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Decision making Under Risk & Uncertainty.
PAWAN MADUSHANKA
MADUSHAN WIJEMANNA
Probability
The term of “Probability “ refer to the likelihood or change that certain event will occur, with potential values ranging from 0 (the event will not occur) to 1 (the event will definitely occur).
What is risk and uncertainty ?
Risk
We don’t know what is going to happen next, but we do know what the distribution looks like. There is a relevant past experiences with statistical evidence enabling a qualified degree of possible outcome.
Uncertainty
We don’t know what is going to happen next and we don’t know what the possible distribution looks like. There is little previous statistical evidence to enable the possible outcomes to be predicted.
Decision Making models
Identified Objective
Identified alternatives
Identified states of nature
Possible outcomes
Measurement of the value of payoffs
Select the best course of action
Subjective Probability
“A probability derived from an individual's personal judgment about whether a specific outcome is likely to occur. Subjective probabilities contain no formal calculations and only reflect the subject's opinions and past experience.”
http://www.investopedia.com/terms/s/subjective_probability.asp
Objective Probability
“The probability that an event will occur based an analysis in which each measure is based on a recorded observation, rather than a subjective estimate. Objective probabilities are a more accurate way to determine probabilities than observations based on subjective measures, such as personal estimates.”
http://www.investopedia.com/terms/o/objective-probability.asp
Expected Value
1
n
i ii
E( X ) Expected value of X p X
where Xi is the i t h outcome of a decision, pi is the probability of the i t h outcome, and n is the total number of possible outcomes in the probability distribution
The expected value of a distribution does not give the actual value of the random outcome, but rather indicates the “average” value of the outcomes if the risky decision were to be repeated a large number of times
Variance
2 2
1
n
X i ii
Variance(X) = p ( X E( X ))
The variance (a measure of absolute risk) of a probability distribution measures the dispersion of the outcomes about the mean or expected outcome. The variance is calculated as
The higher the variance, the greater the risk associated with a probability distribution.
Standard Deviation
The standard deviation is the square root of the variance:
X Variance( X )
The higher the standard deviation, the greater the risk
Coefficient of Variance
Standard deviation
Expected value E( X )
When the expected values of outcomes differ substantially, managers should measure the riskiness of a decision relative to its expected value using the coefficient of variation (a measure of relative risk)
While no single decision rule guarantees that profits will actually be maximized, there are number of decision rules that managers can use to help them make decisions under risk. Decision rules do not eliminate the risk surrounding a decision, they just provide a method of systematically including risk in the process of decision making. The three rules presented in this presentation are (1) the expected value rule, (2) the mean-variance rules, and (3) the coefficient of variation rule. These three rules are summarized below:
Summary of Decision Rules Under Conditions of Risk
Expected value rule Choose decision with highest expected value
Mean-variance rules
Given two risky decisions A & B:• If A has higher expected outcome & lower variance than B, choose decision A• If A & B have identical variances (or standard deviations), choose decision with higher expected value• If A & B have identical expected values, choose decision with lower variance (standard deviation)
Coefficient of variation rule
Choose decision with smallest coefficient of variation
Expected Utility Theory
Expected utility theory postulates that managers make risky decisions in a way that maximizes the expected utility of the profit outcomes, where the expected utility of a risky decision is the sum of the probability-weighted utilities of each possible profit outcome
1 1 2 2 n nE U( ) p U( ) p U( ) ... p U( )
Payoff Table
The application of probability concept to business decision making, pay off table refer to a matrix that provides pay-offs for all the possible combinations of decision alternatives and events
This can be used to solve problems that involve only one decision variable.
3,000,000
3,000,000
1,500,000
2,000,000
2,500,000
3,000,000
6,000,000 9,000,00
06,000,000
5,500,000
5,000,0008,500,000
12,000,000
0.1
0.4
0.33,000,000
6,000,000 9,000,00
0
6,400,000
6,550,000
5,300,000
3,000,000
0.2
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