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Advance your career with a master’s degree in engineering. Our convenient evening classes provide the flexibility your schedule demands. Read more
Advance your career with a master’s degree in engineering. Our convenient evening classes provide the flexibility your schedule demands.

MSOE’s Master of Science in Engineering (MSE) program is an interdisciplinary engineering program with primary emphases in the areas of electrical engineering (EE) and mechanical engineering (ME). A key component of the MSE program is the breadth of engineering background that students gain in areas of systems engineering, EE and ME. Additionally, each student is offered some degree of concentration through the selection of an engineering option and electives.

This interdisciplinary approach is a distinguishing feature of MSOE’s program and students are encouraged to take engineering courses both within and outside of their discipline. Courses cover topics like simulation and modeling, operations research, quality engineering, advanced engineering mathematics, finite element analysis, advanced mechanics, fluid power systems, data communications, control systems and advanced electronic systems.

The MSE program’s major emphasis is on the further development of engineering knowledge and skills in an effort to enhance the productivity of the practicing engineer. The program provides a flexible platform for students to take either an integrated approach or a specialized approach to meet the demands of their career. The course work emphasizes engineering concepts and theory through presentation, and faculty bring extensive industry experience to the classroom.

A nine-credit capstone engineering project option is included as part of the program. A non-project option is also available, which includes two specialty courses and a three-credit engineering paper in the specialty.

Curriculum Format

All classes are offered in the evening, providing convenient scheduling. The program is designed for individuals who hold bachelor degrees in engineering, engineering technology or other closely related areas. Each student works with the program director to plan a course of study tailored to his or her needs. Typically, a total of 45 graduate credits is required to complete the program, but degree requirements may vary depending upon the type of bachelor’s degree.

MSE Program Options

Each student selects either a capstone engineering project or the non-project option.

The engineering project option can either draw from the multiple disciplines studied within the program or focus more on technical areas within the student’s chosen engineering discipline. After consulting with a faculty advisor, each student develops an engineering project proposal and presents it for approval before a committee.

The non-project option requires a two-course sequence in 700- or 800-level EE/ME specialty courses and a final course (GE-791) in which a specialty paper is written. Each student completes an analysis/design of a certain aspect of the chosen specialty and presents it both orally and in writing.

100% Online delivery

Geography is not a constraint for students interested in completing the MSE at a distance. In addition to the face-to-face class format, there is also the option to take courses via 100% online distance delivery. The rich faculty, student interaction that is the hallmark of the MSE is replicated in online classes creating dynamic and flexible learning environments. Students can choose which format best fits their lives, while advancing their learning and professional skills.

Objectives and Outcomes

Program Educational Objectives

- Graduates create new value in a process or product at their workplace through application of advanced engineering skills and knowledge
- Graduates advance in their careers as a direct result of completing the degree

Student Outcomes

Graduates of the MSE program will:
- be able to utilize advanced mathematics, with a primary focus on numerical methods and models, to solve engineering problems involving multivariate differential systems
- have demonstrated an ability to apply advanced engineering principles to complex problems in his or her chosen specialty
- have demonstrated an ability to integrate and analyze information in a chosen specialty in the form of scholarly work, either as an independent specialty paper or as an independent engineering project
- have the ability to effectively present and communicate technical concepts, both orally and in writing

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Microsystems Engineering is one of the most dynamic and interdisciplinary engineering fields. The Master of Science program in Microsystems Engineering (MSE) provides the educational basis for your success in this field. Read more
Microsystems Engineering is one of the most dynamic and interdisciplinary engineering fields. The Master of Science program in Microsystems Engineering (MSE) provides the educational basis for your success in this field. The MSE program is designed for highly qualified graduate students holding a Bachelor degree in engineering or science.

In the first year 12 mandatory courses provide the fundamental theoretical framework for a future career in Microsystems. These courses are designed to provide students with a broad knowledge base in the most important aspects of the field:

• MSE technologies and processes
• Microelectronics
• Micro-mechanics
• MSE design laboratory I
• Optical Microsystems
• Sensors
• Probability and statistics
• Assembly and packaging technology
• Dynamics of MEMS
• Micro-actuators
• Biomedical Microsystems
• Micro-fluidics
• MSE design laboratory II
• Signal processing

As part of the mandatory courses, the Microsystems design laboratory is a two-semester course in which small teams of students undertake a comprehensive, hands-on design project in Microsystems engineering. Requiring students to address all aspects of the generation of a microsystem, from conceptualization, through project planning to fabrication and testing, this course provides an essential glimpse into the workings of engineering projects.

In the second year, MSE students can specialise in two of the following seven concentration areas (elective courses), allowing each student to realize individual interests and to obtain an in-depth look at two sub-disciplines of this very broad, interdisciplinary field:

• Circuits and systems
• Design and simulation
• Life sciences: Biomedical engineering
• Life sciences: Lab-on-a-chip
• Materials
• Process engineering
• Sensors and actuators

Below are some examples of subjects offered in the concentration areas. These subjects do not only include theoretical lectures, but also hands-on courses such as labs, projects and seminars.

