Interdisciplinary graduate programs promote intellectual growth
and offer distinct challenges to conventional thinking. They address
areas that are too broad or too complex to be dealt with adequately
by a single academic discipline. Interdisciplinary programs are
essential for the education of graduate students involved in Technogenesis
projects, i.e., projects concerned with the nurturing of technology
from concept to realization. It is also the case that some interesting
scholarly areas involve the blending of two or more academic disciplines,
for example, management science juxtaposes operations research and business.
Students interested in an interdisciplinary program at either the
master's level or the Ph.D. level may proceed as follows:
- The student outlines in writing the program that he or she would
like to undertake and submits it to the Dean of Graduate Studies.
- If the Dean of Graduate Studies approves the program, an interdisciplinary
advisory committee is appointed to study the program.
- If the committee accepts the program, the student and the committee
prepare a Study Plan and submit it to the Dean of Graduate Studies
for approval.
- One member of the committee is appointed to be the student's
Faculty Advisor and the committee performs the usual departmental
functions.
In addition, Stevens offers a variety of specific interdisciplinary
programs. These programs are described below.
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Master of Science - Construction Management
The construction management curriculum offers an excellent opportunity
for the construction professional and the engineering manager to
direct construction firms and projects in an effective, efficient
and professional manner while dealing with the delicate environmental
issues of today’s complex marketplace. The program consists
of five core and five elective courses of a practical nature, including
those dealing with financial, legal, safety and administrative aspects
relevant to the construction industry. Theory is integrated into
realistic problems that arise within today’s competitive construction
arena. The program has been designed with flexibility so that the
student’s interest in a special area can be satisfied. An
undergraduate degree in engineering or related disciplines from
a recognized school is a prerequisite for graduate study in construction
management.
Core Courses
- CM 509 Construction Cost Analysis and Estimating
- CM 541 Project Management for Construction
- CM 550 Construction Contract Law I
- CM 571 Practicum in Construction Management
- CM 580 Construction Management
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Master of Science – Security Management and Forensics
An interdisciplinary program between the Department of Computer
Science and the Howe School of Technology Management, the M.S. in
Security Management and Forensics provides master’s level
training in security operations, security risk management and security
forensics, as well as a formal means for recognition of skills in
these areas. Students who successfully complete the program receive
an Interdisciplinary Computer Science/Technology Management master’s
degree with a concentration in Security Management and Forensics,
as well as a Graduate Certificate in Security Management and Forensics.
Applicants should have a B.S. degree in Computer Science, Electrical
Engineering, Telecom Management or a similar field. A GPA of at
least 3.0 is required. The program includes 12 courses, as follows:
Core Courses
- CS 590 Introduction to Data Structures and Algorithms
- CS 540 Fundamentals of Software Engineering
- TM 601 Principles of Applied Telecommunications Technology
- TM 675 Security Economics
- CS 573 Fundamentals of CyberSecurity
- CS/TM 694 E-Business Security and Information Assurance
- CS/MIS 665 CyberSecurity Forensics
- MGT 710 Risk Management Methods and Applications
Elective Courses (choose four from the following, subject to advisor
approval)
- CS 520 Introduction to Operating Systems
- CS/TM 613 Knowledge Discovery & Data Mining
- CS 561 Database Management Systems I
- TM 610 Business Information Networks or CS 666 Information
Networks I or CS 521 TCP/IP Networking
- CS 668 Foundations of Cryptography
- CS 693 Cryptographic Protocols
- MIS 645 Cybersecurity Principles for Managers
- MIS 646 Enterprise Architectures for Information Security
- MIS 647 Information Security and the Law
- MGT 690 Organization Theory and Design
- SYS 611 Modeling and Simulation
Master of Science - Information Systems
The following tracks are designed to meet the increasing need
for information technology professionals with both managerial and
technical skills. These interdisciplinary programs involve the School
of Technology Management and the Computer Science department. For
complete description and additional information about the Master
of Science - Information Systems program, please refer to the School
of Technology Management section of the Catalog.
