Finance[ExpectedShortfall] - calculate the expected shortfall
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Calling Sequence
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ExpectedShortfall(pathfunction, pathgenerator, opts)
ExpectedShortfall(pathfunction, process, timegrid, opts)
ExpectedShortfall(pathfunction, process, timeinterval, opts)
ExpectedShortfall(expression, opts)
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Parameters
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pathfunction
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procedure; path function
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pathgenerator
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path generator data structure; path generator
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process
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one- or multi-dimensional stochastic process, or list or vector of one-dimensional stochastic processes
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timegrid
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range or time grid data structure; time grid
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timeinterval
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range; time interval
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expression
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algebraic expression; expression whose shortfall is to be estimated
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opts
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(optional) equation(s) of the form option = value where option is one of confidencelevel, replications, timesteps, or output; specify options for the ExpectedShortfall command
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Description
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The ExpectedShortfall(pathfunction, pathgenerator, opts) calling sequence computes a Monte Carlo estimate of the expected shortfall of a portfolio whose total value is governed by the specified stochastic process. It follows the same procedure as the SamplePath and ExpectedValue commands.
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Compute the value .
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Repeat these two steps the specified number of times (see the replications option) and compute the mean average.
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The ExpectedShortfall command also computes such statistics as standard deviation, skewness, kurtosis, minimum, maximum and standard error (see the output option).
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The ExpectedShortfall(pathfunction, process, timegrid, opts) and ExpectedShortfall(pathfunction, process, timeinterval, opts) calling sequences first construct the corresponding path generator and then perform the same computations as above.
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The parameter pathfunction must be a Maple procedure that accepts a one-dimensional array of floating-point numbers (sample path for the underlying process) and returns the corresponding value as a floating-point number. A path function can be used, for example, to compute expected values for some path-dependent payoffs.
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The timegrid parameter can be used to pass non-homogeneous time grids to the simulation routines. It must be given as a data structure generated by the TimeGrid command.
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The ExpectedShortfall(expression, opts) calling sequence attempts to extract all the stochastic variables involved in expression and generate the corresponding path generator and path function using the specified number of time steps. In particular, ExpectedShortfall will extract all time instances involved in expression and adjust them so that they belong to the grid.
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Options
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confidencelevel = realcons -- This option specifies the confidence level for which the expected shortfall is computed. The value of this option must be a real constant between 0 and 1. By default, a .99 confidence level is used.
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replications = posint -- This option specifies the number of replications of the sample path. By default, only one replication of the sample path is generated.
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timesteps = posint -- This option specifies the number of time steps. This option is ignored if an explicit time grid is specified. By default, only one time step is used.
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output = value, standarddeviation, skewness, kurtosis, minimum, maximum, standarderror, or a list containing several of these quantities -- This option specifies the quantities returned by the ExpectedShortfall command. The output = all option forces the ExpectedShortfall command to return all of the available statistics.
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Compatibility
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The Finance[ExpectedShortfall] command was introduced in Maple 15.
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Examples
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Here is a simple one-dimensional stochastic process.
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Here are several replications of the sample path.
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Here is an example involving a multivariate stochastic process.
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Here is an example of a stochastic process that depends on two factors: one is the previously defined Wiener process; the second is a Poisson process.
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Here are some expressions involving stochastic variables.
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This is the use of a path function.
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testproc := proc(X) exp(X[11]); end proc;
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See Also
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Finance[BrownianMotion], Finance[CEVProcess], Finance[DeterministicProcess], Finance[Diffusion], Finance[Drift], Finance[GaussianShortRateProcess], Finance[GeometricBrownianMotion], Finance[HestonProcess], Finance[OrnsteinUhlenbeckProcess], Finance[PathPlot], Finance[SamplePath], Finance[SampleValues], Finance[SquareRootDiffusion], Finance[StochasticProcesses], Finance[ValueAtRisk], Finance[WienerProcess]
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References
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Glasserman, P., Monte Carlo Methods in Financial Engineering. New York: Springer-Verlag, 2004.
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Hull, J., Options, Futures, and Other Derivatives, 5th. edition. Upper Saddle River, New Jersey: Prentice Hall, 2003.
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Kloeden, P., and Platen, E., Numerical Solution of Stochastic Differential Equations, New York: Springer-Verlag, 1999.
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