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Masters Degrees (Unmanned Aerial Vehicles)

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Aerospace systems are the future of the aerospace industry and constitute the major component of all modern aircraft. They are the essential onboard systems that ensure the safe and accurate operation of all aerospace vehicles, from civil passenger planes to sophisticated unmanned aerial vehicles. Read more
Aerospace systems are the future of the aerospace industry and constitute the major component of all modern aircraft. They are the essential onboard systems that ensure the safe and accurate operation of all aerospace vehicles, from civil passenger planes to sophisticated unmanned aerial vehicles.

Why this programme

◾The University of Glasgow has been the home of Aerospace Research for over 60 years. This long-standing activity has culminated in the Division of Aerospace Sciences having internationally recognised expertise in all areas of Aeronautics and Aerospace Systems.
◾The University of Glasgow is one of the few institutions in the UK, and the only University in Scotland, to offer an Aerospace Systems MSc.
◾Aeronautical engineering at the University of Glasgow is consistently highly ranked recently achieving 10th in the UK and 1st in Scotland (Complete University Guide 2017).
◾If you are an aeronautical engineering or avionics graduate wanting to improve your skills and knowledge; a graduate of another engineering discipline, mathematics or physics and you want to change field; looking for a well-rounded postgraduate qualification in electronics & electrical engineering to enhance your career prospects; this programme is designed for you.
◾Students in this programme can benefit from access to our outstanding facilities: including several wind tunnels, a flight simulation lab, an autonomous unmanned vehicle (UAV) laboratory, helicopter test rig laboratories and computer labs for modelling and simulation.

Programme structure

Modes of delivery of the MSc in Aerospace Systems include lectures, seminars and tutorials and allow students the opportunity to take part in lab, project and team work.

The summer period is dedicated to project work, with either academic or industrial placements providing the context for your project.

Semester 1 core courses
◾Aircraft flight dynamics
◾Control M
◾Navigation systems
◾Simulation of aerospace systems
◾Space flight dynamics 1.

Semester 2 core courses
◾Autonomous vehicle guidance systems
◾Fault detection, isolation and reconfiguration
◾Radar and electro-optic systems
◾Robust control 5.
◾Aerospace systems team design project.

Projects

◾To complete the MSc degree you must undertake a project worth 60 credits.
◾The project will integrate subject knowledge and skills that you acquire during the MSc programme
◾The project is an important part of your MSc where you can apply your newly learned skills and show to future employers that you have been working on cutting edge projects relevant to the industry.
◾You can choose a topic from a list of MSc projects in Aerospace Systems. Alternatively, should you have your own idea for a project, department members are always open to discussion of topics

Example projects

Examples of projects can be found online

*Posters shown are for illustrative purposes

Accreditation

MSc Aerospace Systems is accredited by the Royal Aeronautical Society (RAeS)

Industry links and employability

◾You will be introduced to this exciting multi-disciplinary area of technology, gaining expertise in autonomous guidance and navigation, advanced aerospace control, simulation and simulators, fault detection and isolation, electro-optic and radar systems, and space systems.
◾The School of Engineering has extensive contacts with industrial partners who contribute to several of their taught courses, through active teaching, advising on projects, curriculum development, and panel discussion.
◾During the programme students have an opportunity to develop and practice relevant professional and transferrable skills, and to meet and learn from employers about working in the aerospace industry.

Career prospects

Career opportunities include aerospace, defence, laser targeting systems, radar development, electro-optics, autonomous systems and systems modelling.

Graduates of this programme have gone on to positions such as:
Software Engineer at Hewlett-Packard
Avionic and Mission System Engineer at Qinetiq
Engineering Corporal & Driver at Hellenic Army.

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The Aerospace Engineering MSc aims to further develop students' knowledge of and expertise in specialist engineering subjects associated with the main application areas of aeronautical engineering. Read more
The Aerospace Engineering MSc aims to further develop students' knowledge of and expertise in specialist engineering subjects associated with the main application areas of aeronautical engineering. Particular prominence is given to Sustainable Aviation, Advanced Materials and Processes, Experimental Methods and Techniques, Computational Fluid Dynamics, Structural Analysis and Simulation, Flight Dynamics and Simulation, and Advanced Aircraft Systems, in particular Unmanned Aerial Vehicles.

