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Masters Degrees (Safety And Reliability)

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The MSc Safety Engineering for Oil & Gas programme provides training in safety engineering, reliability engineering, and loss prevention in the offshore, nuclear, transport, aerospace and process industries and more. Read more
The MSc Safety Engineering for Oil & Gas programme provides training in safety engineering, reliability engineering, and loss prevention in the offshore, nuclear, transport, aerospace and process industries and more. Fully accredited by the Institution of Mechanical Engineers (IMechE), the Institution of Civil Engineers (ICE), the Institution of Structural Engineers (IStructE), the Institute of Highway Engineers (IHE) and the Chartered Institution of Highways & Transportation (CIHT).

COURSES
Semester 1
Fundamental Safety Engineering and Risk Management Concepts
Statistics and Probability for Safety, Reliability, and Quality
Fire and Explosion Engineering
Offshore Oil and Gas Production Systems

Semester 2
Advanced Methods for Risk and Reliability Assessment
Applied Risk Analysis and Management
Process Design, Layout and Materials
Human Factors Engineering

Semester 3
Project

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You study safety engineering, reliability engineering, and loss prevention in the context of legal requirements for wide ranging industry applications such as nuclear, defence, transport, aerospace, manufacturing and process industries. Read more
You study safety engineering, reliability engineering, and loss prevention in the context of legal requirements for wide ranging industry applications such as nuclear, defence, transport, aerospace, manufacturing and process industries.

COURSES
Semester 1
Fundamental Safety Engineering, and Risk Management Concepts
Statistics and Probability for Safety, Reliability and Quality
Fire and Explosion Engineering
Subsea Integrity

Semester 2
Advanced Methods for Risk and Reliability Assessments
Applied Risk Analysis and Management
Process Design, Layout and Materials
Human Factors Engineering

Semester 3
Safety Engineering Project

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Risk has become a key concept in modern society. Read more

Programme Background

Risk has become a key concept in modern society. Growing concern about the environment and a number of disasters have served to focus attention on the hazards and risks involved in a wide range of activities from offshore oil production to rail and air transport; from the design of football stadia to the operation of chemical plants and environmental protection. Today there is a wide range of techniques available to assess risk and reliability, both in relation to safety and in the wider sense. These techniques now underpin new legislation on safety and have relevance over a broad spectrum of activities, including environmental and other systems, where risk and reliability are key concerns.

The MSc/PG Diploma programme in Safety, Risk and Reliability Engineering is designed to give a thorough understanding of these techniques and experience of their application to a variety of real-world problems. It aims to provide students with an understanding of safety, risk and reliability engineering in both a qualitative and quantitative manner, and to develop the skills to apply this understanding. The programme will also introduce students to recent developments in analytical techniques, e.g. computer modelling of risk, reliability and safety problems.

Professional Recognition

This MSc degree is accredited as meeting the requirements for Further Learning for a Chartered Engineer (CEng) for candidates who have already acquired an Accredited CEng (Partial) BEng (Hons) undergraduate first degree. See http://www.jbm.org.ukfor further information.

The MSc and PgDip degrees have also been accredited by the Institution of Occupational Safety and Health (IOSH). Graduates are eligible to join IOSH as Graduate members and then undertake an initial professional development process that leads to Chartered membership. http://www.iosh.co.uk for further information.

Programme Content

The MSc/Postgraduate Diploma in Safety, Risk and Reliability Engineering is only available by attendance-free distance learning. The programme comprises eight courses. All courses have written examinations and some have compulsory coursework elements. MSc students are also required to complete an individual project (dissertation). This programme has a stronger engineering bias and you should only attempt this if you have done some University level mathematics or equivalent. Otherwise the Safety and Risk Management course might be more appropriate.

For the project component of the programme distance learners are likely to develop something based in their country of residence with advice and supervision from staff in the School. This may well include work with a local company or may involve independent study. Individual arrangements will be set up with each student.

For more detailed information on this programme please contact the Programme Leader before applying (see above).

Courses

• Risk Assessment and Safety Management
This course aims to give students an appreciation of risk from individual and societal perspectives as well as understanding the basic principles of risk assessment and modelling and how safety management works in practice.

• Systems Reliability
Gives an understanding of the qualitative and quantitative techniques that are used in the reliability, availability and maintainability analysis of all types of engineering systems.

• Learning from Disasters
Provides students with an in depth understanding of some of the classic disasters and their consequences by using a range of practical accident investigation techniques. Students will learn to analyse complex histories in order to find the underlying root cause.

• Safety, Risk and Reliability
Leads to an understanding of the principles of structural reliability theory and its application to risk and reliability engineering.

• Fire Safety, Explosions and Process Safety
Introduces students to the basic principles of fire safety science and engineering, and develops skills in associated modelling leading to an understanding of principal fire/explosion related issues in process safety.

• Data Analysis and Simulation
Develops knowledge of statistical data analysis and its application in engineering and science and introduces the concepts of using simulation techniques for analysis of complex systems. It also teaches linear optimisation techniques and the ability to apply them to solve simple problems.

• Human Factors Methods
This course will equip students from academic and/or industrial backgrounds with knowledge on, and the means to deploy, a wide range of specialist human factors techniques. The emphasis is on method selection, application, combination and integration within existing business practices. Students will develop a critical awareness of what methods exist, how to apply them in practice and their principle benefits and limitations.

•Environmental Impact Assessment
Provides the candidate with the knowledge and understanding of the principles and processes of the Environmental Impact Assessment. By the end of the course, the student should be familiar with the European EIA legislation and its translation into the Scottish planning system, and be able to demonstrate an understanding of the EIA process, the tools and the agents involved in an EIA and the possible problems with using EIA as a decision making tool. It is also intended that the student will be able to appreciate the purpose of the EIA process from a number of perspectives; that of a developer, an EIA practitioner and a policy maker.

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WHAT YOU WILL GAIN. - Skills and know-how in the latest and developing technologies in safety, risk and reliability. - Practical guidance and feedback from industrial automation experts from around the world. Read more
WHAT YOU WILL GAIN:

- Skills and know-how in the latest and developing technologies in safety, risk and reliability
- Practical guidance and feedback from industrial automation experts from around the world
- Live knowledge from the extensive experience of expert instructors
- Credibility and respect as the local safety, risk and reliability expert in your firm
- Global networking contacts in the industry
- Improved career choices and income
- A valuable and accredited Master of Engineering (Safety, Risk and Reliability)** qualification

Next intake is scheduled for June 26, 2017. Applications now open; places are limited.

