Deck 15: Introduction to Simulation Modeling

The "random" numbers generated by the RAND function (or by any other package's random number generator)are not really random.

When determining the most appropriate input probability distribution in a simulation model,first select the most appropriate family,and then select the most appropriate member of that family.

The normal distribution is often used in simulation models because it is the most common distribution in statistics and it does not allow negative values.

If we want to model a random stock price,we should do so with an unbounded symmetric probability distribution.

A discrete distribution is useful for many situations,either when the uncertain quantity is not continuous (the number of televisions demanded,for example)or when we want a discrete approximation to a continuous variable.

A random number from a binomial distribution indicates the number of successes in a certain number of identical trials.

@RISK introduces uncertainty explicitly into a spreadsheet model by allowing several inputs to have probability distributions and then enabling the simulation of random values from these inputs.

We typically choose between a symmetric and skewed distribution on the basis of realism.

The flaw of averages is the reason deterministic models can be very misleading.

A probability distribution is bounded if there are values A and B such that only one possible value can be less than A or greater than B.

The triangular distribution is sometimes used in simulation models because it is more flexible and intuitive than the normal distribution.

The uniform distribution is bounded by a minimum and a maximum,and all values between these two extremes are equally likely.

A primary difference between standard spreadsheet models and simulation models is that at least one of the input variable cells in a simulation model contains random numbers.

When we run simulation,the @RISK automatically keeps statistics such as averages and standard deviations,and can also create graphs such as histograms based on the values generated in the output cells in the simulation model.

The binomial distribution can be well approximated by the normal distribution when the number of trials n is sufficiently small and the probability of success p is not too close to 0 or 1.

One of the primary advantages of simulation models is that they enable managers to answer what-if questions about changes in systems without actually changing the systems themselves.

Sometimes it is convenient to treat a discrete probability distribution as continuous,and vice versa.

The three parameters required to specify a triangular distribution are the minimum,mean,and maximum.

The binomial distribution is a discrete distribution that is applied to situations where n independent and identical "trials" occur,with each trial resulting in a "success" or "failure," and where we want to generate the random number of successes in the n trials.

A correlation matrix must always be symmetric,so that the correlations above the diagonal are a mirror image of those below it.

RISKSIMTABLE is a function in @RISK for running several simulations simultaneously,one for each setting of an input or decision variable.

It is usually not too difficult to predict the shape of the output distribution from the shape(s)of the input distribution(s).

When we maximize or minimize the value of a decision variable by running several simulations simultaneously,we have found an optimal solution to the problem and attitude toward risk becomes irrelevant.

A correlation matrix must always have 1's along its diagonal (because a variable is always perfectly correlated with itself)and the correlations between variables elsewhere.

Data tables in spreadsheet simulations are useful for taking a "prototype" simulation and replicating its key results a desired number of times.

A common guideline in constructing confidence intervals for the mean is to place upper and lower bounds one standard error on either side of the average to obtain an approximate 95% confidence interval.

Analysts often plan a simulation so that the confidence interval for the mean of some important output will be sufficiently narrow.The reasoning is that narrow confidence intervals imply more precision about the estimated mean of the output variable.

Different random numbers generated by the computer are probabilistically dependent.This implies that when we generate a random number in a particular cell,it has some effect on the values of any other random numbers generated in the spreadsheet.

It is common in computer simulations to estimate the mean of some distribution by the average of the simulated observations.The usual practice is then to accompany this estimate with a confidence interval,which indicates the accuracy of the estimate.

Correlation between two random input variables might not change the mean of an output,but it can definitely affect the variability and shape of an output distribution.

If you add several normally distributed random numbers,the result is normally distributed,where the mean of the sum is the sum of the individual means,and the variance of the sum is the sum of the individual variances.This result is difficult to prove mathematically,but it is easy to demonstrate with simulation.To do so,run a simulation where you add three normally distributed random numbers,each with mean 100 and standard deviation 10.Your single output variable should be the sum of these three numbers.Verify with @RISK that the distribution of this output is approximately normal with mean 300 and variance 300 (hence,standard deviation = 17.32).