What is the BSc (Hons) Computer Science (including Foundation Year)?
The BSc (Hons) Computer Science (including Foundation Year) is a four-year degree.
You’ll build a strong foundation in core computer science theory and explore its cutting-edge real-world applications, preparing you to create the technologies of tomorrow.
If you don’t yet meet the entry requirements for the three-year version, starting the course with a Foundation Year gives you a supported step up to university study.
Why this course
The BSc (Hons) Computer Science (including Foundation Year) gives you the theory and practical knowledge to understand – and create – computing technologies that make a real impact on the world.
From Year One of BSc (Hons) Computer Science, you’ll study a broad curriculum shaped by industry partners, gaining the most up-to-date understanding of computer science. Discover which areas you’re interested in exploring further, then specialise in assistive technologies, computer games, artificial intelligence, evolutionary computation, Big Data or robotics.
By graduation, you’ll have the confidence and ability to dig deeper into how technology influences people’s lives. You’ll be ready for careers in software and systems analysis, engineering and programming.
Who should apply
Future software analysts and programmers
Students eager to develop their own computer games, apps, online platforms and digital systems
Those considering a career that benefits from a broad understanding of how computers and digital systems work
Computational thinkers with great grasp of pattern recognition and algorithms
What you’ll learn
Programming: Learn to programme with multiple programming languages
Data: Explore ways to work with data from data structures to Big Data
Web: Secure the principles and technology behind web apps and websites
Digital systems: Grasp the software and hardware underpinning digital computer systems
Your learning experience
Optional modules: Tailor your degree to specialise in areas such as AI, computer games and security
Expert teaching: Learn from leading researchers revolutionising industries such as agriculture and healthcare
Specialist facilities: Access 24/7 computing labs with a range of programming software and specialist facilities for brain-computer interfaces, intelligent environments and more
Careers and outcomes
A BSc (Hons) Computer Science degree prepares you for diverse careers in:
IT: Computer and information research, computer network architecture, database systems administration, security analysis
Healthcare: Health information and technology, clinical data and systems administration
Business and finance: Financial analysis, data analysis, risk management, web development
Energy: Energy generation and distribution systems, data analysis, technological improvement
Computer games: Development, programming
Why we're great.
Top 250 (Top 25 in the UK) for computer science in THE World University Rankings by Subject 2026
9th in the UK for research impact in computer science (REF 2021)
91% of our computing undergraduates are in employment or further study (Graduate Outcomes 2025)
"My time at Essex definitely prepared me for the workplace, largely due to the structure of the course. The mix of theoretical learning and practical assignments helped me develop problem-solving skills, adaptability, and a strong understanding of industry practices. During my studies, I completed a placement at JP Morgan and later did an internship at American Express. Both experiences gave me valuable industry exposure, allowing me to apply what I had learned in real-world settings and build professional connections."
All applications for degree courses with a foundation year (Year Zero) will be considered individually, whether you
think you might not have the grades to enter the first year of a degree course;
have non-traditional qualifications or experience (e.g. you haven’t studied A-levels or a BTEC);
are returning to university after some time away from education; or
are looking for more support during the transition into university study.
Standard offer:
Our standard offer is 72 UCAS tariff points from at least two full A-levels, or equivalent.
Examples of the above tariff may include:
A-levels: DDD
BTEC Level 3 Extended Diploma: MMP
T-levels: Pass with E in core
For this course all applicants must also hold GCSE Maths at grade C/4 or above (or equivalent). We may be able to consider a pass in OFQUAL regulated Level 2 Functional Skills Maths where you cannot meet the requirements for Maths at GCSE level. However, you are advised to try to retake GCSE Mathematics if possible as this will better prepare you for university study and future employment.
If you are unsure whether you meet the entry criteria, please get in touch for advice.
Mature applicants and non-traditional academic backgrounds:
We welcome applications from mature students (over 21) and students with non-traditional academic backgrounds (might not have gone on from school to take level 3 qualifications). We will consider your educational and employment history, along with your personal statement and reference, to gain a rounded view of your suitability for the course.
You will still need to meet our GCSE requirements.
International applicants:
Essex Pathways Department is unable to accept applications from international students. Foundation pathways for international students are available at the University of Essex International College and are delivered and awarded by Kaplan, in partnership with the University of Essex. Successful completion will enable you to progress to the relevant degree course at the University of Essex.
