an MS in a field relevant to the student's research. Two
committee members must be from the graduate faculty of the center.
Graduate Paper/Project Option -
Students with demonstrated practical or research experience, approved
by the graduate coordinator, may choose the graduate project option (5
credit hours) in addition to 40 hours of core and elective courses.
This option takes the form of a systems course (a different course for
each track) and an associated project/paper. The graduate paper is
normally performed during the final quarter of study. Both part- and
full-time students may choose this option, with the approval of the
graduate coordinator.
Typically a minimum of two years is required for the M.S. in Imaging
Science, if the degree is pursued on a full-time basis. Whether a
student pursues the thesis or project/paper option, all degree
requirements must be completed within seven years of the first course
taken for the degree.
Admission Requirements
Admission will be granted to graduates of accredited degree-granting
institutions whose undergraduate studies have included at least the
following courses in the major areas of study: mathematics, through
calculus and including differential equations; and a full-year of
calculus-based physics, including modern physics. It is assumed that
students can write a common computer program.
Applicants must demonstrate to the Graduate Admissions Committee of the
Center for Imaging Science that they have the capability to pursue
graduate work successfully. Normally this will include the submission
of a statement of purpose, presentation of undergraduate academic
records, letters of evaluation from individuals familiar with the
applicant�'s capabilities, and any other pertinent data furnished
by the applicant. While previous high academic achievement does not
guarantee admission, such achievement or other unusually persuasive
evidence of professional promise is expected.
Applicants seeking financial assistance from the center must have all
application documents submitted to the Office of Graduate Enrollment
Services by February 15 for the next academic year. Those seeking
funding from the center are also required to take the GRE. Students
whose native language is not English must demonstrate proficiency in
English, as evidenced, for example, by a minimum TOEFL score of 600
(paper-based), 250 (computer based), or 100 (Internet-based). Students
whose native language is not English are advised to obtain as high a
TOEFL score as possible if they wish to apply for a teaching or
research assistantship. These candidates are also encouraged to take
the TSE-A (Test of Spoken English), in order to be considered for
financial assistance.
Assistantships and Financial Assistance
Funding is restricted to students who choose the research thesis option and are full-time students, and is usually available only for a subset of entering M.S. students. Qualifying students typically are funded as Graduate Teaching Assistants during their first year. Graduate Research Assistantships may be available during the second year. Currently, the stipend for a three-quarter academic year is $15,000.
Prorated Summer quarter support is generally available once a student has begun work with a research advisor. Tuition is also paid for full-time funded students. Funding is guaranteed only for the first year. A small number of partial scholarships are available. These only cover a portion of the tuition costs. Students accepting these scholarships are required to pay the remaining tuition costs each quarter, as well as all living expenses from their own funds.
Further Information
For more information on Imaging Science graduate program requirements, policies, and procedures, please see the Graduate
Handbook.
MS Imaging Science Core Courses*
|
| Course Number |
Class Name |
Credit Hours |
| 1051-706,707,708 |
Imaging Science Seminar |
3**
|
| 1051-716 |
Fourier Methods for Imaging
|
4
|
| 1051-718 |
Digital Imaging Mathematics
|
4 |
| 1051-719 |
Radiometry
|
4
|
| 1051-720 |
The Human Visual System
|
4
|
| 1051-733 |
Optics
|
4 |
| 1051-713 | Probability, Noise, and System Modeling
| 4 | | 1051-782 | Digital Image Processing
| 4 |
*MS students take 5 of 7 of these core courses, where the 5 selected courses must include Fourier Methods for Imaging.
**The Imaging Science Seminar sequence is required for students
pursuing the MS thesis, and constitutes 3 of the 9 required thesis
research credits.
MS Imaging Science tracks (due to recent changes in the MS
core curriculum, prospective students should consult the Graduate
Coordinator as to the present status of these tracks):
| Color Imaging Track |
| Course Number |
Class Name |
Credit Hours |
| 1051-774 |
Vision & Psychophysics |
4 |
| 1051-775 |
Applied Colorimetry |
4 |
| 1051-749 |
Color Reproduction |
4 |
| 1051-726 |
Programming for Scientists & Engineers |
4 |
| 1051-816 |
Color Systems‡ |
4 |
|
Elective |
4 |
| Elective choices are: Geometrical Optics,
Physical Optics, Digital Image Processing, Statistical
Analysis for Engineering, and Statistics & Computation
for Imaging Science |
| Digital Imaging Track |
| Course Number |
Class Name |
Credit Hours |
| 1051-782 |
Intro to Digital Image Processing |
4 |
| 1051-784 |
DIP: Spatial Pattern Recognition |
4 |
| 1051-792 |
Image Understanding |
4 |
| 1051-746 |
Probability & Statistic for Imaging Science I |
4 |
| 1051-713 |
Noise & Random Processes‡ |
4 |
|
2 Electives |
8 |
| Elective choices are: Speech & Image Compression,
Adaptive Signal Processing, ST Random Image Modeling,
and Information Theory |
| Remote Sensing Track |
| Course Number |
Class Name |
Credit Hours |
| 1051-761 |
Remote Sensing: Radiometric |
4 |
| 1051-762 |
Remote Sensing: Image Data Analysis |
4 |
| 1051-763 |
Remote Sensing: Multispectral |
4 |
| 1051-765 |
Remote Sensing Systems‡ |
4 |
|
3 Electives |
12 |
| Elective choices are: Introduction to DIP,
DIP: Spatial Pattern Recognition, Noise & Random Processes,
Geometrical Optics, Physical Optics, and Principles of
Solid State Arrays |
Nanoimaging (under development)
|
| Course Number |
Class Name |
Credit Hours |
| 1051-7xx |
Introduction to Light, Electron & Scanning Probe Microscopy |
4 |
| 1051-7xx |
Fundamentals of Radiation-Matter Interactions |
4 |
| 1051-7xx |
Nanoscale Science & Technology of Imaging Systems |
4 |
|
4 Electives |
16 |
| Elective choices are: Electron Microscopy; Scanning Probe Microscopy, Image Processing, and System Optimization; Principles of Light, X-Ray, and Neutron Scattering; Molecular Spectroscopy; Nano and Microengineering; Micro and Nano-photonics; Principles of Semiconductor Devices; Geometrical Optics; Physical Optics; Magnetic Resonance Imaging; Multivariate Statistics-Imaging Science; Solid State Science; Experimental Techniques: Thin Films |
| Medical Imaging Track |
| Course Number |
Class Name |
Credit Hours |
| 1051-730 |
MRI |
4 |
| 1051-797 |
Prin. CT Imaging |
4 |
| 1051-812 |
Medical Imaging Systems‡ |
4 |
|
3 Electives |
12 |
| Elective choices are: Digital Image Processing,
Spatial Pattern Recognition, Noise and Random Processes,
Vision & Psychophysics, and Adaptive Signal Process |
| Electro-Optical Imaging
Systems Track |
| Course Number |
Class Name |
Credit Hours |
| 1051-736 |
Geometrical Optics |
4 |
| 1051-737 |
Physical Optics |
4 |
| 1051-739 |
Solid State Imaging Arrays |
4 |
| 1051-738 |
Optical Image Formation‡ |
1 |
|
3 Electives |
12 |
| Elective choices are: Astronomical Instrumentation
& Techniques, Introduction to Digital Image Processing,
Remote Sensing & Image Analysis I - III, Electro-Optics,
Semiconductor Physics, and Physics of Semiconductor Devices
I |
‡ System Course, not required for research thesis
option
Click
here for the official RIT course descriptions for the
M.S. Imaging Science curriculum.
|
