Difference between revisions of "Course syllabus: Mathematics of decision making"
From Research management course
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| − | An executive officer, who makes a decision, shall know whether his choice is adequate. What facts, data and expert estimations could prove the quality of a decision? This course presents methods of data and expert estimation collection, processing and modeling, which are necessary to make an adequate decision. The methods are intended to be used in | + | {{#seo: |
| − | The goal of the course is to learn how to state the problem of decision-making, where to collect necessary data, how to gather expert estimations and how to prove that the decision is optimal. | + | |title=Mathematics of Decision Making |
| − | The course includes 30 hours of lectures, 10 hours of workshops, one case test and the exam. | + | |titlemode=replace |
| + | |keywords=Mathematics of decision making | ||
| + | |description=This course Mathematics of Decision Making presents methods of data and expert estimation collection, processing, and modeling, which are necessary to make an adequate decision. | ||
| + | }} | ||
| + | An executive officer, who makes a decision, shall know whether his choice is adequate. What facts, data, and expert estimations could prove the quality of a decision? This course presents methods of data and expert estimation collection, processing, and modeling, which are necessary to make an adequate decision. The methods are intended to be used in daily routine practice and are supported by algorithms. | ||
| + | The goal of the course is to learn how to state the problem of decision-making, where to collect necessary data, how to gather expert estimations, and how to prove that the decision is optimal. | ||
| + | The course includes 30 hours of lectures, 10 hours of workshops, one case test, and the exam. | ||
| − | # The | + | # The feedback management model |
## Decision problem understanding | ## Decision problem understanding | ||
## Data understanding and collection | ## Data understanding and collection | ||
## Data scales and admissible operations | ## Data scales and admissible operations | ||
# Data preprocessing | # Data preprocessing | ||
| − | ## General | + | ## General Statistics |
## Data normalization and recoding | ## Data normalization and recoding | ||
## Data mining | ## Data mining | ||
| Line 37: | Line 43: | ||
# Decision support systems | # Decision support systems | ||
## Specification of expert estimations | ## Specification of expert estimations | ||
| − | ## What index model we have to choose? | + | ## What index model do we have to choose? |
## How to use expert estimations? | ## How to use expert estimations? | ||
## Quality of the decision | ## Quality of the decision | ||
Latest revision as of 00:04, 14 February 2024
An executive officer, who makes a decision, shall know whether his choice is adequate. What facts, data, and expert estimations could prove the quality of a decision? This course presents methods of data and expert estimation collection, processing, and modeling, which are necessary to make an adequate decision. The methods are intended to be used in daily routine practice and are supported by algorithms. The goal of the course is to learn how to state the problem of decision-making, where to collect necessary data, how to gather expert estimations, and how to prove that the decision is optimal. The course includes 30 hours of lectures, 10 hours of workshops, one case test, and the exam.
- The feedback management model
- Decision problem understanding
- Data understanding and collection
- Data scales and admissible operations
- Data preprocessing
- General Statistics
- Data normalization and recoding
- Data mining
- Model selection
- Collection of expert estimation
- Who is an expert?
- Psychology of expertise
- How to make a questionnaire?
- Delphi method
- Voting systems
- Voting procedures
- Instant-runoff voting
- Condorcet method
- Kemeny-Young method
- Arrow’s paradox of impossibility
- Construction of integral indicators
- Distance to the best
- Linear models
- Principal component analysis
- Pareto optimal front and Pareto slicing
- Non-parametric models
- Pairwise comparison
- Combining data and expert estimations
- Linear-scale concordance
- Ordinal-scale concordance
- Multiple experts estimations
- Statistical learning for indexes
- Decision support systems
- Specification of expert estimations
- What index model do we have to choose?
- How to use expert estimations?
- Quality of the decision
- How to use indexes?
- Error analysis
- Model validation
- Presentation of decision results
Prerequisites: Knowledge of linear algebra and mathematical statistics is required.
Grading:
- Exam 80%
- Case test 20%