INTRODUCTION

A powerful force is driving industrial growth and change, and it’s only getting stronger. That force? Uncertainty. Society increasingly demands more efficient transport, more power production, safer energy exploration and processing, less waste, smarter products and of course, all at lower costs. All these demands spotlight uncertainty, and how we need to manage uncertainty through engineering, science and technology. Modern engineers face an intriguing set of challenges when tackling uncertainty and they have developed some of the smartest methods, tools, techniques and approaches for understanding system safety, risk and reliability.

The Master of Engineering (Safety, Risk and Reliability) is the ideal gateway to boost your capacity to tackle these real world increasingly complex issues. In the 21st century, industry will routinely deal with novel hazardous processing technologies, complex energy grid load-balancing from renewables, driverless cars, artificial vision to augment control and feedback in sub-sea exploration – and the infinitesimal scale of nanotechnologies in bionic engineering. Currently, people are at the heart of many hazardous work environments, exposed to the consequences of uncontrolled events; but soon, artificial intelligence will afford more human tasks to be automated (and present a host of newer risks, in exchange for the retired ones). This progress has to be examined in systematic terms – terms that integrate our understandings of technical fallibility, human error and political decision-making.

This program has been carefully designed to accomplish three key goals. First, a set of fundamental concepts is described in useful, manageable ways that encourage rapid and integrated knowledge-acquisition. Second, that knowledge is applied in creative and imaginative ways to afford practical, career-oriented advantages. Third, the learning that results from the integration of knowledge and application is emboldened by activities and projects, culminating in a project thesis that is the capstone of the program. This carefully designed learning journey will develop factual understanding and also exercise participant’s creativity and design-thinking capabilities. Employers are hungry for these skills, and program graduates can expect a significant advantage when interacting with employers, clients, consultants and fellow engineering peers.

ENTRANCE REQUIREMENTS

To gain entry into this program, applicants need one of the following:
a) a recognized 3-year bachelor degree in an engineering qualification in a congruent* field of practice with relevant work experience**.
b) a 4-year Bachelor of Engineering qualification (or equivalent), that is recognized under the Washington Accord or Engineers Australia, in a congruent*, or a different field of practice at the discretion of the Admissions Committee.
c) a 4-year Bachelor of Engineering qualification (or equivalent) that is not recognized under the Washington Accord, in a congruent* field of practice to this program.

AND
An appropriate level of English Language Proficiency equivalent to an English pass level in an Australian Senior Certificate of Education, or an IELTS score of 6.5 (with no individual band less than 6.0) or equivalent as outlined in the EIT Admissions Policy.

* Congruent field of practice means one of the following with adequate Safety, Risk and Reliability content (fields not listed below to be considered by the Dean and the Admissions committee on a case-by-case basis):
• Chemical and Process Engineering
• Electronic and Communication Systems
• Instrumentation, Control and Automation
• Industrial Automation
• Industrial Engineering
• Agricultural Engineering
• Electrical Engineering
• Manufacturing and Management Systems
• Mechanical and Material Systems
• Mechatronic Systems
• Production Engineering
• Mechanical Engineering
• Robotics

**Substantial industrial experience in a related field is preferred, with a minimum of two years’ relevant experience.

PROGRAM STRUCTURE

Students must complete 48 credit points comprised of 12 core subjects and one capstone thesis. The thesis is the equivalent of one full semester of work. There are no electives in this course. The program duration is two years full time, or equivalent. Subjects will be delivered over 4 terms per year. Students will take 2 subjects per term and be able to complete 8 units per year. There will be a short break between terms. Each term is 12 weeks long.

LIVE WEBINARS

During the program you will participate in weekly interactive sessions with the lecturers and other participants from around the world. Each unit's weekly live tutorial will last 60 to 90 minutes. We take student availability into consideration wherever possible before scheduling webinar times. All you need to participate is an adequate Internet connection, speakers and a microphone. The software package and setup details will be sent to you at the start of the program.

COURSE FEES

EIT provides distance education to students located almost anywhere in the world – it is one of the very few truly global training institutes. Course fees are paid in a currency that is determined by the student’s location. A full list of fees in a currency appropriate for every country would be complex to navigate and, with today’s exchange rate fluctuations, difficult to maintain. Instead we aim to give you a rapid response regarding fees that is customized to your individual circumstances.

We understand that cost is a major consideration before a student commences study. For a rapid reply to your query regarding courses fees and payment options, please query via the below button and we will respond within 2 business days.

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Learn to analyse and evaluate the business, financial and management strategies applicable to Logistics and Supply Chain Management on this fascinating Masters programme at LJMU. Read more
Learn to analyse and evaluate the business, financial and management strategies applicable to Logistics and Supply Chain Management on this fascinating Masters programme at LJMU.

•Learn to analyse and evaluate business, financial and management strategies as they apply to Logistics and Supply Chain Management
•Study on a year-long, modular programme with each module delivered over a period of five to six weeks
•Programme is allied with the work of the Liverpool Logistics, Offshore and Marine (LOOM) Research Institute
•Course appeals to an international student base

This is a modular programme with each module delivered over a period of five to six weeks. In most cases, modules are assessed by a piece of applied coursework.

This programme will enable you to:
•develop Masters-level research techniques
•reflect on your prior learning and experience
•plan your own study programme
•learn about manufacturing operations management, focusing on the manufacturing plant and services
•find out about the fundamentals of production planning, inventory control and process modelling and control
•discover how goods are moved around the world within the logistics system
•consider a range of information technology issues which a logistics manager may encounter in a complex supply chain environment
•analyse the components of a logistics system and appraise contemporary developments
•apply operations research techniques to solving business problems in the sector


The 60 credit Project is the culmination of the programme and is undertaken after the entire taught element has been completed. Projects are self-generated, although if you are an externally-funded student you may choose to study an area which will be of value to your employer or sponsor.

You will be allocated a supervisor from amongst the staff programme team with whom you will work closely during the Project stage, culminating with the submission of your dissertation in mid-September.

Please see guidance below on core and option modules for further information on what you will study.
Level 7
Research skills - is embedded into induction week
Manufacturing management - runs in various short blocks at stages during the year
Global transport systems
Data systems for maritime and logistics
Legal principles and export trade law - aimed at those with an interest in legal and contractual matters
International trade - addresses the wider context of global logistics
Project management - obtain awareness of planning, monitoring and controlling processes
Logistics systems - analyses the components of logistics system and, through a case study, appraises contemporary developments
Operations research - you will apply OR techniques to solving business problems in the sector
Supply chain modelling - applies some of the principles specifically to logistics and supply chain issues
Safety and reliability - modern risk management techniques are used to enable improvements in the safety and reliability of systems
Preparing for project - you will develop a coherent set of aims and objectives, and a realistic work plan, in readiness for your individual project

Further guidance on modules

The information listed in the section entitled ‘What you will study’ is an overview of the academic content of the programme that will take the form of either core or option modules. Modules are designated as core or option in accordance with professional body requirements and internal Academic Framework review, so may be subject to change. Students will be required to undertake modules that the University designates as core and will have a choice of designated option modules. Additionally, option modules may be offered subject to meeting minimum student numbers.

