Monte Carlo Simulation
A technique that helps modelers examine the consequences of continuous riskMost risks in real world generate hundreds
of possible outcomes
Provides fuller picture of the risk in an asset or investment by consideringDifferent input assumptions & scenariosLikelihood of inputs & scenarios occurring
5 Steps of Monte Carlo Simulation
Build a spreadsheet model that has dynamic relationships between input assumptions and key outputs
Perform sensitivity analysis to identify the key uncertain inputs that have the most potential impact on the key outputs
Quantify possible values for the key uncertain inputs by specifying probability distributions
Simulate numerous scenarios from the input probability distributions and record output results
Summarize recorded output results to measure risks and likelihood of different outcomes
Random Number Generator (RNG)
=Rand() function in Excel Randomly generates a number between 0 and 1 Used to represent a cumulative probability P(X) between 0%
and 100% Will be used to identify the input value X such that the
probability that value X or a lower value occurs is equal to P(X)
For example, Rand()=.5
Used to find input assumption value X where 50% of the input assumption values are smaller and 50% of possible input assumption values are larger than X.
Rand()=.9 Used to find input assumption value X where 90% of the input
assumption values are smaller than X.
Prob
Normal (u, σ)P(X≤u)=.5
P(u- σ ≤x ≤u+ σ)=.65
σ
u- σ u u+ σ x
Normal Input Distributions
=Norminv(rand(), mean, standard deviation)
For a specified mean and standard deviation, this formula looks up the value for the input distribution that results in rand()% of the assumption values being smaller than the returned value.
The Normal distribution is a continuous distribution
Continuous –vs- Discrete Distributions
In discrete distributions, the values generated for a random variable must be from a finite distinct set of individual values.
In continuous distributions, the values generated for a random variable are specified from a set of uninterrupted values over a range; an infinite number of values is possible
Uniform (a, b)
a u=a+(b-a) b X 2
Prob
P(X ≤ u)=. 5
Uniform Distribution
=a + (b-a)*rand()Where a is the smallest value that could
occur, b is the largest valueValues between a and b are assumed to
be equally likely to occurValues are assumed to be continuous
and not discrete
Triangular Distribution
For symmetrical triangles:=a + (b-a)*(rand()+rand())/2
Where a is the smallest value that could occur, b is the largest value
m is the most likely value to occur and is assumed to be halfway between a and b for symmetrical triangles
Values are assumed to be continuous and not discrete in both symmetrical and nonsymmetrical triangular distributions
Discrete Distribution
P(x)X P(x)10 .211 .312 .413 .1
10 11 12 13 x
.2
1.0/0
.9
.5
1110
13
12
Cumulative Probability Distribution
X P(x)10 .211 .312 .413 .1
P(X≤x).2.5.91.0
Discrete Distributions
Set up a table where the first two columns contain the cumulative probability range for a value and the third column contains the respective discrete values. Make sure the first column starts at 0
Lower Prob
Upper Prob
Discrete Value
0 .2 10
.2 .5 11
.5 .9 12
.9 1.0 13
Vlookup formula for the Discrete Distribution
Use the Excel function:=vlookup(rand(),table,3)
This function will look up the rand() number in column 1 of the table, identify the row that represents the correct cumulative probability, and look up the value associated with that probability in column 3.
See Vlookup Excel Tutorials in MyLMUConnect for logic of the Vlookup formula
Specifiying Input Distributions
Practice in Class Exercise 2!
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