An emphasis on applied technical work will strengthen the engineering development skills of students from an academic background. The programme is delivered by a specialist team of academics. Access to state of the art laboratory and computing facilities within the new Engineering and Computing building. Personal tutor support throughout the postgraduate study. Excellent links with a number of industrial organisations enable access to the latest technology and real-world applications.

WHY CHOOSE THIS COURSE?

The work carried out on this course will provide the demonstrable expertise necessary to help secure professional level employment in related industries.

The Aerospace Engineering MSc curriculum consists of eight mandatory core topics and a substantial MSc project. Successful completion of all elements leads to the award of MSc in Aerospace Engineering. Completion of the taught modules without a project leads to the award of a Post Graduate Diploma.

WHAT WILL I LEARN?

The mandatory study topics are as follows:
-Mathematical modelling in Aerospace Engineering
-Unmanned Aerial Vehicle Systems (UAV)
-Experimental Methods and Techniques
-Computational Fluid Dynamics (CFD)
-Advanced Materials and Processes
-Design and analysis of Aerospace structures
-Flight Dynamics and Simulation
-Project Management
-Individual Project

The substantial individual project gives students the opportunity to work on a detailed area of related technology alongside an experienced academic supervisor. Some projects are offered in conjunction with the work of the Faculty’s research centres or industry. Typical project titles include:
-Integration of Advanced Materials into Aircraft Structures
-Sustainable Aircraft Development and Design
-Intelligent Power Generation
-UAV SWARM Systems

You will have access to:
-Unique Flight Simulator Suite (3 flight simulators, 2 UAV ground control systems plus the associated UAV,1 Air Traffic Control unit);
Harrier Jump Jet;
-New bespoke Mercedes-Petronas low speed wind tunnel and associated measurement;
-Faculty workshop (metal/woodwork), Composites Laboratory, Metrology Laboratory, Electrical Laboratory, Communications and Signal Processing Laboratory, Cogent Wireless Intelligent Sensing Laboratory
-Faculty Open Access Computer Facilities

HOW WILL THIS COURSE ENHANCE MY CAREER PROSPECTS?

The specialist topics studied on the programme will prepare you for work in specialist companies involved with aeronautical engineering. There are also many roles in related industries that rely on the technology. Possible destinations include:
-Design, Development, Operations and Management;
-Projects/Systems/Structural/Avionics Engineers.

Typical student destinations include:
-BAE Systems
-Rolls-Royce
-Airbus
-Dassult

Opportunities also exist to complete a PhD research degree upon completion of the master’s course:
-Research at Coventry University
-Cogent Computing
-Control Theory and Applications Centre
-Distributed Systems and Modelling

Aerospace Engineering MSc has been developed to improve upon the fundamental undergraduate knowledge of aerospace/aeronautical students and help mechanical students learn more about the application of their subject to aircraft. The whole aerospace/aviation industry is committed to a more sustainable and a more efficient future. The techniques, methods and subjects covered in this degree explore the ever changing industrial environment in more detail.

GLOBAL LEADERS PROGRAMME

To prepare students for the challenges of the global employment market and to strengthen and develop their broader personal and professional skills Coventry University has developed a unique Global Leaders Programme.

The objectives of the programme, in which postgraduate and eligible undergraduate students can participate, is to provide practical career workshops and enable participants to experience different business cultures.

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Completing this Masters degree at Liverpool John Moores University will give you the knowledge and practical skills to become a specialist in Unmanned Aerial Vehicles or UAVs. Read more
Completing this Masters degree at Liverpool John Moores University will give you the knowledge and practical skills to become a specialist in Unmanned Aerial Vehicles or UAVs.