Academic Framework reviews are conducted by LJMU from time to time to ensure that academic standards continue to be maintained. A review is currently in progress and will be operational for the academic year 2016/2017. Final details of this programme’s designated core and option modules will be made available on LJMU’s website as soon as possible and prior to formal enrolment for the academic year 2016/2017.

Please email if you require further guidance or clarification.

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The International Master of Science in Fire Safety Engineering (IMFSE) is a two-year educational programme in the Erasmus+ framework. Read more

Applications for this programme should be made through Ghent University.

Programme description

The International Master of Science in Fire Safety Engineering (IMFSE) is a two-year educational programme in the Erasmus+ framework.

This masters programme is jointly offered by the following three full partner universities:

-The University of Edinburgh, UK
-Ghent University, Belgium (coordinator)
-Lund University, Sweden

Additionally, there are three associated partners where students can perform thesis research:

-The University of Queensland, Australia
-ETH Zurich, Switzerland
-The University of Maryland, United States of America

Classes in Edinburgh focus on fire dynamics, fire safety engineering and structural design for fire. Classes in Ghent have a more general fire safety engineering focus. Classes in Lund emphasise enclosure fire dynamics, risk analysis and human behaviour.

Our Building Research Establishment (BRE) Centre for Fire Safety Engineering hosts bespoke equipment to support groundbreaking research and teaching, with combined thermal and mechanical loading and use of the latest image analysis techniques.

IMFSE is very pleased to involved seven industrial partners as official sponsors. With their annual financial contributions, it has been made possible to create the IMFSE Sponsorship Consortium, which awards IMFSE students with full or partial scholarships. The current sponsors are:

-Arup
-IFIC Forensics
-UL
-Promat
-FPC
-BRE
-Fire Engineered Solutions Ghent

Programme structure

The programme consists of four semesters each worth 30 ECTS credits. Changing study location after each semester lets you benefit from the expertise of each university.

Learning outcomes

The course contents and learning outcomes of IMFSE have been jointly developed, taking into account the specialties and experience of each of the three IMFSE universities. All three partners have extensive experience in teaching the different courses and integrating them into different degree requirements.

Competence in one/more scientific discipline(s)
For a masters degree (two years), students must be able to:

-master and apply advanced knowledge in the field of engineering in case of complex problems
-apply Computer Aided Engineering (CAE) tools and sophisticated calculation and communication instruments in a creative and target-oriented approach
-master and apply knowledge of physics, chemistry, thermodynamics, heat and mass transfer to critically analyse and evaluate the development of fires in enclosures
-master and apply knowledge of 'element methods' and dynamics of structures to critically analyse and evaluate the behaviour of simple structures in case of fire
-master and apply knowledge of explosions to critically analyse and evaluate associated risks
-master and apply the advanced knowledge of fire dynamics, risk assessment, human behaviour and integrate this in a performance-based fire safety design

Skills and abilities
For a masters degree (two years), students must be able to:

-analyse complex problems and convert them into scientific questions.
-perform research by making use of scientific literature.
-select and apply appropriate models, methods and techniques in different circumstances
-develop and validate mathematical models and methods
-analyse own results and results of others in an objective manner
-critically elaborate problems of fire risk assessment with autonomy and flexibility, using a limited amount of data
-perform valid computer simulations of development and consequences of enclosure fires

Intellectual competence
For a masters degree (two years), students must be able to:

-take independent positions on complex situations and be able to defend the point of view
-use own knowledge in a creative, target-oriented and innovative way regarding research, conceptual design and production
-reflect on the own way of thinking and acting and be conscious of the own expertise
-be aware of ongoing evolutions in the field of interest and maintain competence on the expert level
-flexibly adapt to changing professional circumstances.
-develop scientifically sound arguments to optimise passive and active fire protection measures

Competence in cooperation and communication
-discuss field of specialisation in English
-project planning: formulate objectives, report efficiently, keep track of end-goals and progress of the project
-cooperate and take the lead in a team in a multi-disciplinary working-environment
-report on technical or scientific subjects orally, in writing and in graphics
-function in an international environment (students, PhD students, scientific co-workers, scholars)

Societal competence
-Act in an ethical, professional and social manner.
-Be aware of the most important corporate and legal aspects in their field of engineering.
-Interpret the historical evolution of the own field of engineering and its social relevance.
-Master and apply critical insight in existing fire safety legislation and regulations in the development of a fire safety design.
-Act in an ethical, professional and social way when developing and presenting a performance-based fire safety design.

Profession-specific competence
-Master the complexity of technical systems by use of system and process models.
-Reconcile conflicting specifications and boundary conditions and transform them into high-quality, innovative concepts and processes.
-Transform incomplete, contradictory or redundant data into useful information.
-Select enough knowledge and comprehension to control the results of complex calculations or make approximate estimates.
-Pay attention to entire life-cycles of systems, machines and processes.
-Pay attention to energy-efficiency, environmental pressure, use of raw materials and labour costs.
-Pay attention to all aspects of reliability, safety and ergonomics.
-Be aware and insightful of the importance of entrepreneurship in society.
-Show perseverance, drive for innovation and a sense for the creation of added value.

Career opportunities

We aim to train the next generation of leaders in this field; there is currently great demand for fire safety engineering graduates worldwide and graduates have gained relevant employment or enhanced career opportunities.

A fire safety engineer fulfils a broad range of duties, in various ways related to fire. This can range from designing fire protection for a space station, to protecting treasures such as the US Constitution, to safely securing the occupants of a high-rise building from fire hazards.

Fire safety engineers are in great demand by corporations, educational institutions, consulting firms, and government bodies around the world. You may find career opportunities in the following industries:

-consulting engineering firms
-fire departments
-fire equipment and systems manufacturers
-government
-hospitals and health care facilities
-insurance industry
-research and testing laboratories
-educational institutions
-entertainment industry
-forensic investigations

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NHS staff from all professions will need to acquire an understanding of analytic tools and techniques that help determine the system deficiencies and approaches to ensuring issues identified can be addressed. Read more
NHS staff from all professions will need to acquire an understanding of analytic tools and techniques that help determine the system deficiencies and approaches to ensuring issues identified can be addressed.