International & EU entry requirements
We accept a wide range of qualifications from applicants studying in the EU and other countries. Get in touch with any questions you may have about the qualifications we accept. Remember to tell us about the qualifications you have already completed or are currently taking.
Sorry, the entry requirements for the country that you have selected are not available here. Please contact our Undergraduate Admissions team at ugquery@essex.ac.uk to request the entry requirements for this country.
English language requirements
English language requirements for applicants whose first language is not English: IELTS 5.5 overall with a minimum of 5.5 in each component, or specified score in another equivalent test that we accept.
Details of English language requirements, including component scores, and the tests we accept for applicants who require a Student visa (excluding Nationals of Majority English Speaking Countries) can be found here
If we accept the English component of an international qualification it will be included in the academic levels listed above for the relevant countries.
English language shelf-life
Most English language qualifications have a validity period of 5 years. The validity period of Pearson Test of English, TOEFL and CBSE or CISCE English is 2 years.
If you require a Student visa to study in the UK please see our immigration webpages for the latest Home Office guidance on English language qualifications.
Pre-sessional English courses
If you do not meet our IELTS requirements then you may be able to complete a pre-sessional English pathway that enables you to start your course without retaking IELTS.
Pending English language qualifications
You don’t need to achieve the required level before making your application, but it will be one of the conditions of your offer.
If you cannot find the qualification that you have achieved or are pending, then please email ugquery@essex.ac.uk.
Additional Notes
If you’re an international student, but do not meet the English language or academic requirements for direct admission to this degree, you could prepare and gain entry through a pathway course. Find out more about opportunities available to you at the University of Essex International College
Structure
Course structure
Our research-led teaching is continually evolving to address the latest challenges and breakthroughs in the field. The following modules are based on the current course structure and may change in response to new curriculum developments and innovation.
We understand that deciding where and what to study is a very important decision for you. We'll make all reasonable efforts to provide you with the courses, services and facilities as described on our website and in line with your contract with us. However, if we need to make material changes, for example due to significant disruption, we'll let our applicants and students know as soon as possible.
Components and modules explained
Components
Components are the blocks of study that make up your course. A component may have a set module which you must study, or a number of modules from which you can choose.
Each component has a status and carries a certain number of credits towards your qualification.
Status
What this means
Core
You must take the set module for this component and you must pass. No failure can be permitted.
Core with Options
You can choose which module to study from the available options for this component but you must pass. No failure can be permitted.
Compulsory
You must take the set module for this component. There may be limited opportunities to continue on the course/be eligible for the qualification if you fail.
Compulsory with Options
You can choose which module to study from the available options for this component. There may be limited opportunities to continue on the course/be eligible for the qualification if you fail.
Optional
You can choose which module to study from the available options for this component. There may be limited opportunities to continue on the course/be eligible for the qualification if you fail.
The modules that are available for you to choose for each component will depend on several factors, including which modules you have chosen for other components, which modules you have completed in previous years of your course, and which term the module is taught in.
Modules
Modules are the individual units of study for your course. Each module has its own set of learning outcomes and assessment criteria and also carries a certain number of credits.
In most cases you will study one module per component, but in some cases you may need to study more than one module. For example, a 30-credit component may comprise of either one 30-credit module, or two 15-credit modules, depending on the options available.
Modules may be taught at different times of the year and by a different department or school to the one your course is primarily based in. You can find this information from the module code. For example, the module code HR100-4-FY means:
HR
100
4
FY
The department or school the module will be taught by.
In this example, the module would be taught by the Department of History.
How do you test and evaluate the operation of simple computer programs? Or develop a program using tools in the Python programming language? Study the principles of procedural computing programming. Examine basic programming concepts, structures and methodologies. Understand good program design, learn to correct coding and practice debugging techniques.
Reading, Writing, Research, and Presentation Skills
(30 CREDITS)
This blended-learning module is designed to support students in their academic subject disciplines and to strengthen their confidence in key skills areas such as: academic writing, research, academic integrity, collaborative and reflective practices.
The students are supported through the use of subject-specific materials tailored to their chosen degrees with alignment of assessments between academic subject modules and the skills module.