- Computer Science Concentration
- E-Commerce Technical Track
- Information Security
- Integrated Information Architecture Track
- Quantitative Software Engineering Track
- Systems Engineering Track
- Telecommunications Management Track
Master of Science - Telecommunications
Management
The School of Technology Management administers the interdisciplinary
graduate program in Telecommunications Management. This program,
which leads to a Master of Science degree, is offered jointly with
the Department of Electrical and Computer Engineering. A four-course
graduate program leading to a Graduate Certificate in Telecommunications
Management is also available. Please refer to the School
of Technology Management section of this catalog for a complete
description of this program and its courses.
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Integrated Product Development
The increasing demand placed on the military and commercial sectors
to improve the quality and reliability of engineering systems while
cutting costs in a rapidly changing technological world are creating
new challenges for industry and government personnel responsible
for planning and leading multidisciplinary product development projects.
The traditional disciplinary engineering programs do not address
the skill set, competencies, and practices needed for integrated
product development. The Charles V. Schaefer, Jr. School of Engineering and Science,
a leader in engineering education, is offering both graduate certificate
and degree programs in Integrated Product Development that stress
the design, manufacture, implementation and life-cycle issues of
engineering systems. The programs focus on innovative designs and
methodologies, and on new materials and process technologies in
new product development. The programs aim to provide an innovative
view of the landscape of product development to practitioners from
different engineering disciplines, to enhance their practice of
engineering today and to position them for career growth in the
global economy.
The Integrated Product Development degree is an integrated Master
of Engineering degree program focusing on the integrated and multidisciplinary
aspects of product development. The core courses emphasize the design,
manufacture, implementation, and life-cycle issues of engineering
systems. The remaining courses provide a disciplinary focus. The
program embraces and balances qualitative as well as quantitative
aspects, and utilizes state-of-the-art tools and methodologies.
It aims to educate students in problem-solving methodologies, modeling,
analysis, simulation, and technical management. The program trains
engineers in relevant software applications and their productive
deployment and integration in the workplace. A full description
of this program can be found in the Mechanical Engineering department
section.
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Microelectronics and Photonics Science
and Technology
The Physics and Engineering Physics, Electrical and Computer Engineering
(ECE) and Materials Engineering Department each offer a Master of Engineering
degree with an interdisciplinary concentration in Microelectronics
and Photonics Science and Technology. Students are required to take
the departmental degree core courses and EE/Mt/PEP 507 Introduction
to Microelectronics and Photonics. A full description of the program
can be found in the Chemical, Biomedical and Materials Engineering
department section.
Product-Architecture and Engineering Program
The Master of Engineering in Product-Architecture and Engineering
degree program is intended to integrate the study of Product Design,
Computational Architecture and Engineering with production methodologies
and emerging materials. The program is supported by the Product
Architecture Lab. All students in the program must complete 10
courses (30 credits) comprised of five core courses and up to five
elective courses. Three of the five electives must be taken from
the recommended list (see below) of relevant graduate courses offered
by the Mechanical Engineering department. The remaining two courses
(6 credits) constitute the student’s elective field and will
consist of at least one course of "600-level or higher"
offered within the Product-Architecture and Engineering program.
Students may elect to complete a thesis (PAE 900: Thesis in Product Architecture
and Engineering) in lieu of completing of the two open electives.
A Bachelor of Science degree in Engineering, a B.I.D., a B.F.A., B.A.,
or B.S. in Industrial Design, or a B.Arch. (Bachelor in Architecture)
is needed for acceptance to the program. Applicants with undergraduate
degrees in other engineering or design disciplines may be required
to take appropriate undergraduate courses before being formally
admitted into the program.
Core Courses
- PAE 610 The Creative Form and the Digital Environment
- PAE 620 The Creative Form and the Production Environment
- PAE 630 Introduction to Interactive Digital Media
- PAE 640 Performative Environments
- PAE 800 Product Architecture and Engineering Design Project
The recommended courses from the Mechanical Engineering offerings
are:
- ME 520 Analysis and Design of Composites
- ME 564 Principles of Optimum Design and Manufacture
- ME 635 Simulation and Modeling
- ME 566 Design for Manufacturability
In order to graduate with a Master of Engineering in Product-Architecture
and Engineering, a student must obtain a minimum of a "B"
average in the major field as well as an overall average of "B"
in all the courses needed to meet the 30-credit requirement for
the degree. Please see the Office of Graduate Studies section on
student status.