The Improving Safety and Quality in Health Care module will enable you to reflect on the challenges of improving healthcare delivery and specifically enhancing patient safety. The module incorporates the latest thinking relating to improvement models and the contribution of human factors to patient safety.

Module content

Day 1
-Understanding the concept of variation in healthcare, how it can be identified and measured.
-Reflect upon the link between variation in delivery systems and overall system reliability and resilience.
-Explore the connection between variation, system performance and patient safety.

Day 2
-Explore models of improvement, the strengths and weaknesses of various tools and techniques.
-Understand systems thinking from the perspective of improvement and performance.
-Analyse the difference between personal v systems failure in contributing to patient safety.

Day 3
-Measurement of system performance, specifically statistical process control, risk assurance, both qualitative and quantitative data
-Contribution of patient (user input to health system assessment).
-The potential learning from other sectors, notably the nature and contribution of safety cases to improving patient safety.

Day 4
-The nature of error/failure modes and assessment approaches.
-Contribution of human factors, performance influencing factors and organisational culture to improvement and safety.
-Engagement of staff in improvement/safety and sustainability of interventions/improvements.

Day 5
-Matching capacity and demand in healthcare.
-Learning from other industries.
-Assignment planning.

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Accredited by the the Institution of Chemical Engineers. Whether you’re already working in the field or just starting out, this course will deepen your understanding and equip you with skills and expertise in process safety, loss prevention and risk assessment. Read more

About the course

Accredited by the the Institution of Chemical Engineers

Whether you’re already working in the field or just starting out, this course will deepen your understanding and equip you with skills and expertise in process safety, loss prevention and risk assessment. You’ll be ready for a career in the oil and gas, chemical, nuclear and pharmaceutical industries, or with any of the consultancies that service them.

Take advantage of our expertise

Our teaching is grounded in specialist research expertise. Our reputation for innovation secures funding from industry,
UK research councils, the government and the EU. Industry partners, large and small, benefit from our groundbreaking work addressing global challenges.

You’ll have access to top facilities, including modern social spaces, purpose-built labs, the Harpur Hill Research Station for large-scale work, extensive computing facilities and a modern applied science library. There are high-quality research facilities for sustainable energy processes, safety and risk engineering, carbon capture and utilisation, and biological processes and biomanufacturing.

Studentships

Contact us for current information on available scholarships.

Course content

Diploma: three core modules and five optional modules. MSc(Eng): one core module, major research project, and five optional modules.

Core modules

Process Safety Management and Loss Prevention
Introduction to Hazard Analysis and Risk Assessment
Hazards in Process Plant Design and Operation
Dissertation (for MSc)

Examples of optional modules

Process Plant Reliability and Maintainability
Human Error and Human Behaviour
Applied Hazard and Operability Studies (HAZOP)
Safety in Nuclear Operations
Computer Control: Safe Practice
Process Safety in the Oil and Gas Industry
Process Safety in the Pharmaceutical, Food and Consumer Products

Full-time or part-time

This course is available full-time over a year, or part-time over two or three years. Each module can be taken as a short course – useful if you’re already working in industry.

Part-time students need to complete all modules within two years. You can take an extra third year to complete your dissertation if you need to – we won’t charge fees for that year. Modules are delivered about once per month from September to June. Each module is four days long. You must therefore attend for 32 days in total.

Teaching and assessment

We use a mixture of lessons and discussions, real-life case studies, workshops and hands-on computer sessions. Continuous assessment is based on assignments for each module, and a dissertation.

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Running for over 35 years, this fully accredited MSc programme builds advanced capabilities in specialist aspects of bridge engineering. Read more
Running for over 35 years, this fully accredited MSc programme builds advanced capabilities in specialist aspects of bridge engineering.

Successful completion of this programme will aid you in pursuing a career as a bridge engineer with a consultancy, a specialist contractor or a local authority.

PROGRAMME OVERVIEW

Graduate students will find the programme of substantial use in developing their knowledge and skills base for bridge analysis, design and management.

The programme also offers the opportunity for practising bridge engineers to update their knowledge of current design and assessment codes and guidelines, become familiar with developments in new techniques for the design, construction and management of bridges.

The Bridge Engineering programme encompasses a wide range of modules addressing the whole life-analysis of bridge structures from design to end-of-life.

Optional modules from some of our other study streams are also offered, covering structural engineering, geotechnical engineering, water engineering, construction management, and infrastructure engineering and management.

Graduates are highly employable and may progress to relevant specialist PhD or EngD research programmes in the field.

PROGRAMME STRUCTURE

This programme is studied over either one year (full-time) or between two and five years (part-time or distance learning). It consists of eight taught modules and a dissertation project.

This degree is accredited as meeting the requirements for Further Learning for a Chartered Engineer (CEng) for candidates who have already acquired an Accredited CEng (Partial) BEng(Hons) or an Accredited IEng (Full) BEng/BSc (Hons) undergraduate first degree.

The following modules are indicative, reflecting the information available at the time of publication. Please note that not all modules described are compulsory and may be subject to teaching availability and/or student demand.

Bridge Engineering Group Modules
-Bridge Deck Loading and Analysis
-Prestressed Concrete Bridge Design
-Durability of Bridges and Structures
-Steel and Composite Bridge Design
-Long-Span Bridges

Structural Engineering Group Modules
-Steel Building Design
-Space Structures
-Structural Mechanics and Finite Elements
-Subsea Engineering
-Concrete Building Design
-Structural Safety and Reliability
-Earthquake Engineering
-Design of Masonry Structures

Geotechnical Engineering Group Modules
-Advanced Soil Mechanics
-Energy Geotechnics
-Geotechnical Structures
-Soil-Structure Interaction
-Foundation Engineering

Construction Management Group Modules
-Construction Management and Law
-Construction Organisation
-Project and Risk Management

Infrastructure Engineering and Management Group Modules
-Infrastructure Investment and Financing
-Infrastructure Interdependencies and Resilience
-Infrastructure Asset Management
-Sustainability and Infrastructure

Water and Environmental Engineering Group Modules
-Environmental Health
-Water Treatment
-Wastewater Treatment
-Applied Chemistry and Microbiology
-Pollution Control
-Groundwater Control
-Regulation and Management
-Water Resources Management and Hydraulic Modelling
-Water Policy and Management
-Dissertation
-Dissertation Project