Develop your problem-solving skills in this module, as you are introduced to Statistical and Mathematical concepts including mechanics. You become familiar with R software, one of the most widely used statistical analysis software in the world, and learn how to use it to analyse and interpret data. You study simple concepts and techniques like data description and distribution; before moving on to more complex topics and theories including Newton's laws of motion. While also covering everything from probability rules and hypothesis testing to advanced algebra - you will be well equipped to present your solutions and findings to an audience with no specialist knowledge of Statistics and Mechanics.
Our Team Project Challenge gives you the opportunity to develop a range of professional skills by working as part of a small student team on a specific project. The projects are research-based and incorporate the concepts of specifications, design, and implementation. You’ll learn about sustainability, project and time management, design, legal issues, health and safety, data analysis and presentation, team reporting, and self-evaluation.
You’ll also develop skills such as critical thinking and problem solving, agility, leadership, collaboration across networks, and effective oral and written communication, as well as curiosity and imagination, all of which will enhance your knowledge, confidence and social skills necessary to innovate and succeed in a competitive global environment.
The aim of this module is to cover fundamental mathematics for Computer Scientists. It does not assume A-level mathematics, and the emphasis and delivery will be on understanding the key concepts as they apply to Computer Science.
The aim of this module is to provide an introduction to the fundamental concepts of computer programming. After completing this module, students will be expected to be able to demonstrate an understanding of the basic principles and concepts that underlie the procedural programming model, explain and make use of high-level programming language features that support control, data and procedural abstraction. Also, they will be able to analyse and explain the behaviour of simple programs that incorporate standard control structures, parameterised functions, arrays, structures and I/O.
Want to become a Java programmer? Topics covered in this module include control structures, classes, objects, inheritance, polymorphism, interfaces, file I/O, event handling, graphical components, and more. You will develop your programming skills in supervised lab sessions where help will be at hand should you require it.
Databases are everywhere. They are employed in banking, production control and the stock market, as well as in scientific and engineering applications. For example, the Human Genome Project had the goal of mapping the sequence of chemical base pairs which make up human DNA. The result is a genome database. This module introduces the underlying principles of databases, database design and database systems. It covers the fundamental concepts of databases, and prepares the student for their use in commerce, science and engineering.
The aim of this module is to provide students with an introduction to the principles and technology that underlie internet applications and the techniques used in the design and construction of web sites. Students showcase their skills by designing and building both client and server components of a data driven web site.
Data structures and algorithms are two of the foundations of computer science, distinguishing it from just programming. In this module, you will learn what algorithms are and how they can be implemented even in very simple computers. You will cover fundamental algorithms for sorting and searching, along with data structures for lists and trees, and will be introduced to the analysis of algorithm efficiency.
Computers, embedded systems, and digital systems in general have become an essential part of most people's lives, whether directly or indirectly. The aim of this module is to introduce the software and hardware underpinnings of such systems at an introductory yet challenging level suitable for future computer scientists and engineers. Topics covered in the module include both top-view as well as bottom-view approaches to understanding digital computers. They range from the more theoretical (e.g., state machines, logic circuits, and von Neumann's architecture) to the more practical (e.g., how transistors produce binary signals, operating system functions, memory management, and common hardware devices). The module also includes problem solving classes in which a guided discussion of weekly exercises is aimed at giving the student an opportunity to consolidate his/her understanding of the topics involved. Upon completion of this module, students should have a good conceptual and practical understanding of the nature and architecture of digital computer systems and their components.
This course covers the principles of project management, team working, communication, legal issues, finance, and company organisation. Working in small teams, students will go through the full project life-cycle of design, development and implementation, for a bespoke software requirement. In this course, students gain vital experience to enable them to enter the computer science/Electrical engineering workforce, with a degree backed by the British Computer Society, and by the Institute of Engineering and Technology.
This module aims to equip students with the main principles guiding the activities involved in software development throughout its lifecycle, including software requirements, object-oriented analysis and design, software validation and testing, and software maintenance and software evolution.
This module extends the students' knowledge and skills in object-oriented application programming by a treatment of further Java language principles and of important Application Programming Interfaces (APIs). The Java Collections API is explored in some more detail with emphasis on how to utilise these classes to best effect. A particular focus will be on the interaction with databases (e.g. via JDBC) and on writing secure applications.