•Complete this masters degree in one year full time, two years part time
•Highly practical Masters degree
•Secure understanding of legal and regulatory frameworks
•Gain the expertise to exploit this exciting new technology in a wide range of industries in the UK, Europe and around the world
•Curriculum informed by ongoing research and consultancy in drone technology
•Build and test fly your own multi-rotor drone

This taught masters degree will give you the practical, theoretical and regulatory knowledge to lead and undertake all aspects of the implementation and operation of UAV systems within a commercial enterprise in a safe, efficient and legal manner.

You will also secure essential practical skills in constructing, flying and operating drone systems. You will build your own, professional standard, multi-rotor drone system; test fly this system and then use it for practical assignments during the programme, including undertaking a research dissertation project. At the end of the course you can take your drone system with you and use as part of your career.

In today’s world, to be commercially successful in drone applications, you must be safe and operating totally with the aviation law. That’s why the programme includes a specialist module on UAV Operations and the Law. Not only will you know the legal and regulatory framework, more importantly you will learn how to interpret it so that you can design complex and challenging UAV operations within the current legal and regulatory framework.

Please see guidance below on core and option modules for further information on what you will study.
Level 7
UAV Technology and Operations: This will teach you the basics of the technology at systems level. As part of this module you will learn to fly UAVs under experienced qualified instructors, first on simulators and then out in the field.
Drone Construction: You build your own multi-rotor drone, complete with flight controller, GPS systems and radio control system. Under the guidance of the teaching team, you will test and then fly your drone in a series of increasingly demanding exercises.
Research Methods: In order to obtain your Masters degree you will have to undertake an individual research project and write it up as a dissertation. In this module you will learn the research, presentation and critical appraisal skills you will need to successfully complete your project.
Advanced UAV Technology and Operations: Practical flying and operating experience, now in more advanced scenarios, is an important element of this module with further simulator exercises and another 5 full-day flying sessions.
UAV Operations and the Law: Its important to know the legal and regulatory framework within which UAVs operate, to become qualified for commercial UAV use its essential. Here you will learn about the law, the guidelines and get to practice your understanding with 'moot' exercises – debating complex operational scenarios.
Optical Measurement and Sensing: Of all the data gathering devices carried by UAV’s the overwhelming majority are optical and to get the best results you will need to understand this technology. Its not just video cameras; you need to fully understand technologies including stereo photogrammetry, LIDAR, structured light and shape from motion systems if you are to be effective in data gathering from drones.
Dissertation Project: On successful completion of the taught part of the programme you will complete an individual research or advanced practice project. Project topics can be self-generated, or drawn from a range of real-world applications originating from outside of the university among the research team’s industrial contacts.

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 recent growth in the desire to ‘build’ smart cities requires employees who understand the latest an emerging smart networking technologies including… Read more
The recent growth in the desire to ‘build’ smart cities requires employees who understand the latest an emerging smart networking technologies including Cloud Computing, Virtual Networking, Data Centre Management, Internet of things (IoT), 4G/5G Mobile Networks, Mobile App Development, Unmanned Aerial Vehicles (UAVs), and Data and Network Security, which are creating new opportunities for business education, research and many other aspects of our daily lives.

The course aims to produce graduates with the vision, knowledge and skills to apply these latest smart networking technologies to optimise the ICT networking infrastructure for businesses to design innovative networking solutions, and to develop smart networking-enabled applications and services.

It aims to provide you with the necessary current knowledge and skills to allow you to make an immediate contribution to relevant industries and research environments. The blend of theory and practical applications in smart networking will enhance your employability.

There are six entry points through the year. This allows you to start when it is most suitable. The entry points are:

• September
• November
• January
• March
• June
• July

Visit the website: https://www.beds.ac.uk/howtoapply/courses/postgraduate/next-year/sensors-and-smart-cities#about

Course detail

The expertise that the University of Bedfordshire has in the related areas of smart cities, and the work it has undertaken as part of a world-leading smart city project called MK:Smart means that you will be at the forefront of developments in this exciting area.