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Ph. D. Program in Integrated Product Development Interdisciplinary)
An interdisciplinary Ph.D. program in Integrated Product Development
may be arranged by the Dean of Graduate Studies at the request of
the student. To oversee and approve such a program, the Dean of
Graduate Studies, on the advice of faculty responsible for the programs
involved, will designate a professor from each of the pertinent
disciplinary areas to serve on a special advisory committee. The
committee chairman will ordinarily be the professor who supervises
research.
To earn a doctoral degree, a student needs to complete at least
90 credits of which at least 30 are thesis credits. The mix of credits
will be decided upon by the student's principal advisor. Doctoral
study plans typically include all core course subjects in concurrent
engineering.
Doctoral students are also required to successfully complete two
days of qualifying examinations. The first day will be devoted to
the concentrated area of study and will cover topics studied in
the core courses. The second day of examinations will be organized
by the student's doctoral committee and will include selected topics
from the student's focused area of concentration. The student, with
guidance from the student's doctoral committee, will also present
the thesis proposal and an oral defense of the thesis as per the
guidelines published in the Graduate Student Handbook.
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Interdisciplinary Ph.D. Program Involving Physics and Materials
An interdisciplinary Ph.D. program is jointly offered by the Department
of Physics and Engineering Physics and the Materials Program in
the Department of Chemical, Biomedical and Materials Engineering.
This program aims to address the increasingly cross-cutting nature
of doctoral research in these two traditional disciplines, particularly
in the area of solid state electronics and photonics and in the
area of plasma and thin-film technology. The interdisciplinary Ph.D.
program aims to take advantage of the complementary educational
offerings and research opportunities in these areas offered by both
programs. Any student who wishes to enter this interdisciplinary
program needs to obtain the consent of the two departments and the
subsequent approval by the Dean of Graduate Studies. The student
will follow a study plan designed by his/her faculty advisor(s).
The student will be granted official candidacy in the program upon
successful completion of the qualifying exam that will be administered
according to the applicable guidelines of the Office of Graduate
Studies. All policies of the Office of Graduate Studies that govern
the credit and thesis requirements apply to students enrolled in
this interdisciplinary program. Interested students should follow
the normal graduate application procedures through the Dean of Graduate
Studies.
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The Systems Integration Initiative: The System Design and
Operational Effectiveness Program
As part of this initiative in the Charles V. Schaefer, Jr. School of Engineering and Science, participants can pursue a number of interdisciplinary
graduate certificate programs leading to a master’s degree
(M.E.) or a doctoral degree in Systems Engineering. All graduate programs
offered through this initiative involve a multidisciplinary approach
to engineering education by providing a blend of engineering, systems,
and management subjects. The traditional engineer and scientist
often lacks preparation in the human, financial and systems integration
skills necessary to make project teams more productive, improve
product and process quality and promote the advancement of high
technology for complex systems. Our programs are unique in that
we strive to create an engineer who is well prepared for a future
in the conception, definition, architecting, modeling and simulation,
integration, sustenance and management of modern complex systems
in a variety of market domains.
As technology advances, systems tend to become more complex. Complexity
can greatly increase the cost of a system over its life-cycle. Short-term
costs including research, design, test and production are only
part of the life-cycle cost. Post-production costs associated with
system operation, maintenance and support are often 70% to 80%
of the total cost.
The traditional approach to system design focuses on key performance
characteristics plus cost and schedule. Only near the end of design
is it determined exactly how the system-as-already-designed is to
be supported. This approach for complex systems compromises their
reliability, maintainability and supportability, thus greatly increasing
total ownership costs. At the same time, users are demanding more
quality. That is, users want more reliability and availability at
a lower total cost.
