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Mathematics and Physics BSc

Please note that information shown below may be subject to change.

UCAS code
Year of entry
View 2019 entry »
Course length
3 years full time
Mathematics »
Physics »

Mathematics has gone hand-in-glove with physics since the time of Newton. Physics is widely conceived as the most fundamental of sciences in that all other branches can be said to derive from its theories and principles, but it couldn’t be studied without a strong working knowledge and appreciation of mathematics. This three-year programme is accredited by the Institute of Physics. It allows you to explore the logical interplay between the two disciplines and split your time equally between the two. As well as covering all the core theories and principles of physics, you will also delve deep into the world of abstract mathematical ideas and explore their wide range of applications in the world around us.

You will be welcomed into a vibrant, friendly learning environment and guided throughout your studies by world-class researchers and teachers who offer generous office hours. While the joint degree is arguably more challenging than a single honours degree, it will equip you with an enviable set of skills to set you apart in the world of work. By combining physics and mathematics you will have the opportunity to approach mathematics from a more rigorous point of view, giving you a deeper understanding of the theoretical aspects of core physics topics such as quantum theory and general relativity. Some of the laboratory components of the standalone physics programme are reduced to make way for this. In year 3 you will have the option of carrying out a supervised research project on a topic of your choice.

Our Department of Mathematics is internationally renowned for its work in pure mathematics, information security, statistics and theoretical physics, while our Department of Physics is one of the most respected centres for physics teaching and research in the UK, boasting cutting-edge laboratories and research facilities and dedicated technical support. There is an astronomical dome on the roof of the department and thanks to our parkland location, away from the big city, our telescopes enjoy the best observational capacities of the University of London campuses.

At the end of your first year you will have the option of transferring onto the second year of our four-year MSci programme, which is aimed at students who want to pursue mathematics and physics at a high level after graduation, for example in research or in specialist roles in industry.

  • Learn from inspirational mathematicians. We rank second in the UK for our research impact and fourth for world leading or internationally excellent research output (Research Excellence Framework 2014).
  • Our physics research is expanding in new and exciting directions, including strategic partnerships with CERN, the National Physical Laboratory (NPL), SNOLAB and industry at large.
  • Both departments put a real emphasis on small group teaching. You will be studying in a close-knit, friendly and supportive environment with a high staff to student ratio.
  • We have a strong track record of high student satisfaction in the annual National Student Survey.
  • Our Department of Physics has been awarded IOP Juno Champion and Athena SWAN silver awards for best practice in promoting women in science and welcoming large cohorts of female students.

Core modules

Year 1

Mathematics: Calculus

In this module, you will develop an understanding of the key concepts in Calculus, including differentiation and integration. You will learn how to factorise polynomials and separate rational functions into partial fractions, differentiate commonly occurring functions, and find definite and indefinite integrals of a variety of functions using substitution or integration by parts. You will also examine how to recognise the standard forms of first-order differential equations, and reduce other equations to these forms and solve them.

Mathematics: Functions of Several Variables

In this module you will develop an understanding of the calculus functions of more than one variable and how it may be used in areas such as geometry and optimisation. You learn how to manipulate partial derivatives, construct and manipulate line integrals, represent curves and surfaces in higher dimensions, calculate areas under a curve and volumes between surfaces, and evaluate double integrals, including the use of change of order of integration and change of coordinates.

Mathematics: Number Systems

In this module you will develop an understanding of the fundamental algebraic structures, including familiar integers and polynomial rings. You will learn how to apply Euclid's algorithm to find the greatest comon divisor of two integers, and use mathematical induction to prove simple results. You will examine the use of arithmetic operations on complex numbers, extract roots of complex numbers, prove De Morgan's laws, and determine whether a given mapping is bijective.

Mathematics: Matrix Algebra

In this module you will develop an understanding of basic linear algebra, in particular the use of matrices and vectors. You will look at the basic theoretical and computational techniques of matrix theory, examining the power of vector methods and how they may be used to describe three-dimensional space. You will consider the notions of field, vector space and subspace, and learn how to calculate the determinant of an n x n matrix.

Physics: Scientific Skills 1

In this module you will develop an understanding of good practices in the laboratory. You will keep a notebook, recording experimental work as you do it. You will set up an experiment from a script, and carry out and record measurements. You will learn how to analyse data and plot graphs using a computer package, and present results and conclusions including error estimations from your experiments.