EDUCATIONAL AIMS OF THE PROGRAMME

The programme aims to provide graduates with:
-A comprehensive understanding of engineering mechanics for bridge analysis
-The ability to select and apply the most appropriate analysis methodology for problems in bridge engineering including advanced and new methods
-The ability to design bridge structures in a variety of construction materials
-A working knowledge of the key UK and European standards and codes of practice associated with the design, analysis and construction of bridge structures and the ability to interpret and apply these to both familiar and unfamiliar problems
-The necessary technical further learning towards fulfilling the educational base for the professional qualification of Chartered Engineer

PROGRAMME LEARNING OUTCOMES

The programme provides opportunities for students to develop and demonstrate knowledge and understanding, skills, qualities and other attributes in the following areas:

Knowledge and understanding
-A knowledge and understanding of the key UK and European standards and codes of practice relating to bridge engineering
-The ability to interpret and apply the appropriate UK and European standards and codes of practiceto bridge design for both familiar and unfamiliar situations
-A knowledge and understanding of the construction of different types of bridge structures using different types of materials (e.g. concrete and steel)
-A knowledge and understanding of the common and less common materials used in bridge engineering
-A comprehensive understanding of the principles of engineering mechanics underpinning bridge engineering
-The ability to critically evaluate bridge engineering concepts
-The ability to apply the appropriate analysis methodologies to common bridge engineering problems as well as unfamiliar problems
-The ability to understand the limitations of bridge analysis methods
-A knowledge and understanding to work with information that may be uncertain or incomplete
-A Knowledge and understanding of sustainable development related to bridges
-The awareness of the commercial, social and environmental impacts associated with bridges
-An awareness and ability to make general evaluations of risk associated with the design and construction of bridge structures including health and safety, environmental and commercial risk
-A critical awareness of new developments in the field of bridge engineering

Intellectual / cognitive skills
-The ability to tackle problems familiar or otherwise which have uncertain or incomplete data (A,B)
-The ability to generate innovative bridge designs (B)
-The ability to use theory or experimental research to improve design and/or analysis
-The ability to apply fundamental knowledge to investigate new and emerging technologies
-Synthesis and critical appraisal of the thoughts of others

Professional practical skills
-The awareness of professional and ethical conduct
-A Knowledge and understanding of bridge engineering in a commercial/business context
-Ability to use computer software to assist towards bridge analysis
-Ability to produce a high quality report
-Ability of carry out technical oral presentations

Key / transferable skills
-Communicate engineering design, concepts, analysis and data in a clear and effective manner
-Collect and analyse research data
-Time and resource management planning

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This fully accredited MSc programme helps graduate engineers to acquire advanced capabilities and in-depth knowledge across a range of civil-engineering disciplines, including bridge engineering, construction management, and geotechnical, structural and water engineering. Read more
This fully accredited MSc programme helps graduate engineers to acquire advanced capabilities and in-depth knowledge across a range of civil-engineering disciplines, including bridge engineering, construction management, and geotechnical, structural and water engineering.

This well-established programme is delivered by experienced University staff, together with practising engineers from consultancies and local authorities.

PROGRAMME OVERVIEW

You can access six study streams on this Masters programme:
-Bridge Engineering
-Construction Management
-Geotechnical Engineering
-Structural Engineering
-Water Engineering and Environmental Engineering
-Infrastructure Engineering and Management

As well as supporting the career development of Civil Engineering graduates, this programme provides the necessary further learning for engineers working in the construction industry who hold related first degrees such as engineering geology or construction management.

It is also designed to update the technical skills of practising engineers engaged in the planning, design, construction and operation of civil-engineering works.

PROGRAMME STRUCTURE

This programme is studied full-time over one academic year and part-time / distance learning for between two to five academic years. It consists of eight taught modules and a dissertation. This degree is accredited as meeting the requirements for Further Learning for a Chartered Engineer (CEng) for candidates who have already acquired an Accredited CEng (Partial) BEng(Hons) or an Accredited IEng (Full) BEng/BSc (Hons) undergraduate first degree.

The following modules are indicative, reflecting the information available at the time of publication. Please note that not all modules described are compulsory and may be subject to teaching availability and/or student demand.

Structural Engineering Group Modules
-Steel Building Design
-Space Structures
-Structural Mechanics and Finite Elements
-Subsea Engineering
-Concrete Building Design
-Structural Safety and Reliability
-Earthquake Engineering
-Design of Masonry Structures

Bridge Engineering Group Modules
-Bridge Deck Loading and Analysis
-Prestressed Concrete Bridge Design
-Durability of Bridges and Structures
-Bridge Management
-Steel and Composite Bridge Design
-Long-Span Bridges

Geotechnical Engineering Group Modules
-Advanced Soil Mechanics
-Energy Geotechnics
-Geotechnical Structures
-Soil-Structure Interaction
-Deep Foundations and Earth Retaining Structures

Construction Management Group Modules
-Construction Management and Law
-Construction Organisation
-Project and Risk Management

Infrastructure Engineering Group Modules
-Infrastructure Investment and Financing
-Infrastructure Interdependencies and Resilience
-Infrastructure Asset Management
-Sustainability and Infrastructure

Water and Environmental Engineering Group Modules
-Environmental Health
-Water Treatment Optional
-Wastewater Treatment
-Applied Chemistry and Microbiology
-Pollution Control
-Groundwater Control
-Regulation and Management
-Water Resources

Dissertation
-Dissertation Project

EDUCATIONAL AIMS OF THE PROGRAMME

The Civil Engineering programme aims to provide graduate engineers with:
-Advanced capabilities and in-depth knowledge in a range of specialised aspects of civil engineering
-It is also designed to update the technical skills of practising engineers engaged in the planning, design, construction and operation of civil engineering works and to contribute to a personal professional development programme
-A working knowledge of some of the UK and European standards and codes of practice associated with the design, analysis and construction of civil engineering structures and the ability to interpret and apply these to both familiar and unfamiliar problems
-The necessary further learning towards fulfilling the educational base for the professional qualification of Chartered Engineer in both a technical or non-technical capacity dependent upon module selection

PROGRAMME LEARNING OUTCOMES

The programme provides opportunities for students to develop and demonstrate knowledge and understanding, skills, qualities and other attributes in the following areas:

Knowledge and understanding
-The mathematical principles necessary to underpin their education in civil engineering and to enable them to apply mathematical methods, tools and notations proficiently in the analysis and solution of multi-disciplinary open ended engineering problems
-The properties, behaviour and use of relevant materials
-The management techniques which may be used to achieve civil engineering objectives within that context
-Some of the roles of management techniques and codes of practice in design
-The principles and implementation of some advanced design and management techniques specific to civil engineering
-Mathematical and computer models relevant to civil engineering, and an appreciation of their limitations
-The role of the professional engineer in society, including health, safety, environmental, sustainability, ethical issues and risk assessment within civil engineering
-The wider multidisciplinary engineering context and its underlying principles
-Developing technologies related to civil engineering and the ability to develop an ability to synthesize and critically appraise some of them
-The framework of relevant requirements governing engineering activities, including personnel, health, safety, and risk issues (an awareness of)
-The advanced design processes and methodologies and the ability to adapt them in open ended situations.