Modules

• Wireless Embedded Systems
• Information Governance and Compliance
• Smart Infrastructure and Data Architecture
• Research Methodologies and Project Management
• MSc Project – Sensors and Smart Cities

Assessment

Most units are assessed with examinations and coursework. Details can be found in the individual module specifications. Assessment is carried out according to context and purpose and recognises that you may exhibit different aptitudes in different forms of assessment:

• Most of the units require collaborative assessments that ask students to form teams and work on a selected project or research topics. However, students will be assessed individually based on their contributions to the overall work.
• Oral presentations are also important assessment method in many units that require student to present the projects developed or researched outlined by the assignment specifications.
• There are formal unseen written examinations for two 30 credit units.
• Individual project that can formed as different ways with conjunctions with their supervisors but has to be suitable to the course scope.

Careers

Employability is understood widely as encompassing knowledge, skills and a professional attitude which your tutors expect you to display in all your units. All University of Bedfordshire courses aim to help you to be prepared for the world of work. The Careers Service is there to support you throughout the three years of your study. On the one hand, our curriculum gives you skills that are valuable for a career within Finance in particular but is also relevant for a much wider range of applications such as information analysis or decision support systems. On the other hand, the department will fully use our industry collaboration connections and resources to serve the course delivery. The collaboration industry partners include car manufactory, MK:SmartCity project and airport data security project and so on. These industry collaborations will well help students developing their real world problem solving skills and extended their employability.

The final year unit `Professional Project Management in particular requires you to work in a team so as to apply a current project management methodology that embraces all of these knowledge areas in an integrated way while going through the stages of planning, execution and project control; you will work as part of a team, take responsibility and make autonomous decisions that impact on the project team performance.

Funding

For information on available funding, please follow the link: https://www.beds.ac.uk/howtoapply/money/scholarships/pg

How to apply

For information on how to apply, please follow the link: https://www.beds.ac.uk/howtoapply/course/applicationform

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The recent growth in the desire to ‘build’ smart cities requires employees who understand the latest an emerging smart networking technologies including… Read more
The recent growth in the desire to ‘build’ smart cities requires employees who understand the latest an emerging smart networking technologies including Cloud Computing, Virtual Networking, Data Centre Management, Internet of things (IoT), 4G/5G Mobile Networks, Mobile App Development, Unmanned Aerial Vehicles (UAVs), and Data and Network Security, which are creating new opportunities for business education, research and many other aspects of our daily lives.

The course aims to produce graduates with the vision, knowledge and skills to apply these latest smart networking technologies to optimise the ICT networking infrastructure for businesses to design innovative networking solutions, and to develop smart networking-enabled applications and services.

It aims to provide you with the necessary current knowledge and skills to allow you to make an immediate contribution to relevant industries and research environments. The blend of theory and practical applications in smart networking will enhance your employability.

This course is offered via block delivery. There are two entry points (October and November). This allows you to start when it is most suitable

Visit the website: https://www.beds.ac.uk/howtoapply/courses/postgraduate/next-year/sensors-and-smart-cities-15-months#about

Course detail

The expertise that the University of Bedfordshire has in the related areas of smart cities, and the work it has undertaken as part of a world-leading smart city project called MK:Smart means that you will be at the forefront of developments in this exciting area.

Modules

• Wireless Embedded Systems
• Information Governance and Compliance
• Smart Infrastructure and Data Architecture
• Research Methodologies and Project Management
• MSc Project – Sensors and Smart Cities

Assessment

Most units are assessed with examinations and coursework. Details can be found in the individual module specifications. Assessment is carried out according to context and purpose and recognises that you may exhibit different aptitudes in different forms of assessment:

• Most of the units require collaborative assessments that ask students to form teams and work on a selected project or research topics. However, students will be assessed individually based on their contributions to the overall work.
• Oral presentations are also important assessment method in many units that require student to present the projects developed or researched outlined by the assignment specifications.
• There are formal unseen written examinations for two 30 credit units.
• Individual project that can formed as different ways with conjunctions with their supervisors but has to be suitable to the course scope.