Physics: Classical Mechanics

In this module you will develop an understanding of how to apply the techques and formulae of mathematical analysis, in particular the use of vectors and calculus, to solve problems in classical mechanics. You will look at statics, dynamics and kinematics as applied to linear and rigidy bodies. You will also examine the various techniques of physical analysis to solve problems, such as force diagrams and conservation principles.

Physics: Classical Matter

In this module you will develop an understanding of the macroscopic properties of the various states of matter, looking at elementary ideas such as ideal gases, internal energy and heat capacity. Using classical models of thermodynamics, you will examine gases, liquids, solids, and the transitions between these states, considering phase equilibrium, the van der Waals equation and the liquefaction of gases. You will also examine other states of matter, including polymers, colloids, liquid crystals and plasmas.

Physics: Physics of the Universe

In this module you will develop an understanding of the building blocks of fundamental physics. You will look at Einstein’s special theory of relativity, considering time-dilation and length contraction, the basics of quantum mechanics, for example wave-particle duality, and the Schrödinger equation. You will also examine concepts in astrophysics such as the Big Bang theory and how the Universe came to be the way we observe it today.

Year 2

Mathematics: Vector Analysis and Fluids

In this module you will develop an understanding of the concepts of scalar and vector fields. You examine how vector calculus is used to define general coordinate systems and in differential geometry. You will learn how to solve simple partial differential equations by separating variables, and become familiar with how these concepts can be appield in the field of dynamics of inviscid fluids.

Mathematics: Ordinary Differential Equations and Fourier Analysis

In this module you will develop an understanding of the concepts arising when the boundary conditions of a differential equation involve two points. You will look at eingenvalues and eingenfunctions in trigonometric differenital equations, and determine the Fourier series for a periodic function. You will learn how to manipulate the Dirac delta-function and apply the Fourier transform. You will also examine how to solve differential equations where the coefficients are variable.

Physics: Scientific Computing Skills

In this module you will develop an understanding of how computers are used in modern science for data analysis and visualisation. You will be introduced to the intuitive programming language, Python, and looking at the basics of numerical calculation. You will examine the usage of arrays and matrices, how to plot and visualise data, how to evaluate simple and complex expressions, how to sample using the Monte Carlo methods, and how to solve linear equations.

Physics: Quantum Mechanics

In this module you will develop an understanding of quantum mechanics and its role in and atomic, nuclear, particle and condensed matter physics. You will look at the wave nature of matter and the probabilistic nature of microscopic phenomena. You will learn how to use the key equation of quantum mechanics to describe fundamental phenomena, such as energy quantisation and quantum tunnelling. You will examine the principles of quantum mechanics, their physical consequences, and applications, considering the nature of harmonic oscillator systems and hydrogen atoms.

Physics: Classical and Statistical Thermodynamics

In this module you will develop an understanding of themal physics and elementary quantum mechanics. You will look at the thermodynamic properties of an ideal gas, examining the solutions of Schrödinger’s equation for particles in a box, and phenomena such as negative temperature, superfluidity and superconductivity. You will also consider the thermodynamic equilibrium process, entropy in thermo-dynamics, and black-body radiation.

Physics: The Solid State

In this module you will develop an understanding of the physical properties of solids. You will look at their structure and symmetry, concepts of dislocation and plastic deformation, and the electrical characteristics of metals, alloys and semiconductors. You will examine methods of probing solids and x-ray diffraction, and the thermal properties of phonons. You will also consider the quantum theory of solids, including energy bands and the Bloch thorem, as well as exploring fermiology, intrinsic and extrinsic semiconductors, and magnetism.

Year 3

Physics: Optics


Physics: Atomic and Nuclear Physics


Physics: Experimental or Theoretical Project


Physics: Electromagnetic Theory


Mathematics: Non-Linear Phenomena and Chaos


Optional modules

In addition to these mandatory course units there are a number of optional course units available during your degree studies. The following is a selection of optional course units that are likely to be available. Please note that although the College will keep changes to a minimum, new units may be offered or existing units may be withdrawn, for example, in response to a change in staff. Applicants will be informed if any significant changes need to be made.