Circuits and Systems
• Analog CMOS Circuit Design
• Mixed-Signal CMOS Circuit Design
• VLSI – System Design
• RF- und Microwave Devices and Circuits
• Micro-acoustics
• Radio sensor systems
• Optoelectronic devices
• Reliability Engineering
• Lasers
• Micro-optics
• Advanced topics in Macro-, Micro- and Nano-optics


Design and Simulation
• Topology optimization
• Compact Modelling of large Scale Systems
• Lattice Gas Methods
• Particle Simulation Methods
• VLSI – System Design
• Hardware Development using the finite element method
• Computer-Aided Design

Life Sciences: Biomedical Engineering
• Signal processing and analysis of brain signals
• Neurophysiology I: Measurement and Analysis of Neuronal Activity
• Neurophysiology II: Electrophysiology in Living Brain
• DNA Analytics
• Basics of Electrostimulation
• Implant Manufacturing Techologies
• Biomedical Instrumentation I
• Biomedical Instrumentation II

Life Sciences: Lab-on-a-chip
• DNA Analytics
• Biochip Technologies
• Bio fuel cell
• Micro-fluidics 2: Platforms for Lab-on-a-Chip Applications

Materials
• Microstructured polymer components
• Test structures and methods for integrated circuits and microsystems
• Quantum mechanics for Micro- and Macrosystems Engineering
• Microsystems Analytics
• From Microsystems to the nano world
• Techniques for surface modification
• Nanomaterials
• Nanotechnology
• Semiconductor Technology and Devices

MEMS Processing
• Advanced silicon technologies
• Piezoelectric and dielectric transducers
• Nanotechnology

Sensors and Actuators
• Nonlinear optic materials
• CMOS Microsystems
• Quantum mechanics for Micro- and Macrosystems Engineering
• BioMEMS
• Bionic Sensors
• Micro-actuators
• Energy harvesting
• Electronic signal processing for sensors and actuators


Essential for the successful completion of the Master’s degree is submission of a Master’s thesis, which is based on a project performed during the third and fourth semesters of the program. Each student works as a member of one of the 18 research groups of the department, with full access to laboratory and cleanroom infrastructure.

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This course equips students with the knowledge and statistical skills to make valuable contributions to medical research as well as public health in low-, middle- and high-income countries. Read more
This course equips students with the knowledge and statistical skills to make valuable contributions to medical research as well as public health in low-, middle- and high-income countries. Epidemiological methods underpin clinical medical research, public health practice and health care evaluation to investigate the causes of disease and to evaluate interventions to prevent or control disease.

Graduates enter careers in medical research, public health and community medicine, epidemiological field studies, drug manufacturers, government or NGOs.

The Nand Lal Bajaj and Savitri Devi Prize is awarded to the best project each year. The prize was donated by Dr Subhash Chandra Arya, former student, in honour of his parents Dr Nand Lal Bajaj and Mrs Savitri Devi.

- Full programme specification (pdf) (http://www.lshtm.ac.uk/edu/qualityassurance/epi_progspec.pdf)

Visit the website http://www.lshtm.ac.uk/study/masters/mse.html

Additional Requirements

Additional requirements for the MSc Epidemiology are:

- evidence of numeracy skills (e.g. A level Mathematics or Statistics or a module with a good mark in their university degree)

- it is preferable for a student to have some work experience in a health-related field

Any prospective student who does not meet the above minimum entry requirement, but who has relevant professional experience, may still be eligible for admission. Please contact the course directors () if you are not sure whether this is the right course for you.

Objectives

By the end of this course, students should be able to:

- demonstrate advanced knowledge and awareness of the role of epidemiology and its contribution to other health-related disciplines

- choose appropriate designs and develop detailed protocols for epidemiological studies

- enter and manage computerised epidemiological data and carry out appropriate statistical analyses

- assess the results of epidemiological studies (their own or other investigators'), including critical appraisal of the study question, study design, methods and conduct, statistical analyses and interpretation

Structure

Term 1:
All students take the compulsory modules and usually take optional modules.

Compulsory modules are:
- Clinical Trials
- Epidemiology in Practice
- Extended Epidemiology
- Statistics for Epidemiology and Population Health .

Optional modules include:
- Demographic Methods
- Molecular Epidemiology of Infectious Diseases

Terms 2 and 3:
Students take a total of five modules, one from each timetable slot (Slot 1, Slot 2 etc.).

*Recommended modules

- Slot 1:
Study Design: Writing a Proposal (compulsory)

- Slot 2:
Statistical Methods in Epidemiology (compulsory)

- Slot 3:
Epidemiology of Non-Communicable Diseases*
Medical Anthropology and Public Health*
Social Epidemiology*
Spatial Epidemiology in Public Health*
Applied Communicable Disease Control
Control of Sexually Transmitted Infections
Current Issues in Safe Motherhood & Perinatal Health
Medical Anthropology and Public Health; Nutrition in Emergencies
Tropical Environmental Health

- Slot 4:
Environmental Epidemiology*
Epidemiology & Control of Communicable Diseases*
Genetic Epidemiology*
Design and Evaluation of Mental Health Programmes
Ethics, Public Health & Human Rights; Globalisation & Health; Nutrition Related Chronic Disease

- Slot 5:
Advanced Statistical Methods in Epidemiology*
AIDS
Applying Public Health Principles in Developing Countries
Integrated Vector Management
Principles and Practice of Public Health

Further details for the course modules - http://www.lshtm.ac.uk/study/currentstudents/studentinformation/msc_module_handbook/section2_coursedescriptions/tepi.html

Residential Field Trip

This course has a compulsory two-day residential retreat outside London. This is held on the Wednesday and Thursday of the first week in Term 1. This is included in the £200 field trip fee.