Careers

Employability is understood widely as encompassing knowledge, skills and a professional attitude which your tutors expect you to display in all your units. All University of Bedfordshire courses aim to help you to be prepared for the world of work. The Careers Service is there to support you throughout the three years of your study. On the one hand, our curriculum gives you skills that are valuable for a career within Finance in particular but is also relevant for a much wider range of applications such as information analysis or decision support systems. On the other hand, the department will fully use our industry collaboration connections and resources to serve the course delivery. The collaboration industry partners include car manufactory, MK:SmartCity project and airport data security project and so on. These industry collaborations will well help students developing their real world problem solving skills and extended their employability.

The final year unit `Professional Project Management in particular requires you to work in a team so as to apply a current project management methodology that embraces all of these knowledge areas in an integrated way while going through the stages of planning, execution and project control; you will work as part of a team, take responsibility and make autonomous decisions that impact on the project team performance.

Funding

For information on available funding, please follow the link: https://www.beds.ac.uk/howtoapply/money/scholarships/pg

How to apply

For information on how to apply, please follow the link: https://www.beds.ac.uk/howtoapply/course/applicationform

Visit the MSc Sensors and Smart Cities (12 months) page on the University of Bedfordshire website for more details!

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The Aircraft Design option of the MSc in Aerospace Vehicle Design (AVD) aims to provide a comprehensive overview of aircraft performance, structures and systems. Read more

Course Description

The Aircraft Design option of the MSc in Aerospace Vehicle Design (AVD) aims to provide a comprehensive overview of aircraft performance, structures and systems. A holistic teaching approach is taken to explore how the individual elements of an aircraft can be designed and integrated using up-to-date methods and techniques. You will learn to understand how to select specific systems such as fuel systems, and their effect on the aircraft as a whole.
This course is suitable for students with a background in aeronautical or mechanical engineering or those with relevant industrial experience.

Overview

Modern aircraft design focuses on the integration of new technologies and systems, with current and advanced configurations to lead us towards environmentally friendly and cost effective aviation in the civil arena and high performance and effective aviation in the military arena. This includes new structures, materials and manufacturing processes. New aircraft design is essential to address issues such as carbon footprint reduction, lower noise pollution and improved passenger comfort as well as contributing to national security.

Our work in this field covers all flying vehicles including civil and military aircraft, helicopters, Unmanned Aerial Vehicle Systems (UAVS), ultra-high capacity airlines and space vehicles. Current research being undertaken includes:

Advanced Configurations – such as blended wing and morphing wing aircraft design. This includes both fixed wing and rotorcraft vehicles.

Advanced Systems Integration – such as Distributed Propulsion using hydrogen or alternative fuels for power and high temperature superconducting materials technology.

Advanced Materials and Manufacturing Processes – exploring the benefits achieved through the application of advanced composite materials.

Advanced Design Methodologies – developing techniques to ensure that optimum designs are achieved.

Airworthiness Compliance – ensuring new designs demonstrate the same safety requirements as traditional aircraft.

Operational Aspects – cost, performance, reliability and maintainability are important features of aircraft design as well as advanced techniques such as Integrated Vehicle Health Management (IVHM). Vulnerability and susceptibility also have a major impact.

Biomimetics – taking lessons from nature for example insects and birds, and their application in aviation such as launch, recovery and flight.

English Language Requirements

If you are an international student you will need to provide evidence that you have achieved a satisfactory test result in an English qualification. The minimum standard expected from a number of accepted courses are as follows:

IELTS - 6.5
TOEFL - 92
Pearson PTE Academic - 65
Cambridge English Scale - 180
Cambridge English: Advanced - C
Cambridge English: Proficiency - C

In addition to these minimum scores you are also expected to achieve a balanced score across all elements of the test. We reserve the right to reject any test score if any one element of the test score is too low.

We can only accept tests taken within two years of your registration date (with the exception of Cambridge English tests which have no expiry date).

Structure

The Aircraft Design option consists of a taught component, a group design project and an individual research project.