Year 1

Only core modules are taken

Year 2

Mathematics: Statistical Methods

In this module you will develop an understanding of statistical modelling, becoming familiar with the theory and the application of linear models. You will learn how to use the classic simple linear regression model and its generalisations for modelling dependence between variables. You will examine how to apply non-parameric methods, such as the Wilxocon and Kolmogorov-Smirnov goodness-of-fit tests, and learn to use the Minitab statistical software package.

Mathematics: Probability

In this module you will develop an understanding of the basic principles of the mathematical theory of probability. You will use the fundamental laws of probability to solve a range of problems, and prove simple theorems involving discrete and continuous random variables. You will learn how to forumulate an explain fundamental limit theorems, such as the weak law of large numbers and the central limit theorem.

Mathematics: Graphs and Optimisation

In this module you will develop an understanding of the basic concepts of graph theory and linear programming. You will consider how railroad networks, electrical networks, social networks, and the web can be modelled by graphs, and look at basic examples of graph classes such as paths, cycles and trees. You will examine the flows in networks and how these are related to linear programming, solving problems using the simplex algorithm and the strong duality theorem.

Mathematics: Rings and Factorisation

In this module you will develop an understanding of ring theory and how this area of algebra can be used to address the problem of factorising integers into primes. You will look at how these ideas can be extended to develop notions of 'prime factorisation' for other mathematical objects, such as polynomials. You will investigate the structure of explicit rings and learn how to recognise and construct ring homomorphisms and quotients. You will examine the Gaussian integers as an example of a Euclidean ring, Kronecker's theorem on field extensions, and the Chinese Remainder Theorem.

Mathematics: Groups and Group Actions

In this module you will develop an understanding of the algebraic structures known as groups. You will look at how groups represent symmetries in the world around us, examining examples that arise from the theory of matrices and permutations. You will see how groups are ubiquitous and used in many different fields of human study, including mathematics, physics, the study of crystals and atoms, public key cryptography, and music theory. You also will also consider how various counting problems concerning discrete patterns can be solved by means of group actions.

Mathematics: Further Linear Algebra and Modules

In this module you will develop an understanding of the language and concepts of linear algebra that are used within Mathematics. You will look at topics in linear algebra and the theory of modules, which can be seen as generalisations of vector spaces. You will learn how to use alternative matrix representations, such as the Jordan canonical or the rational canonical form, and see why they are important in mathematics.

Mathematics: Real Analysis

In this module you will develop an understanding of the convergence of series. You will look at the Weierstrass definition of a limit and use standard tests to investigate the convergence of commonly occuring series. You will consider the power series of standard functions, and analyse the Intermediate Value and Mean Value Theorems. You will also examine the properties of the Riemann integral.

Year 3

Mathematics: Mathematics Project

In this module you will carry out a detailed investigation on a topic of your choosing, guided by an academic supervisor. You will prepare a written report around 7,000 words in length, and give a ten-minute presentation outlining your findings.

Mathematics: Mathematics in the Classroom

In this module you will develop an understanding of a range of methods for teaching children up to A-level standard. You will act act as a role model for pupils, devising appropriate ways to convey the principles and concepts of mathematics. You will spend one session a week in a local school, taking responsibility for preparing lesson plans, putting together relevant learning aids, and delivering some of the classes. You will work with a specific teacher, who will act as a trainer and mentor, gaining valuable transferable skills.

Mathematics: Number Theory

In this module you will develop an understanding of how prime numbers are the building blocks of the integers 0, ±1, ±2, … You will look at how simple equations using integers can be solved, and examine whether a number like 2017 should be written as a sum of two integer squares. You will also see how Number Theory can be used in other areas such as Cryptography, Computer Science and Field Theory.

Mathematics: Computational Number Theory

In this module you will develop an understanding of a range methods used for testing and proving primality, and for the factorisation of composite integers. You will look at the theory of binary quadratic forms, elliptic curves, and quadratic number fields, considering the principles behind state-of-the art factorisation methods. You will also look at how to analyse the complexity of fundamental number-theoretic algorithms.

Mathematics: Complexity Theory

In this module you will develop an understanding the different classes of computational complexity. You will look at computational hardness, learning how to deduce cryptographic properties of related algorithms and protocols. You will examine the concept of a Turing machine, and consider the millennium problems, including P vs NP, with a $1,000,000 prize on offer from the Clay Mathematics Institute if a correct solution can be found.

