Handling Uncertainty in Artificial Intelligence

Table of Contents

Chapter 1: Introduction to handling uncertainty in artificial intelligence

1.1. Introduction

1.2. Common challenges of handling uncertainty in artificial intelligence

1.3. Numeric approaches

1.3.1.       Probability and Bayesian theory

1.3.2.       The Dempster-Shafer Theory

1.3.3.       Certainty factor and evidential reasoning

1.3.4.       Fuzzy logic-based approach

1.4. Symbolic approaches

1.4.1.       Nonmonotonic approach

1.4.2.       Cohen's theory of endorsements

1.5. Summary

Chapter 2: Probability and Bayesian Theory to Handle Uncertainty in artificial intelligence

2.1. Introduction

2.2. Popular phrases related to probability

2.2.1. Event

2.2.2. Sample space

2.3. Ways to solve uncertainty using probability

2.3.1. Bayes' theorem

2.3.2. Bayesian Belief Network

2.4. Advantages of probability-based methods

2.5. Limitations of probability-based methods

2.6. Summary

Chapter 3: The Dempster-Shafer Theory to handle uncertainty in artificial intelligence

3.1. Introduction

3.2. Basic terms used in D-S theory

3.2.1. Frame of discernment

3.2.2. Power Set

3.2.3. Evidence

3.2.4. Data source

3.2.5. Data fusion

3.3. Main Components of D-S Theory

3.3.1. Basic Probability Assignment (BPA) or Mass Function (M-value)

3.3.2. Belief function (Bel)

3.3.3. Plausibility Function (Pl)

3.3.4. Commonality function C (Q)

3.3.5. Uncertainty Interval (U)

3.4. D-S Rule of Combination

3.5. Advantages of D-S theory

3.6. Limitations of D-S theory

3.7. Summary

Chapter 4: Certainty factor and evidential reasoning to handle uncertainty in artificial intelligence

4.1. Introduction

4.2. Case study 1

4.3. Case study 2

4.4. Case study 3

4.5. Advantages of CF

4.6. Limitations of CF

4.7. Summary

Chapter 5: A fuzzy logic-based approach to handle uncertainty in artificial intelligence

5.1. Introduction

5.2. Characteristics of fuzzy logic

5.3. Fuzzy Logic vs Probability

5.4. Membership functions

5.4.1. Singleton membership function

5.4.2. Triangular membership function

5.4.3. Trapezoidal membership function

5.4.4. Gaussian membership function

5.4.5. Generalized bell-shaped membership function

5.4.6. Sigmoid membership function

5.5. Architecture of the fuzzy logic-based system

5.5.1. Rule base

5.5.2. Fuzzification

5.5.3. Inference engine

5.5.4. Defuzzification

5.6. Case study

5.7. Advantages of Fuzzy Logic System

5.9. Summary

Chapter 6: Decision-making under uncertainty in artificial intelligence

6.1. Introduction

6.2. Types of Decisions

6.2.1. Strategic Decision

6.2.2. Administrative Decision

6.2.3. Operating Decision

6.3. Steps in decision making

6.4. Criterion for deciding under uncertainty

6.4.1. Maximax

6.4.2. Maximin

6.4.3. Minimax regret

6.4.4. Hurwicz criteria

6.4.5. Laplace criteria

6.5. Utility theory

6.5.1. Utility functions

6.5.1. Expected utility

6.6. Decision network

6.6.1. Solving the Weakness Decision Network - Enumerating all Policies

6.6.2. Solving the Weakness Decision Network - Variable Elimination Algorithm

6.7. Applying the Variable Elimination Algorithm to a Therapeutic Diagnostic Scenario

6.8. Advantages of expected utility under an uncertain situation

6.9. Limitations of expected utility under an uncertain situation

6.10. Summary

Chapter 7: Applications of different methods to handle uncertainty in artificial intelligence

7.1. Applications of Probability and Bayesian Theory in the field of uncertainty

7.2. Applications of Dempster-Shafer (DS) theory in the field of uncertainty

7.3. Applications of certainty factor (CF) in the field of uncertainty

7.4. Applications of Fuzzy logic in the field of uncertainty

7.5. Applications of utility and expected utility theory

7.6. Summary