In addition to management, communication, team work and research skills, each student will attain at least the following outcomes from this degree course:

•To build upon knowledge to enable students to enter a wide range of aerospace and related activities concerned with the design of flying vehicles such as aircraft, missiles, airships and spacecraft
•To ensure that the student is of immediate use to their employer and has sufficient breadth of understanding of multi-discipline design to position them for accelerated career progression
•To provide teaching that integrates the range of disciplines required by modern aircraft design
•To provide the opportunity for students to be immersed in a 'Virtual Industrial Environment' giving them hands-on experience of interacting with and working on an aircraft design project

Modules

The taught programme for the Aircraft Design masters is generally delivered from October to March. As well as completing the 12 compulsory taught modules, students have an extensive choice of optional modules to match their specific interests.

Core:
- Airframe System Design
- Design and Analysis of Composite Structures
- Initial Aircraft Design (including Structural Layout)
- Loading Actions
- Aircraft Stability and Control
- Aircraft Performance
- Design for Manufacture and Operation
- Fatigue Fracture Mechanics and Damage Tolerance
- Aeroelasticity
- Reliability, Safety Assessment and Certification
- Flight Experimental Methods (Jetstream Flight Labs)
- Detail Stressing

Optional:
- Computing Aided Design (CATIA)
- Aircraft Aerodynamics
- Structural Dynamics
- Structural Stability
- Aircraft Accident Investigation
- Aircraft Power Plant Installation
- Avionic System Design
- Aerospace System Development and Life Cycle Model
- Integrated Vehicle Health Management
- Sustaining Design (Structural Durability)
- Finite Element Analysis (including NASTRAN/PATRAN Workshops)
- Crashworthiness

Individual Project

The individual research project aims to provide the training necessary for you to apply knowledge from the taught element to research, and takes place from March to September. The project may be theoretical and/or experimental and drawn from a range of topics related to the course and suggested by teaching staff, your employer or focused on your own area of interest.

Recent Individual Research Projects include:
- Ultra Long Range Science UAV Structure / Systems Development
- Conceptual Design of a Hypersonic Space Launcher and Global Transportation System
- Effect of Aerodynamics on the Conceptual Design of Blended Wing Body Aircraft
- Review, Evaluation and Development of a Microlight Aircraft
- Feasibility of the Application of Low Cost Scaled Aircraft Demonstrators.

Group Project

The extensive group design project is a distinctive and unique feature of this course. This teamwork project takes place from October to March, and recreates a virtual industrial environment bringing together students with various experience levels and different nationalities into one integrated design team.

Each team member is given responsibility for the detailed design of a significant part of the aircraft, for example, forward fuselage, fuel system, or navigation system. The project will progress from the conceptual phase through to the preliminary and detail design phases. You will be required to run project meetings, produce engineering drawings and detailed analyses of your design. Problem solving and project coordination must be undertaken on a team and individual basis. At the end of the project, groups are required to report and present findings to a panel of 200 senior engineers from industry.

This element of the course is both realistic and engaging, and places the student group in a professional role as aerospace design engineers. Students testify that working as an integrated team on real problems is invaluable and prepares them well for careers in a highly competitive industry.

Assessment

The taught modules (10%) are assessed by an examination and/or assignment. The Group Project (50%) is assessed by a written technical report and oral presentations. The Individual Research Project (40%) forms the remainder of the course.

Career opportunities

The MSc in Aircraft Design is valued and respected by employers worldwide. The applied nature of this course ensures that our graduates are ready to be of immediate use to their future employer and has provided sufficient breadth of understanding of multi-discipline design to position them for accelerated career progression.

This course prepares graduates for careers as project design engineers, systems design, structural design or avionic engineers in aerospace or related industries, with the aim of progressing to technical management/chief engineer. Graduates from the MSc in Aircraft Design can therefore look forward to a varied choice of challenging career opportunities in the above disciplines.

Many of our graduates occupy very senior positions in their organisations, making valuable contributions to the international aerospace industry. Typical student destinations include BAE Systems, Airbus, Dassault and Rolls-Royce.

For further information

on this course, please visit our course webpage http://www.cranfield.ac.uk/Courses/Masters/AVD-Option-Aircraft-Design

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