An integrated approach to system design and development can result
in an improved balance between system effectiveness and total ownership
cost. Such an approach must concurrently consider all aspects of
the entire life-cycle of the system/product from design to manufacture,
maintenance, repair and disposal; and bring potential cost drivers
to the attention of decision-makers early and in compelling ways.
The Charles V. Schaefer, Jr. School of Engineering and Science, as a leader
in engineering education, is offering a graduate degree in Systems
Engineering and a variety of certificate programs that stress
system design, modeling, analysis, operations, and life-cycle support.
The program objective is to provide an innovative view of the landscape
of system design to practitioners from different engineering disciplines,
to enhance their practice of engineering today, and to position
them for career growth in the global economy.
Uniqueness of the Curriculum and Delivery Format in the
System Design and Operational Effectiveness (SDOE) Program
The curriculum in the SDOE Program is focused on the requirements
of system integrators across a multitude of domains in the commercial
and aerospace sectors. A synopsis of the topical clusters is reflected
in the figure. These topical clusters were identified in collaboration
with our partners in the aerospace and defense, telecommunications,
IT,and automotive industries. Courses within the program address
all these functional clusters. A more detailed description of these
clusters can be obtained from the School fo Systems and Enterprises Web site (http://www.stevens.edu/sse/).
The delivery mechanism of our courses is also unique. All courses
in our program are offered in a unique week-long modular format
or offered in a completely web-based format. Modes of instruction
of the SDOE program have been structured to allow flexibility. The
week-long modular format minimizes time away from “home base”
while live and intensive weeklong courses, and associated group
exercises, ensure development of team building skills, leadership
development and the real-time negotiation and tradeoffs that characterize
reality. Participants are given reading assignments prior to the
instructional week. Further, participants pursing a degree or graduate
certificate have ten weeks subsequent to the instructional week
to complete their homework assignments and projects.
Systems Engineering Master’s Degree in the SDOE Executive
Education Program
The Systems Engineering degree is a multidisciplinary program that
includes a blend of engineering, systems thinking and management
subjects. The increasing complexity of systems, the pervasive realities
of global competitiveness, the enhanced focus on cost and profitability
and ever more challenging customer expectations have led a number
of premiere organizations in the defense and commercial sectors
to assume the role of system integrators. These organizations are
increasingly adopting an evolving business model that emphasizes
the selling of functionality, a solution or a capability, instead
of focusing on selling and providing systems, system elements and
products. The curriculum emphasizes the development of large-scale,
complex and multifunctional systems in a number of domains, while
also addressing the requirements of time-to-market focused organizations
in the commercial sector. Core courses in the SDOE Program have a
strong case study and project orientation to facilitate understanding
of the concepts discussed.
Admission to the SDOE program generally requires an undergraduate
degree in engineering or related disciplines with a "B"
average or better from an accredited college or university. Outstanding
applicants in other areas may be conditionally admitted subject
to the satisfactory completion of several introductory courses within
the program. Specific requirements are determined on an individual
basis depending upon the student’s background. It is required
that any applicants requesting research assistantship appointments
and applicants to the Ph.D. program provide evidence of the ability
to carry out independent work. Examples of such evidence include
the master's degree thesis work and/or completed work-related projects.
GRE scores are not required, but may be submitted in support of
the application. International students must demonstrate their proficiency
in the English language prior to admission by scoring at least 550
(213 for computer-based) on the TOEFL examination. Applications
for admission from qualified students are accepted at any time.
Graduates from this program will be prepared to work effectively
at the interface between engineering and management and to assume
professional positions of increasing responsibility. The program
consists of four core courses that must be completed if the applicant
is pursuing a Master’s or Doctoral degree:
ALL students must take the following two-course sequence:
- SDOE 625 Operational Effectiveness and Life-cycle Analysis
- SDOE 650 System Architecture and Design
OR, the following two course sequence:
- SDOE 651 Agile Systems Engineering and Architecting
- SDOE 780 Agile Development Strategies
Plus, two of the following four options:
- SDOE 611 Modeling and Simulation or SDOE 670 Forecasting
and Demand Modeling
- SDOE 612 Project Management for Complex Systems
- SDOE 660 Decision and Risk Analysis or SDOE 675 Integrated
Supply Chains
- SDOE 605 Systems Integration or SDOE 606 Accelerated Systems
Integration and Testing
A candidate may propose a customized track of six elective courses
leading to other specialties with approval from a faculty advisor.