Data structures and algorithms lie at the heart of Computer Science as they are the basis for the efficient solution of programming tasks. In this module, students will study core algorithms and data structures, as well as being given an introduction to algorithm analysis and basic computability.
The highlight of our undergraduate degree courses is the individual capstone project. This project module provides students with the opportunity to bring together all the skills they have gained during their degree and demonstrate that they can develop a product from the starting point of a single 1/2 page description, provided either by an academic member of staff or an external company. In all the student spends 450 hours throughout the academic year, reporting to their academic tutor, and in the case of company projects, to a company mentor. All projects are demonstrated to external companies on our Project Open Day.
Courses are taught by a combination of lectures, laboratory work, assignments, and individual and group project activities.
Undergraduate students in the School of Computer Science and Electronic Engineering typically attend a two-hour lecture and a two-hour lab for each 15-credit module.
A significant amount of practical lab work will need to be undertaken for written assignments and as part of your learning.
Assessment
In your first year, you will have exams before the start of term in January.
Your assessed coursework will generally consist of essays, reports, in-class tests, individual or group oral presentations, and small scale research projects.
All credit-bearing modules will involve a final exam, which will be either essay-based or in the form of a test.
Our events are a great way to find out more about studying at Essex. We run a number of Open Days throughout the year which enable you to discover what our campus has to offer.
You have the chance to:
tour our campus and accommodation
find out answers to your questions about our courses, student finance, graduate employability, student support and more
meet our students and staff
Check out our Visit Us pages to find out more information about booking onto one of our events. And if the dates aren’t suitable for you, feel free to book a campus tour here.
Our UK students, and some of our EU and international students, who are still at school or college, can apply through their school. Your school will be able to check and then submit your completed application to UCAS. Our other international applicants (EU or worldwide) or independent applicants in the UK can also apply online through UCAS Apply. Please note that this course is not open to international applicants.
The UCAS code for our University of Essex is ESSEX E70. The individual campus code for our Loughton Campus is 'L'.
You can find further information on how to apply, including information on transferring from another university, applying if you are not currently at a school or college, and applying for readmission on our How to apply and entry requirements page.
If you receive an undergraduate offer to study with us in October 2026 and live in the UK, you will receive an email invitation to book onto one of our Open Days. These events provide the opportunity to meet your department, join interesting taster sessions, tour our campus and accommodation, and chat to current students. You can visit our Open Days event page for more information, including terms and conditions.
Please note that this course is not open to international applicants.
Visit Colchester Campus
Set within 200 acres of award-winning parkland - Wivenhoe Park and located two miles from the historic city centre of Colchester – England's oldest recorded development. Our Colchester Campus is also easily reached from London and Stansted Airport in under one hour.
If you live too far away to come to Essex (or have a busy lifestyle), no problem. Our 360-degree virtual tour allows you to explore our University from the comfort of your home. Check out our Colchester virtual tour to see accommodation options, facilities and social spaces.
Chat to us
Got a question about this course? Chat with Dr Ian Daly from the School of Computer Science and Electronic Engineering.
Meet the lecturers, discover our alumni’s achievements, and learn about undergraduate study life in the School of Computer Science and Electronic Engineering.
At Essex we pride ourselves on being a welcoming and inclusive student community. We offer a wide range of support to individuals and groups of student members who may have specific requirements, interests or responsibilities.
The University makes every effort to ensure that this information on its programme specification is accurate and up-to-date. Exceptionally it can be necessary to make changes, for example to courses, facilities or fees. Examples of such reasons might include, but are not limited to: strikes, other industrial action, staff illness, severe weather, fire, civil commotion, riot, invasion, terrorist attack or threat of terrorist attack (whether declared or not), natural disaster, restrictions imposed by government or public authorities, epidemic or pandemic disease, failure of public utilities or transport systems or the withdrawal/reduction of funding. Changes to courses may for example consist of variations to the content and method of delivery of programmes, courses and other services, to discontinue programmes, courses and other services and to merge or combine programmes or courses. The University will endeavour to keep such changes to a minimum, and will also keep students informed appropriately by updating our programme specifications. The University would inform and engage with you if your course was to be discontinued, and would provide you with options, where appropriate, in line with our Compensation and Refund Policy.
The full Procedures, Rules and Regulations of the University governing how it operates are set out in the Charter, Statutes and
Ordinances and in the University Regulations, Policy and Procedures.
