| Module Code: |
H9AIDM |
|
Long Title
|
AI Driven Decision Making
|
|
Title
|
AI Driven Decision Making
|
| Module Level: |
LEVEL 9 |
| EQF Level: |
7 |
| EHEA Level: |
Second Cycle |
| Module Coordinator: |
Ade Fajemisin |
| Module Author: |
Margarete Silva |
| Departments: |
School of Computing
|
| Specifications of the qualifications and experience required of staff |
MSc and/or PhD degree in computer science, mathematics or cognate discipline. May have industry experience also.
|
| Learning Outcomes |
| On successful completion of this module the learner will be able to: |
| # |
Learning Outcome Description |
| LO1 |
Critically assess theories and models of decision making to contextualise artificial intelligence driven approaches for decision making. |
| LO2 |
Model and solve a variety of real-world problems as constraint satisfaction and optimisation problems. |
| LO3 |
Identify and apply appropriate artificial intelligence driven decision-making approaches (e.g., Bayesian Networks, Fuzzy Systems, Evolutionary Systems) to solve problems across various application domains. |
| LO4 |
Implement, compare, contrast, and critically evaluate alternative artificial intelligence algorithmic approaches to determine their suitability for decision making with sample optimisation problems. |
| Dependencies |
Module Recommendations
This is prior learning (or a practical skill) that is required before enrolment on this module. While the prior learning is expressed as named NCI module(s) it also allows for learning (in another module or modules) which is equivalent to the learning specified in the named module(s).
|
| No recommendations listed |
Co-requisite Modules
|
| No Co-requisite modules listed |
| Entry requirements |
Learners are required to hold a minimum of a level 8 honours qualification, or equivalent on the National Qualifications Framework, and must be from a cognate background.
|
Module Content & Assessment
| Indicative Content |
|
Module Introduction
Theory & Models of Decision Making (e.g., Simon / Boyd)
Structured, semi-structured, unstructured decision making
Decision Support Systems
Intelligent Decision Support Systems
AI/Human Decision Making context (Support, Augment, Replace, Automate)
Explainable AI
Expert Systems, Case-based & Rule-based systems / Historical Perspective
AI approaches to decision making covered in the module
Ethical questions and implications
|
|
Introduction to Optimization
Components of an optimisation problem
Maximization and Minimization problems
Graph optimization
Application to real-world problems such as cutting stock problems, vehicle routing problems, scheduling problems, etc.
|
|
Linear and Integer Programming
Basic properties of Linear Programming problems
Linear Programming formulation
Mixed Integer Programming
Algorithms for solving optimisation problems: Branch-and-Bound, Branch-and-Price
|
|
Constraint Programming
Modelling problems using constraint programming
Constraint propagation using arc-consistency, node-consistency and path consistency
Backtracking search algorithms
Local search methods
Applications of constraint programming
|
|
Bayesian Networks
Random variables
Bayes's Theorem and Conditional Probability
Bayesian Networks
Real-world applications of Bayesian Networks, e.g. image processing, information retrieval, troubleshooting, etc.
|
|
Fuzzy Systems
Fuzzy Sets
Fuzzy Logic
Membership Functions
Fuzzy Reasoning
Fuzzy Decision Making
|
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Evolutionary Systems
Genetic Algorithms
Operators in Genetic Algorithms
Stopping Conditions and Constraints
Classification of GAs
|
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Evolutionary Systems
Swarm Intelligence
Memetic Algorithms
|
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Metaheuristics
Fitness landscapes
Local search
Simulated annealing
|
|
Metaheuristics
Tabu Search
Variable neighbourhood search
|
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Hybrid Systems
Combining metaheuristics with mathematical programming, constraint programming, machine learning and data mining
|
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Applications
Survey and analysis of AI decision making across a number of application domains.
|
| Assessment Breakdown | % |
|---|
| Coursework | 100.00% |
AssessmentsFull Time
| Coursework |
| Assessment Type: |
Formative Assessment |
% of total: |
Non-Marked |
| Assessment Date: |
n/a |
Outcome addressed: |
1,2,3,4 |
| Non-Marked: |
Yes |
Assessment Description:
Formative assessment will be provided on the in-class individual or group activities. Feedback will be provided in written or oral format, or on-line through Moodle. In addition, in class discussions will be undertaken as part of the practical approach to learning. |
|
| Assessment Type: |
Continuous Assessment |
% of total: |
40 |
| Assessment Date: |
n/a |
Outcome addressed: |
2 |
| Non-Marked: |
No |
Assessment Description:
The learner will be required to model and solve a series of problems using integer programming |
|
| Assessment Type: |
Project |
% of total: |
60 |
| Assessment Date: |
n/a |
Outcome addressed: |
1,2,3,4 |
| Non-Marked: |
No |
Assessment Description:
Long-form project which the student produces over the course of the entire semester. Student is required to research and utilise a suite of AI based algorithms and approaches to provide decision making capabilities in a chosen application problem domain. The results of applying these techniques should then be critically evaluated. It is required to submit a project report including: (a) the background research that has been conducted, (b) the methodology applied to complete the project, (c) implementation details, (d) experimentation details, (e) evaluation of results, and (f) conclusion. |
|
| No End of Module Assessment |
| Reassessment Requirement |
Coursework Only
This module is reassessed solely on the basis of re-submitted coursework. There is no repeat written examination.
|
NCIRL reserves the right to alter the nature and timings of assessment
Module Workload
| Module Target Workload Hours 0 Hours |
| Workload: Full Time |
| Workload Type |
Workload Description |
Hours |
Frequency |
Average Weekly Learner Workload |
| Lecture |
In-class lectures |
24 |
Per Semester |
2.00 |
| Lab |
Application of concepts presented in lectures |
24 |
Per Semester |
2.00 |
| Independent Learning |
Independent learning |
77 |
Per Semester |
6.42 |
| Total Weekly Contact Hours |
4.00 |
Module Resources
| Recommended Book Resources |
|---|
-
Frederick S. Hillier,Gerald J. Lieberman. Introduction to Operations Research, [ISBN: 9781259253188].
-
William Kocay,Donald L. Kreher. (2016), Graphs, Algorithms, and Optimization, Second Edition, CRC Press, p.546, [ISBN: 9781482251166].
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Francesca Rossi,Peter Van Beek,Toby Walsh. (2006), Handbook of Constraint Programming, Elsevier Science Limited, p.955, [ISBN: 9780444527264].
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Norman Fenton,Martin Neil. (2012), Risk Assessment and Decision Analysis with Bayesian Networks, CRC Press, p.524, [ISBN: 9781439809112].
| | Supplementary Book Resources |
|---|
-
El-Ghazali Talbi. (2009), Metaheuristics: From Design to Implementation.
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Kartik Hosanagar. (2019), A Human's Guide to Machine Intelligence, Penguin, p.272, [ISBN: 9780525560890].
| | Supplementary Article/Paper Resources |
|---|
-
Çağrı Koça,Tolga Bektaşa,Ola
Jabalib,Gilbert Laporte. (2016), Thirty years of heterogeneous vehicle
routing, European Journal of Operational Research, 249,
-
Pablo Martínez Fernándeza, Ignacio
Villalba Sanchísa, Víctor Yepesb,Ricardo
Insa Franco. Assessment and optimization of
sustainable forest wood supply chains –
A systematic literature review, Journal of Cleaner Production, 222,
-
Billie Anderson. (2019), Using Bayesian networks to perform
reject inference, Expert Systems with Applications, 137,
| | This module does not have any other resources |
|---|
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