Intellectual / cognitive skills
-Analyse and solve problems
-Think strategically
-Synthesis of complex sets of information
-Understand the changing nature of knowledge and practice in the management of culturally diverse construction environments
-Select and transfer knowledge and methods from other sectors to construction-based organisation
-Produce sound designs to meet specified requirements such as Eurocodes, deploying commercial software packages as appropriate
-Dynthesis and critical appraisal of the thoughts of others

Professional practical skills
-Awareness of professional and ethical conduct
-Extract data pertinent to an unfamiliar problem, and apply its solution using computer based engineering tools where appropriate
-Evaluate and integrate information and processes in project work
-Present information orally to others
-Show a capability to act decisively in a coordinated way using theory, better practice and harness this to experience
-Use concepts and theories to make engineering judgments in the absence of complete data
-Observe, record and interpret data using appropriate statistical methods and to present results in appropriate forms for the civil engineering industry

Key / transferable skills
-Communicate engineering design, concepts, analysis and data in a clear and effective manner
-Collect and analyse research data
-Time and resource management planning

GLOBAL OPPORTUNITIES

We often give our students the opportunity to acquire international experience during their degrees by taking advantage of our exchange agreements with overseas universities.

In addition to the hugely enjoyable and satisfying experience, time spent abroad adds a distinctive element to your CV.

Read less
This well-established and fully accredited MSc programme will develop the knowledge and skills acquired in your undergraduate programme. Read more
This well-established and fully accredited MSc programme will develop the knowledge and skills acquired in your undergraduate programme. It builds the advanced capabilities in analysis and codified design in specialised aspects of structural engineering that are required by industry.

PROGRAMME OVERVIEW

Our Structural Engineering postgraduate programme is delivered by the Faculty’s own staff, together with practising engineers from consultancies and local authorities.

For practising engineers engaged in the planning, design and construction of structural engineering works, this programme provides an opportunity to update their knowledge of current design practice and to become familiar with developments in codes and methods of analysis.

You will be able to choose from a rich and varied selection of specialist structural engineering subjects. The programme is offered in the standard full-time mode, in addition to part-time and distance learning options.

Graduates from the programme are highly employable and may progress to relevant specialist PhD or EngD research programmes in the field.

PROGRAMME STRUCTURE

This programme is studied full-time over one academic year and part-time or distance learning over two to five academic years. It consists of eight taught modules and a dissertation project.

This degree is accredited as meeting the requirements for Further Learning for a Chartered Engineer (CEng) for candidates who have already acquired an Accredited CEng (Partial) BEng (Hons) or an Accredited IEng (Full) BEng/BSc (Hons) undergraduate first degree. The following modules are indicative, reflecting the information available at the time of publication. Please note that not all modules described are compulsory and may be subject to teaching availability and/or student demand.

Structural Engineering Group Modules
-Steel Building Design
-Space Structures
-Structural Mechanics and Finite Elements
-Subsea Engineering
-Concrete Building Design
-Structural Safety and Reliability
-Earthquake Engineering
-Design of Masonry Structures

Bridge Engineering Group Modules
-Bridge Deck Loading and Analysis
-Prestressed Concrete Bridge Design
-Durability of Bridges and Structures
-Bridge Management
-Steel and Composite Bridge Design
-Long-Span Bridges

Geotechnical Engineering Group Modules
-Advanced Soil Mechanics
-Energy Geotechnics
-Geotechnical Structures
-Soil-Structure Interaction
-Deep Foundations and Earth Retaining Structures

Construction Management Group Modules
-Construction Management and Law
-Construction Organisation
-Project and Risk Management

Infrastructure Engineering Group Modules
-Infrastructure Investment and Financing
-Infrastructure Interdependencies and Resilience
-Infrastructure Asset Management
-Sustainability and Infrastructure

Water and Environmental Engineering Group Modules
-Environmental Health
-Water Treatment
-Wastewater Treatment
-Applied Chemistry and Microbiology
-Pollution Control
-Groundwater Control
-Regulation and Management
-Water Resources

Dissertation
-Dissertation Project

Apart from the usual full-time mode, there are also part-time options. The majority of Bridge, Geotechnical and Structural Engineering modules can be studied by distance learning through the use of an interactive web-based e-learning platform (SurreyLearn). This programme can be studied via distance learning, which allows a high level of flexibility and enables you to study alongside other commitments you may have.

EDUCATIONAL AIMS OF THE PROGRAMME

The programme aims to provide graduates with:
-A comprehensive understanding of engineering mechanics for structural analysis
-The ability to select and apply the most appropriate analysis methodology for problems in structural engineering including advanced and new methods
-The ability to design structures in a variety of construction materials
-A working knowledge of the key UK and European standards and codes of practice associated with the design, analysis and construction of civil engineering structures and the ability to interpret and apply these to both familiar and unfamiliar problems
-The necessary technical further learning towards fulfilling the educational base for the professional qualification of Chartered Engineer

PROGRAMME LEARNING OUTCOMES

Knowledge and understanding
-A knowledge and understanding of the key UK and European standards and codes of practice relating to structural engineering
-The ability to interpret and apply the appropriate UK and European standards and codes of practice to structural design for both familiar and unfamiliar situations
-A knowledge and understanding of the construction of different types of structures using different types of materials (e.g. concrete and steel)
-A knowledge and understanding of the common and less common materials used in structural engineering
-A comprehensive understanding of the principles of engineering mechanics underpinning structural engineering
-The ability to critically evaluate structural engineering concepts
-The ability to apply the appropriate analysis methodologies to common structural engineering problems as well as unfamiliar problems
-The ability to understand the limitations of structural analysis methods
-A knowledge and understanding to work with information that may be uncertain or incomplete
-A Knowledge and understanding of sustainable development related to structures
-The awareness of the commercial, social and environmental impacts associated with structures
-An awareness and ability to make general evaluations of risk associated with the design and construction of structures including health and safety, environmental and commercial risk
-A critical awareness of new developments in the field of structural engineering

Intellectual / cognitive skills
-The ability to tackle problems familiar or otherwise which have uncertain or incomplete data
-The ability to generate innovative structural designs
-The ability to use theory or experimental research to improve design and/or analysis
-The ability to apply fundamental knowledge to investigate new and emerging technologies
-Produce sound designs to meet specified requirements such as Eurocodes, deploying commercial software packages as appropriate
-Synthesis and critical appraisal of the thoughts of others

Professional practical skills
-The awareness of professional and ethical conduct
-A Knowledge and understanding of structural engineering in a commercial/business context
-Ability to use computer software to assist towards structural analysis
-Ability to produce a high quality report
-Ability of carry out technical oral presentations

Key / transferable skills
-Communicate engineering design, concepts, analysis and data in a clear and effective manner
-Collect and analyse research data
-Time and resource management planning

GLOBAL OPPORTUNITIES

We often give our students the opportunity to acquire international experience during their degrees by taking advantage of our exchange agreements with overseas universities.

