- UCAS course code
- H800
- UCAS institution code
- M20
Bachelor of Engineering (BEng)
BEng Chemical Engineering
- Typical A-level offer: AAA including specific subjects
- Typical contextual A-level offer: AAB including specific subjects
- Refugee/care-experienced offer: ABB including specific subjects
- Typical International Baccalaureate offer: 36 points overall with 6,6,6 at HL, including specific requirements
Course unit details:
Chemical Engineering Optimisation
Unit code | CHEN20051 |
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Credit rating | 10 |
Unit level | Level 2 |
Teaching period(s) | Semester 1 |
Available as a free choice unit? | No |
Overview
Chapter 1: Introduction to Chemical Engineering Optimisation
- Scope and hierarchy of engineering optimisation
- Types of mathematical models in chemical engineering
- Types of optimisation (programming) problems
Chapter 2: Construction of Mathematical Models
- Formulation of general optimisation problems
- Process models and constraints
Chapter 3: Fundamentals of Optimisation Theory
- Degrees of freedom
- Unimodality vs. Multimodality
- Review of matrix algebra
Chapter 4: Convexity and Optimality
- Convex functions and regions
- Necessary & sufficient conditions for convexity
- Necessary & sufficient conditions for an optimal solution
Chapter 5: Nonlinear Programming
- Lagrange function for constrained optimisation
- Necessary & sufficient conditions for constrained optimisation problems
Chapter 6: Nonlinear Programming Algorithms
- General algorithms to solve an unconstrained optimisation problem
- General algorithms to solve a constrained optimisation problem
Chapter 7: Linear Programming and Mixed-integer Programming
- Introduction to linear programming
- Graphical solution for two variable problems
- Introduction to mixed-integer programming
Aims
This course introduces the main concepts of engineering optimisation theories (e.g. convexity, optimality) and general optimisation algorithms that are predominantly used in the chemical and biochemical industry. Its main aim is to equip the students with the essential mathematical skills for analysing, optimising, and designing (bio)chemical processes.
The course also provides a range of case studies during the class and coursework sessions to enable students to practise optimisation techniques and apply them to real chemical engineering problems. The students will learn about fundamental optimisation theories, how to formulate optimisation problems (both linear and nonlinear), select appropriate mathematical algorithms, implement curve fitting and data analysis, and calculate a high-quality numerical solution.
The course will also introduce use of advanced artificial intelligence techniques (e.g. machine learning, data-driven optimisation) for (bio)chemical process modelling and optimisation, and illustrate how these novel techniques can further improve process efficiency and sustainability.
Learning outcomes
ILO 1: Demonstrate fundamental knowledge of optimisation theory.
ILO 2: Create and develop mathematical models for engineering optimisation problems.
ILO 3: Choose appropriate optimisation algorithms to calculate a high-quality optimal solution.
ILO 4: Extend knowledge to the concept of complexity and optimality.
ILO 5: Select classic methods to solve unconstrained and constrained optimisation problems.
ILO 6: Describe the general procedure to solve linear programming, nonlinear programming, and mixed-integer programming problems.
ILO 7: Understand applications of modern artificial intelligence and machine learning techniques for chemical process modelling and optimisation.
Teaching and learning methods
Lectures provide fundamental aspects supporting the critical learning of the module and will be delivered as pre-recorded asynchronous short videos via our virtual learning environment.
Synchronous sessions will support the lecture material with Q&A and problem-solving sessions where you can apply the new concepts. Surgery hours are also available for drop-in support.
Students are expected to expand the concepts presented in the session and online by additional reading (suggested in the Online Reading List) in order to consolidate their learning process and further stimulate their interest to the module.
Study budget:
- Core Learning Material (e.g. recorded lectures, problem solving sessions): 24 hours
- Self-Guided Work (e.g. continuous assessment, extra problems, reading): 44 hours
- Exam Style Assessment Revision and Preparation: 32 hours
Assessment methods
Assessment Types | Total Weighting |
Continuous assessment | 30% |
Exam style assessments | 70% |
Please note that the exam style assessments weighting may be split over midterm and end of semester exams.
Feedback methods
Feedback on problems and examples, feedback on coursework and exams, and model answers will be provided through the virtual learning environment. A discussion board provides an opportunity to discuss topics related to the material presented in the module.
Recommended reading
Reading lists are accessible through the Blackboard system linked to the library catalogue.
Study hours
Scheduled activity hours | |
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Lectures | 24 |
Independent study hours | |
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Independent study | 76 |
Teaching staff
Staff member | Role |
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Konstantinos Theodoropoulos | Unit coordinator |