At least two of the electives must be taken from the SEEM/SDOE
curriculum. Students should review other sections of the graduate
catalog for certificate options. Students are encouraged to take
an integrated four-course sequence leading to a graduate certificate
for the remaining four electives or four additional courses in
systems engineering. Many certificates are offered on-line via
web-based instruction.
Students in the SDOE program are required to take either a 3-credit
special project class (SDOE 800) or a 6-credit hour thesis (SDOE
900). Students should communicate with their academic advisor
to develop a study plan to coordinate the thesis versus the project
options and to match the student’s background, experience
and interests while satisfying the requirements for any of the
programs.
Doctoral Programs in Systems Engineering
The programs leading to the Doctor of Philosophy (Ph.D.) degree
are designed to develop a student's ability to perform research or high-level
design in systems engineering or engineering management. Admission
to the doctoral program is made through the departmental graduate
admissions committee and is based on review of the applicant's scholastic record.
A master’s degree is generally required before a student is
admitted to the doctoral program. Your master’s level academic
performance must reflect your ability to pursue advanced studies
and perform independent research. Typically a GPA of 3.5 or better
is required for admission to the Ph.D. program.
Ninety credits of graduate work in an approved program of study
beyond the bachelor’s degree are required for completion of
the doctoral program. Up to 30 credits obtained in a master’s
program can be included toward the doctoral degree. Of the remaining
60 credits, 15 to 30 credit hours of course work as well as 30 to
45 credit hours of dissertation work are required. Within two years
from the time of admission to the doctoral program, students must form
a Doctoral Advisory Committee (DAC) and take a written qualifying
examination that is intended to test their comprehension of undergraduate
and master’s level engineering fundamentals associated with
their general dissertation topic area.
The candidate’s graduate advisor serves as the chair of
the DAC, and the student should seek the assistance of his/her advisor
in identifying faculty who might serve on the committee. The graduate
committee should be composed of those faculty members who can best
assist the student in completing his/her graduate research. Each
member is added to the student’s committee after consenting
to serve. For the Ph.D., the advisory committee must include a minimum
of four members and its composition must be consistent with those guidelines
contained in the Graduate Student Handbook. Committee members are
expected to attend meetings as a collective body. Under unusual
circumstances, a member of the committee may attend a meeting via
video or telephone. However, a student’s advisory committee
must be physically present at all such meetings. Faculty participation
on graduate student committees is considered to be an important
part of SEEM faculty responsibilities. To this end, full-time SEEM
faculty are expected to attend all committee meetings for students
they advise or on the committees they serve.
The written and oral components of the qualification examination
must be successfully completed by all Ph.D. students. The intent
of the examination is to establish that the student is qualified
to pursue creative, original, independent research at a level expected
of Ph.D. students. The written portion of the examination requires
two weeks for completion. The oral component of the examination
is administered two weeks after the completion of the written portion.
Students must be registered during the semester that the examination
is taken. Students may not schedule the qualification examination
until they have an approved Study Plan. The qualification examination
is administered by the student’s DAC and at most one negative
vote by a committee member is permitted for the successful completion
of the examination. All members of the student’s advisory
committee must attend the oral portion of the examination. If performance
on the examination is unsatisfactory, one full semester must lapse
(15 weeks) before the examination is administered a second time.
Students failing the examination twice will be dismissed from the
program. At the discretion of the committee, a candidate may be
allowed to change his/her degree option from a Ph.D. to a Master's.
The result of the examination is recorded on a form furnished by
the Registrar’s Office on the day of the oral portion of the
examination. This form must be signed by each member of the student’s
advisory committee.