Mathematics: Principles of Algorithm Design

In this module you will develop an understanding of efficient algorithm design and its importance for handling large inputs. You will look at how computers have changed the world in the last few decades, and examine the mathematical concepts that have driven these changes. You will consider the theory of algorithm design, including dynamic programming, handling recurrences, worst-case analysis, and basic data structures such as arrays, stacks, balanced search trees, and hashing.

Mathematics: Quantum Theory 1

In this module you will develop an understanding of quantum theory, and the development of the field to explain the behaviour of particles at the atomic level. You will will look at the mathematical foundations of the theory, including the Schrodinger equation. You will examine how the theory is applied to one and three dimensional systems, including the hydrogen atom, and see how a probabilistic theory is required to interpret what is measured.

Mathematics: Quantum Theory 2

In this module you will develop an understanding of how the Rayleigh-Ritz variational principle and perturbation theory can be used to obtain approximate solutions of the Schrödinger equation. You will look at the mathematical basis of the Period Table of Elements, considering spin and the Pauli exclusion principle. You will also examine the quantum theory of the interaction of electromagnetic radiation with matter.

Mathematics: Dynamics of Real Fluids

In this module you will develop an understanding of how the theory of ideal fluids can be used to explain everyday phenomena in the world around us, such as how sound travels, how waves travel over the surface of a lake, and why golden syrup (or volcanic lava) flows differently from water. You will look at the essential features of compressible flow and consider basic vector analysis techniques.

Mathematics: Non-Linear Dynamical Systems - Routes to Chaos

In this module, you will develop an understanding of non-linear dynamical systems. You will investigate whether the behaviour of a non-linear system can be predicted from the corresponding linear system, and see how dynamical systems can be used to analyse mechanisms such as the spread of disease, the stability of the universe, and the evolution of economic systems. You will gain an insight into the 'secrets' of the non-linear world and the appearance of chaos, examining the significant developments achieved in this field during the final quarter of the 20th Century.

Mathematics: Inference

In this module you will develop an understanding of the main priciples and methods of statstics, in particular the theory of parametric estimation and hypotheses testing.You will learn how to formulate statistical problems in mathematical terms, looking at concepts such as Bayes estimators, the Neyman-Pearson framework, likelihood ratio tests, and decision theory.

Mathematics: Time Series Analysis

In this module you will develop an understanding of statistics by looking at the theory and methods used in time series analysis and forecasting. You will look at descriptive methods and theoretical techniques to analyse time series data from fields such as finance, economics, medicine, meteorology, and agriculture. You will learn to use the statistical computing package Minitab as a data analysis, calculation and graphical aid.

Mathematics: Applied Probability

In this module you will develop an understanding of the the probabilistic methods used to model systems with uncertain behaviour. You will look at the structure and concepts of discrete and continuous time Markov chains with countable stable space, and consider the methods of conditional expectation. You will learn how to generate functions, and construct a probability model for a variety of problems.

Mathematics: Channels

In this module you will develop an understanding of the mathematics of communication, focusing on digital communication as used across the internet and by mobile telephones. You looking at compression, considering how small a file, such as a photo or video, can be made, and therefore how the use of data can be minimised. You will examine error correction, seeing how communications may be correctly received even if something goes wrong during the transmission, such as intermittent wifi signal. You will also analyse the noiseless coding theorem, defining and using the concept of channel capacity.

Mathematics: Quantum Information and Coding

In this module you will develop an understanding of how the behaviour of quantum systems can be harnessed to perform information processing tasks that are otherwise difficult, or impossible, to carry out. You will look at basic phenomena such as quantum entanglement and the no-cloning principle, seeing how these can be used to perform, for example, quantum key distribution. You will also examine a number of basic quantum computing algorithms, observing how they outperform their classical counterparts when run on a quantum computer.

Mathematics: Mathematics of Financial Markets

In this module you will develop an understanding of how financial markets operate, with a focus on the ideas of risk and return and how they can be measured. You will look at the random behaviour of the stock market, Markowitz portfolio optimisation theory, the Capital Asset Pricing Model, the Binomial model, and the Black-Scholes formula for the pricing of options.

Mathematics: Advanced Financial Mathematics

In this module you will develop an understanding of the role of mathematics and statistics in securities markets. You will investigate the validity of various linear and non-linear time series occurring in finance, and apply stochastic calculus, including partial differential equations, for interest rate and credit analysis. You will also consider how spot rates and prices for Asian and barrier exotic options are modelled.