In addition to the hugely enjoyable and satisfying experience, time spent abroad adds a distinctive element to your CV.

Read less
Enhance your career prospects with this Masters in Manufacturing Engineering at Liverpool John Moores University. This postgraduate course is accredited by IMechE, meets Chartered Engineer requirements and has close links with industry. Read more
Enhance your career prospects with this Masters in Manufacturing Engineering at Liverpool John Moores University. This postgraduate course is accredited by IMechE, meets Chartered Engineer requirements and has close links with industry.

•Complete this masters degree in one year full time
•Accredited by the Institution of Mechanical Engineers (IMechE) and meets Chartered Engineer requirements
•Study at one the UK’s leading Engineering Schools
•Programme informed by internationally-acclaimed research in LJMU’s General Engineering Research Institute
•Close industry links and excellent career prospects

The MSc programme will equip you with a range of skills and techniques appropriate for companies working in the field of advanced manufacturing and engineering.

These advanced skills will allow you to make an immediate contribution to a company's manufacturing capability and operation, and to ultimately progress into senior management positions.

The course is designed for graduates wishing to reach senior positions as engineers and technical managers in manufacturing process engineering, with particular emphasis on advanced manufacturing technologies and the application of advanced materials.

In addition, it covers quality engineering, logistics and management skills.

This programme builds on experience developed at undergraduate level and provides a progression route for graduates from relevant programmes in mechanical and manufacturing engineering.

Strong links with an Industry Advisory Committee, provide you with the opportunity to become part of local, national and international organisations and their networks.

Please see guidance below on core and option modules for further information on what you will study.

Level 7

Advanced Materials
Optical Measurement and Inspection
Manufacturing Process Engineering
Manufacturing Management
Research Skills
Project Management
Automation Systems
Supply Chain Modelling
MSc Project
Advanced Engineering Design
Operations Research
Safety and Reliability
Alternative Energy Systems
Modelling Matlab and Simulink
Programming for Engineering
LabVIEW

Further guidance on modules

The information listed in the section entitled ‘What you will study’ is an overview of the academic content of the programme that will take the form of either core or option modules. Modules are designated as core or option in accordance with professional body requirements and internal Academic Framework review, so may be subject to change. Students will be required to undertake modules that the University designates as core and will have a choice of designated option modules. Additionally, option modules may be offered subject to meeting minimum student numbers.

Academic Framework reviews are conducted by LJMU from time to time to ensure that academic standards continue to be maintained. A review is currently in progress and will be operational for the academic year 2016/2017. Final details of this programme’s designated core and option modules will be made available on LJMU’s website as soon as possible and prior to formal enrolment for the academic year 2016/2017.

Please email if you require further guidance or clarification.

Read less
Explore the latest electrical engineering and process control techniques through this Masters in Microelectronic Systems Design. This postgraduate course is accredited by IET and meets Chartered Engineer status. Read more
Explore the latest electrical engineering and process control techniques through this Masters in Microelectronic Systems Design. This postgraduate course is accredited by IET and meets Chartered Engineer status.

•Complete this masters degree in one year (full time)
•Accredited by the Institution of Engineering and Technology (IET), the course meets Chartered Engineer status requirements
•Study at one the UK’s leading Engineering Schools
•Programme informed by internationally-acclaimed research
•Close industry links
•Excellent career opportunities in roles such as system designers, analysts, and senior engineers in the fields of electrical engineering, process control, and related industries

This Masters course will equip you with the technical and management skills you need to progress to senior professional positions, specialising in the design, fabrication and testing of microelectronic devices.

You will study the fundamental principles that drive future developments in microelectronics. We offer the opportunity to develop the critical, analytical and experimental skills to solve practical problems and work at the cutting edge of this rapidly developing field.

You’ll learn how to critically analyse designs, their functionality and expected reliability and it will also be important for you to gain a strong understanding of the capabilities and limitations of modelling and simulation tools.

The programme design provides opportunities to practice communication skills at Chartered Engineer level. You’ll gain sought after professional behavioural traits to prepare you for technical and management roles in microelectrical system design.

You will also undertake an individual project giving the opportunity to focus on your area of interest, working with our world-leading researchers.

Please see guidance below on core and option modules for further information on what you will study.
Level 7
Dynamic systems simulation
Microelectronic systems design
VLSI devices, fabrication and testing
Embedded systems
VLSI design
Research skills
Modelling with Matlab and Simulink
MSc project
Advanced single processing
Operations research
Safety and reliability
Project management
Programming for engineering
LabVIEW
Professional and leadership skills

Further guidance on modules

The information listed in the section entitled ‘What you will study’ is an overview of the academic content of the programme that will take the form of either core or option modules. Modules are designated as core or option in accordance with professional body requirements and internal Academic Framework review, so may be subject to change. Students will be required to undertake modules that the University designates as core and will have a choice of designated option modules. Additionally, option modules may be offered subject to meeting minimum student numbers.

Academic Framework reviews are conducted by LJMU from time to time to ensure that academic standards continue to be maintained. A review is currently in progress and will be operational for the academic year 2016/2017. Final details of this programme’s designated core and option modules will be made available on LJMU’s website as soon as possible and prior to formal enrolment for the academic year 2016/2017.

Please email if you require further guidance or clarification.