Students pursuing the Ph.D. are required to complete research
in the course of graduate study. To initiate the research effort
students are required to pass a preliminary examination upon successful
completion of the qualifying examination. The student is required
to prepare a research proposal that describes the content of the
research, the outcome anticipated, the contribution to the field
of endeavor and the creative content of the effort. This proposal
must be in a written form and must be presented to his/her committee
at a meeting where all committee members are present. Approval of
the research effort is signified by signatures of each committee
member on the cover page of the proposal. The signed research proposal
must be delivered to the SEEM/SDOE student records office for inclusion
in the student’s academic record. A student pursuing the Ph.D.
degree should demonstrate, through the dissertation, the ability
to carry out original and creative research. The results of the
research should be sufficiently significant to be publishable in
a major technical journal. The writing style, grammar and spelling
of the dissertation should reflect a high level of skill in written
communication. Between the research proposal and the final examination
the student is required to provide at least one progress report
to his/her advisory committee at a meeting where all committee members
are present. The time of this meeting is determined by the student’s
DAC.
At the completion of the research, you must defend your thesis
in a public presentation. Doctoral candidates are encouraged to
hold a private defense with his or her committee several weeks prior
to the public defense. At that time, the committee should raise
issues with the candidate prior to the public defense. The final
examination must be scheduled through the Registrar’s Office,
at least two weeks prior to its administration. To pass the final
examination, a degree candidate must have a favorable vote from
a majority of the examining/advisory committee, with a maximum of
one negative vote. If a student fails the final examination, there
must be a lapse of one full semester (15 weeks) before rescheduling
the examination. A student is allowed no more than two opportunities
to pass the final examination.
SDOE Graduate Certificate Programs
All graduate certificate programs require a minimum of 12 credit
hours of course work. An undergraduate degree in engineering or
related disciplines with a "B" average or better from
an accredited college or university is generally required for graduate
study in any one of our programs. Outstanding applicants in other
areas may be conditionally admitted subject to the satisfactory
completion of several ramp courses or introductory courses within
the specific program. The specific requirements will be determined
on an individual basis depending upon the student’s background.
International students must demonstrate their proficiency in the
English language prior to admission by scoring at least 550 (213
for computer-based) on the TOEFL examination. Applications for admission
from qualified students are accepted at any time.
Each of the graduate certificate programs is a stepping stone
towards the Master’s degree in Systems Engineering.
Graduate Certificate in Agile Systems Engineering
- SDOE 651 Agile Systems Engineering and Architecting: Methods,
Processes and Practices
- SDOE 606 Accelerated Systems Integration and Testing
- SDOE 655 Robust Engineering Design
- SDOE 780 Agile Development Strategy
Graduate Certificate in Systems and Supportability Engineering
- SDOE 625 System Operational Effectiveness and Life-cycle Analysis
(SYS 625WS is the web-based version)
- SDOE 640 System Supportability and Logistics
- SDOE 645 Design for System Reliability, Maintainability and
Supportability
- SDOE 650 System Architecture and Design (SYS 650WS is the web-based
version)
Graduate Certificate in Systems Engineering and Architecting
- SDOE 625 Systems Operational Effectiveness and Life-cycle Analysis
- SDOE 650 System Architecture and Design
- SDOE 612 Project Management of Complex Systems or MGT 550 Introduction
to Project Management (for students wishing to obtain an additional
certificate in Project Management)
- SDOE 605 Systems Integration
Graduate Certificate in Value Chain Enterprise Systems
- SDOE 640 Supportability and Logistics (SYS 640WS is the web-based
version)
- SDOE 665 Integrated Supply Chains
- SDOE 670 Forecasting and Demand Modeling Systems or EM 744 Advanced
Data Analysis and Forecasting or SYS 611 Modeling and Simulation
- SDOE 675 Dynamic Pricing Systems or SDOE 660 Decision and Risk
Analysis
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Interdisciplinary Graduate Certificate Programs
Atmospheric and Environmental Science and Engineering
(Interdisciplinary)
- PEP 575 Fundamentals of Atmospheric Radiation and Climate
- CE 691 Introduction to Dynamic Meteorology
- ME 532/EN 506 Air Pollution Principles and Control
- EN 550 Environmental Chemistry and Atmospheric Processes
Information Security
- MGT 645 CyberSecurity Principles
- MGT 762 Enterprise Architecture for Information
- CS 573 Fundamentals of Computer Security
- CS 694 E-Business Security & Information Assurance
Integrated Product Development
- IPD 601 Integrated Product Development I
- IPD 602 Integrated Product Development II
- IPD 611 Simulation and Modeling
- IPD 612 Project Management and Organizational Design
Pharmaceutical Manufacturing Practices
The Graduate Certificate in Pharmaceutical Manufacturing Practices
is an interdisciplinary School of Engineering certificate developed
by the Department of Mechanical Engineering and the Department of
Chemical, Biomedical and Materials Engineering. This certificate
is intended to provide professionals with skills required to work
in the pharmaceutical industry. The focus is on engineering aspects
of manufacturing and the design of facilities for pharmaceutical
manufacturing, within the framework of the regulatory requirements
in the pharmaceutical industry.