Mathematics: Combinatorics

In this module you will develop an understanding of some of the standard techniques and concepts of combinatorics, including methods of counting, generating functions, probabilistic methods, permutations, and Ramsey theory. You will see how algebra and probability can be used to count abstract mathematical objects, and how to calculate sets by includion an exclusion. You will examine the applications of number theory and consider the use of simple probabilistic tools for solving combinatorial problems.

Mathematics: Error Correcting Codes

In this module you will develop an understanding of how error correcting codes are used to store and transmit information in technologies such as DVDs, telecommunication networks and digital television. You will look at the methods of elementary enumeration, linear algebra and finite fields, and consider the main coding theory problem. You will see how error correcting codes can be used to reconstruct the original information even if it has been altered or degraded.

Mathematics: Cipher Systems

In this module you will develop an understanding of secure communication and how cryptography is used to achieve this. You will look at some of the historical cipher systems, considering what security means and the kinds of attacks an adversary might launch. You will examine the structure of stream ciphers and block ciphers, and the concept of public key cryptography, including details of the RSA and ElGamal cryptosystems. You will see how these techniques are used to achieve privacy and authentication, and assess the problems of key management and distribution.

Mathematics: Public Key Cryptography

In this module you will develop an understanding of public key cryptography and the mathematical ideas that underpin it, including discrete logarithms, lattices and elliptic curves. You will look at several important public key cyptosystems, including RSA, Rabin, ElGamal encryption and Schnorr signatures. You will consider notions of security and attack models relevant for modern theoretical cryptography, such as indistinguishability and adaptive chosen ciphertext attack.

Mathematics: Applications of Field Theory

In this module you will develop an understanding of Field Theory. You will learn how to express equations such as X2017=1 in a formal algebraic setting, how to classify finite fields, and how to determine the number of irreducible polynomials over a finitie field. You will also consider some the applications of fields, including ruler and compass constructions and why it is impossible to generically trisect an angle using them.

The programme has a flexible, modular structure and you will take a total of 12 course units at a rate of four, 30-credit modules per year. In addition to our compulsory core modules you will be free to choose between a number of optional courses. Some contribute 15 credits to your overall award while others contribute the full 30.

We use a variety of teaching methods and there is a strong focus on small group teaching in the department. You will attend 12 to 15 hours of formal teaching in a typical week, including lectures, tutorials, problem solving workshops, laboratory work and practical sessions. You will also be expected to work on worksheets, revision and project work outside of these times. In year 2, teaching will mainly be delivered through lectures and workshops and in year 3, mostly through relatively small group lectures.

Our courses are mostly examined by two-hour written examinations at the end of the year but many include a coursework or in-class test element as well. Experimental work is generally assessed by written reports or oral presentation. A minimum of six of the eight course units must be passed each year, with a minimum score of 40%. In year 3 there are optional courses which are examined solely by a project and/or presentation. Outside of class time, you will be expected to work on group projects and independent study, with access to the College’s comprehensive e-learning facility, ‘Moodle’.

Study time

Proportions of study time will vary depending on modules taken, but typically:

Year 1

You will spend 35% of your study time in scheduled learning and teaching activities, and 65% in guided independent study.

Year 2

You will spend 33% of your study time in scheduled learning and teaching activities, and 67% in guided independent study.

Year 3

You will spend 30% of your study time in scheduled learning and teaching activities, and 70% in guided independent study.


Proportions of assessment types will vary depending on modules taken, but typically:

Year 1

Written exams account for 78% of the total assessment for this year of study, 1% will be assessed through practical exams, and 21% will be assessed through coursework.

Year 2

Written exams account for 78% of the total assessment for this year of study, 1% will be assessed through practical exams, and 21% will be assessed through coursework.

Year 3

Written exams account for 79% of the total assessment for this year of study, 2% will be assessed through practical exams, and 19% will be assessed through coursework.

Typical offers

Typical offers

 AAA-AAB including grade A in Maths and grade A in Physics
How we assess your application:  predicted grades lower than our typical offers are considered.  Read more about what we look for here.

  • Where an applicant is taking the EPQ alongside A-levels, the EPQ will be taken into consideration and result in lower grades being required.

  • Socio-economic factors which may have impacted an applicants education will be taken into consideration and alternative offers may be made to these applicants.