Read less
This Masters in Telecommunications Engineering is accredited by IET and meets Chartered Engineer Status. Excel in the latest telecommunications technologies on this industry focused Liverpool John Moores University postgraduate course. Read more
This Masters in Telecommunications Engineering is accredited by IET and meets Chartered Engineer Status. Excel in the latest telecommunications technologies on this industry focused Liverpool John Moores University postgraduate course

•Complete this masters degree in one year (full time)
•Study at one the UK’s leading Engineering Schools
•Accredited by the Institution of Engineering and Technology (IET) and meets Chartered Engineer requirements
•Programme informed by internationally-acclaimed research in LJMU’s Electrical and Electronic Engineering Research Centre
•Close industry links
•Excellent career opportunities for positions including system designers, analysts, and senior engineers in the fields communications, computer networks and telecommunications

The MSc in Telecommunications Engineering is designed to develop engineers for the telecommunications industry who are able to design, commission, and manage telecommunications systems.

The programme benefits from being delivered by academics from LJMU’s School of Engineering, Technology and Maritime Operations, the General Engineering Research Institute (GERI) and the School of Computing and Mathematical Sciences.

The course team has strong industrial links and has established an international research profile. This is reflected in the programme securing accreditation by the Institution of Engineering and Technology (IET) - formerly the IEE - to meet its requirements for Chartered Engineer status.

The course covers radio frequency and microwave technologies, electronics and communications technologies, computer networks and wireless computing, and management.

The curriculum emphasises the application of the technologies and as such the course is supported by modern systems of modelling and simulation, an extensive laboratory programme and lectures from industrial experts.

You will have an opportunity to complete industrially-based projects and work experience in the areas of microwave, optical sensing, instrumentation, antenna design, etc.

Most of the MSc projects are undertaken in the Radio Frequency and Microwave research group within the General Engineering Research Institute. Research interests are concentrated into six main areas: Radio Frequency and Microwave (RFM) Applications, Underwater Communications, Radio Frequency Identification Technology (RFID) and wireless Applications, Sustainable Technologies, Non-destructive sensing and Terahertz laser sources.

LJMU’s international reputation in this field is reflected in the substantial research funds secured from the UK Engineering and Physical Sciences Research Council (EPSRC), Department of Trade and Industry, Envirolink, European Community and directly from industry including BP, United Utilities, Organon, Protensive, MercaChem and Biotage, Aspen Electronic, Anritsu and NEL.

Please see guidance below on core and option modules for further information on what you will study.
Level 7
Digital communications systems
Wireless networks and technologies
Telecommunications systems
Networks and protocols
Transmission media
Research skills
Modelling with Matlab and Simulink
MSc project
Advanced signal processing
Operations research
Safety and reliability
Project management
Programming for engineering
LabVIEW
Professional and leadership skills


Further guidance on modules
The information listed in the section entitled ‘What you will study’ is an overview of the academic content of the programme that will take the form of either core or option modules. Modules are designated as core or option in accordance with professional body requirements and internal Academic Framework review, so may be subject to change. Students will be required to undertake modules that the University designates as core and will have a choice of designated option modules. Additionally, option modules may be offered subject to meeting minimum student numbers.

Academic Framework reviews are conducted by LJMU from time to time to ensure that academic standards continue to be maintained. A review is currently in progress and will be operational for the academic year 2016/2017. Final details of this programme’s designated core and option modules will be made available on LJMU’s website as soon as possible and prior to formal enrolment for the academic year 2016/2017.

Please email if you require further guidance or clarification.

Read less
The Master of Science in Subsea Engineering seeks to prepare highly-trained, highly-qualified, business-aware graduates that can make an immediate impact in their chosen career, and who can address the need for key skills in the subsea industry. Read more
The Master of Science in Subsea Engineering seeks to prepare highly-trained, highly-qualified, business-aware graduates that can make an immediate impact in their chosen career, and who can address the need for key skills in the subsea industry. Subsea Engineering at the University of Aberdeen has a unique relationship with the subsea industry both locally and internationally, and the programme receives contributions from local industrial organisations in terms of relevant and up-to-the minute contributions to teaching, and support in the specification of group and individual projects.

Aberdeen is the heart of the European oil and gas industry, an international hub for companies engaged in Subsea Engineering. A degree from the University of Aberdeen puts you in a unique position to develop business links alongside of learning and developing international skills within the flexible, modular programme.



Full-Time or Part-Time (Distance) Study
===============================
The programme is available as both full-time and part-time (distance learning) study. Distance learning students make use of the University's online virtual learning environment (WebCT) to study via the internet. No attendance at the University is required making it a fully internationally available programme and one which can be studied alongside your career.



About the Programme
=================
The programme seeks to best address the needs of the industry today in terms of subject areas of fundamental importance. The programme objectives are to provide students with:


Increased technical depth and breadth of knowledge and understanding of the development and operation of subsea technologies and systems, from wellhead to topside structure interconnections.

Intellectual and practical skills so that they can apply sound engineering principles and analysis methods to the design and installation of subsea systems, and can use and adapt appropriate analysis tools and techniques, specialist design software and Standards for design improvements and performance optimisation.

The opportunity to further enhance their transferable and personal skills in self-study, communication, report writing, project and time management, and problem solving.

An awareness of the roles and challenges of a practising subsea engineer based on course contents which are tailored to the current and future needs of industry, and therefore provides students with the knowledge and understanding and skills necessary for technical leadership and managerial responsibility.



Syllabus
=======
Students study the following:

Subsea Integrity
Project Management
Subsea Safety and Reliability Management
Subsea Controls
Subsea Construction, Inspection & Maintenance
Pipelines & Soil Mechanics
Riser Systems & Hydrodynamics
Flow Assurance
Individual Project



Assessment
==========
The modules are assessed by a combination of coursework and written examination. The distance learning coursework is submitted to the course tutor through the web-site and marks and comments will be sent back, also via the web, on campus submission is either by email or in person at teaching sessions. Each module has a timetable which details when the coursework is due and when the exam is scheduled to take place. Arrangements can be made for examinations to be taken at a convenient place for you. Distance learning students near to Aberdeen are able to take their examinations at the University.
Examinations are usually held towards the end of January and the end of May. Students sit the examination within their own timezone (e.g. 9am local time).



Teaching
=======
The courses are completely modular in structure and have been carefully developed to articulate to each other to provide a variety of levels of provision, suiting the needs of the participants. A choice of exit levels is provided to suit the needs of the participants thus leading to the award of a postgraduate Certificate, Diploma or MSc qualification. Each level is a necessary requirement for entry to the next one. Full-time students complete 4 modules per half session while part-time students complete up to 2.



Funding
=======
Funding exists for this programme (dependent on eligibility). Please visit http://www.abdn.ac.uk/funding



More Information
=============
More information about this programme can be found on our Postgraduate Prospectus: http://www.abdn.ac.uk/prospectus/pgrad/study/taught.php?code=subsea_engineering

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