The certificate is designed for technologists in primary manufacturers,
including pharmaceutical, biotechnology, medical device, diagnostic
and cosmetic companies, as well as in related companies and organizations,
including architect/engineer/construction firms, equipment manufacturers
and suppliers, government agencies and universities.
(Interdisciplinary between Mechanical Engineering and Chemical
Engineering)
- PME 530 Introduction to Pharmaceutical Manufacturing
- PME 531 Process Safety Management (ChE Graduate Course)
- PME 535 Good Manufacturing Practice in Pharmaceutical Facilities
Design
- PME 540 Validation and Regulatory Affairs in Pharmaceutical
Manufacturing
and one of the following electives:
- PME 628 Pharmaceutical Finishing and Packaging Systems
- PME 538 Chemical Technology Processes in API Manufacturing
- PME 649 Design of Water, Steam and CIP Utility Systems for
Pharmaceutical Manufacturing (M.E. Graduate Course)
Microelectronics
EE/MT/PEP 507 Introduction to Microelectronics and Photonics
- EE/MT/PEP 561 Solid State Electronics I
- EE/MT/PEP 562 Solid State Electronics II
- CPE/MT/PEP 690 Introduction to VLSI Design
Microdevices and Microsystems
- EE/MT/PEP 507 Introduction to Microelectronics and Photonics
- EE/MT/PEP 595 Reliability and Failure of Solid State Devices
- EE/MT/PEP 596 Micro-Fabrication Techniques
- EE/MT/PEP 685 Physical Design of Wireless Systems
Any ONE elective in the three certificates above may be replaced
with another within the Microelectronics and Phototnics (MP) curriculum
upon approval from the MP Program Director.
Photonics
- EE/MT/PEP 507 Introduction to Microelectronics and Photonics
- EE/MT/PEP 515 Photonics I
- EE/MT/PEP 516 Photonics II
- EE/MT/PEP 626 Optical Communication Systems
Security Management and Forensics
The objective of this interdisciplinary graduate certificate program is to provide training in security risk management and security forensics, as well as a formal means for recognition of skills in these areas. The program would particularly benefit graduate students in EE, CS, TM, and Management, as well as professionals in the financial industry, the insurance industry, and law enforcement organizations.
The program includes lectures, projects, and related labs, and is taught by dedicated world-class experts with many years of teaching, research, and real-world experience. An Advanced Certificate in Security Management and Forensics recognizes successful completion of the program. Such recognition is all the more valuable as Stevens has been designated by the National Security Agency as one of the Centers of Academic Excellence (CAE) in Information Assurance. This is an honor of great value in the security profession; government and industry favor graduates of CAEs.
The program includes the following four courses, which are offered, in addition to on-campus, online and in off-campus corporate locations with a sufficient number of students.
Courses
- CS 573: Fundamentals of CyberSecurity
- CS/TM 694: E-business Security and Information Assurance
- CS/MIS 695: Cybersecurity Forensics
- MGT 710: Risk Management: Methods and Applications
For more detail, please visit www.stevens.edu/ses/academics/cs/.
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