Day field trip to Oxford

A one-day field trip to Oxford usually takes place in November during reading week. Students are encouraged to attend but it is not a compulsory part of the course.

Project Report

During the summer months (July - August), students complete a written research project on a topic selected in consultation with their tutor, for submission by early September. This can be a data-analysis of an adequately powered study, a study protocol, a systematic review or an infectious disease modelling study. Students do not usually travel abroad to collect data.

Find out how to apply here - http://www.lshtm.ac.uk/study/masters/mse.html#sixth

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This course has been designed to meet the local, regional and national needs in developing the knowledge, skills and competencies of clinical educators and learning facilitators working in health and related clinical services. Read more
This course has been designed to meet the local, regional and national needs in developing the knowledge, skills and competencies of clinical educators and learning facilitators working in health and related clinical services. It will provide a framework in which clinical educators can critically review and develop theoretical perspectives and practical skills in facilitating their students / trainees experience.

During the course students will systematically and creatively analyse the complexities of clinical education using techniques which build on their own experience. The course will involve active and reflective learning and ensure the integration of contemporary theory and practice.

The course will help prepare clinicians to assume leadership positions in clinical education in their own profession and cooperate in developing multi professional aspects of clinical education.

What modules will I study?
Compulsory modules:

MSE-4030 Clinical Performance Assessment
MSE-4032 Teaching and Technology
What will I learn?
This programme will equip clinical educators with a greater breadth and depth of knowledge and understanding of medical education including:

An in-depth knowledge and understanding of specific issues at the forefront of theory and practice in medical education.
A critical understanding of the requirement of clinical performance assessments and appraisal for fitness to practice.
A critical understanding of the standard setting processes.
A critical understanding of the basic tenets of good adult pedagogy.
A practical understanding of the methods used to facilitate learning.
The ability to appraise the goals of assessment and the impact of assessment on student learning.
The ability to evaluate the relevance, validity and reliability of assessment methodologies.
The ability to critically review and reflect on contemporary adult learning and medical education literature relating to the application of simulation teaching technology and apply this to own simulation practice experience.
Reviewing ethical issues relating to teaching and learning facilitation in a clinical context.

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MSE (M.Sc. in Space Engineering) is an international full-time Master’s programme in space engineering that starts at Technische Universität Berlin in April each year. Read more
MSE (M.Sc. in Space Engineering) is an international full-time Master’s programme in space engineering that starts at Technische Universität Berlin in April each year. The aim of the programme is to educate systems engineers equipped to become leaders in the space industry.

At the Chair of Space Technology of TU Berlin

The course is offered by the Chair of Space Technology at Technische Universität Berlin and combines excellent teaching in space technology with project management and intercultural skills. The entire programme, over four semesters, is taught in English.

Highly project oriented Master’s programme

The Master’s programme is highly project oriented and designed to prepare students for the requirements of the global space industry. Students have the chance to be involved in challenging satellite projects, working within intercultural teams. Especially, they benefit from the worldwide leading expertise and network of TU Berlin in the field of small satellites. Interdisciplinary skills, such as project management, innovation marketing and business will complement the curriculum.

Internship experience in the European space industry

Furthermore, the opportunity to gain internship experience in the European space industry will be provided. After graduation, students will be equipped with skills, experience and a strong network to boost their space career either in Europe, in their home country or anywhere else.

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The Department of Materials Science and Engineering (MSE) offers graduate programs leading to the degrees of Master of Applied Science (MASc), Master of Engineering (MEng), and Doctor of Philosophy (PhD). Read more
The Department of Materials Science and Engineering (MSE) offers graduate programs leading to the degrees of Master of Applied Science (MASc), Master of Engineering (MEng), and Doctor of Philosophy (PhD). Graduate courses and research opportunities are offered to qualified students in a wide range of subjects.

Typical subjects in extractive and process metallurgy involve a study of the equilibria existing during the reduction of oxides with carbon and metals, life cycle analysis of materials, properties of iron and steelmaking slags, the fundamental properties of fused salt solutions, fused salt electrolysis of reactive metals, kinetics of high-temperature reactions, mathematical modelling of metallurgical processes, process metallurgy, and hydrometallurgy.

Typical physical metallurgy and materials science subjects deal with the structure, properties, and application of advanced materials in such fields as nanomaterials, surface chemistry, energy, sustainability, optoelectronics, biomaterials, nuclear materials, metalmatrix composites (MMCs), metallic glasses, corrosion, fatigue, phase transformations, and solidification. These studies are all related to the general problem of understanding structure-property-processing-performance relationships in materials.

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