Required/preferred subjects

Required subjects: A in Mathematics and A in Physics, plus a Pass in the practical element of all Science A-levels taken

At least five GCSEs at grade A*-C or 9 - 4 including English and Mathematics


Other UK Qualifications
International Baccalaureate  

6,6,5 at Higher Level, including 6 in Maths at Higher Level and 6 in Physics at Higher Level, with a minimum of 32 points overall

BTEC National Extended Diploma

Not normally accepted unless combined with A-level Maths

Distinction, Distinction in a relevant subject plus A-level Maths grade A and A-level Physics grade A

BTEC National Extended Certificate

Distinction plus A-level Maths grade A and A-level Physics grade A

Welsh Baccalaureate  

Requirements are as for A-levels where one non-subject-specified A-level can be replaced by the same grade in the Welsh Baccalaureate - Advanced Skills Challenge Certificate.

Scottish Advanced Highers  

AAA-AAB including A in Maths and A in Physics

Scottish Highers  

AAAAB including A in Maths and A in Physics

Irish Leaving Certificate  

H2,H2,H2,H2,H2 at Higher Level including Maths and Physics

Access to Higher Education Diploma  

Pass in a relevant subject with at lest 30 level 3 credits at Distinction, 15 of which must be in Maths units at Distinction, and the remaining Level 3 credits at Merit, plus A-level Maths grade A.

Please note that the Access to Higher Education Diploma will only be acceptable if the applicant  has had a considerable break from education 

Other UK qualifications

Please select your UK qualification from the drop-down list below

Please select a qualification

Please select a qualification

International and EU entry requirements

Please select your country from the drop-down list below

English language

IELTS 6.5 overall and minimum of 5.5 in each subscore.  For equivalencies please see here

For more information about entry requirements for your country please visit our International pages. For international students who do not meet the direct entry requirements, we offer an International Foundation Year, run by Study Group at the Royal Holloway International Study Centre. Upon successful completion, students can progress on to selected undergraduate degree programmes at Royal Holloway, University of London.

With our internationally recognised Mathematics and Physics degree you will be in demand for your advanced understanding of the theoretical and practical aspects of both disciplines, as well as for your wide range of transferrable skills, such as data handling and analysis, numeracy, logical thinking, technical skills and creative problem solving abilities.

Graduate employment levels for physicists are amongst the highest of any subject. Our Department of Mathematics is also part of the School of Mathematics and Information Security and enjoys particularly strong ties with the information security sector as well as with industry at large. In physics we benefit from strong collaborative ties with international projects and laboratories such as CERN, the National Physical Laboratory (NPL) and SNOLAB.

Recent mathematics and physics graduates have gone on to enjoy successful careers in a wide range of careers, including: business management, IT consultancy, computer analysis and programming, accountancy, the civil service, teaching, actuarial science, finance, risk analysis, research and engineering. We have graduates working for organisations such as: KPMG, Ernst & Young, the Ministry of Defence, Barclays Bank, Lloyds Banking Group, the Department of Health, Logica, McLaren and TowersWatson, and in research teams tackling problems as diverse as aircraft design, operational research and cryptography. 

  • Over 90% of our graduates go into full time employment or further study within six months of graduating (Unistats 2015).
  • According to the Institute of Physics, physics related industry employs more than 1.79 million people in the UK along, and physics graduates typically earn more than those in other disciplines.
  • Both departments offer competitive work experience schemes, with short-term placements and paid summer internships available during the summer holidays.
  • The University of London Careers Advisory Service also offers tailored sessions on finding relevant summer internships or holiday jobs and securing employment after graduation.

Home and EU students tuition fee per year 2018/19*: £9,250

International students tuition fee per year 2018/19**: £18,900

Other essential costs***: £55

How do I pay for it? Find out more about funding options, including loans, grants, scholarships and bursaries.

*The tuition fee for UK and EU undergraduates is controlled by Government regulations, and for students starting a degree in the academic year 2018/19 will be £9,250 for that year. The UK Government has confirmed that EU students starting an undergraduate degree in 2018/19 will pay the same level of fee as a UK student for the duration of their degree.

**Fees for international students may increase year-on-year in line with the rate of inflation. The policy at Royal Holloway is that any increases in fees will not exceed 5% for continuing students. For further information see fees and funding and our terms and conditions.

***These estimated costs relate to studying this particular degree programme at Royal Holloway. Costs, such as accommodation, food, books and other learning materials and printing etc., have not been included.

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