chain

run a Monte Carlo Markov Chain

Syntax: chain [best] [burn <length>] [clear] [dic] [filetype fits|ascii] [info] [length <length>] [load <filename>] [proposal [<distr> <source>] |[<user-defined>]] [rand on|off] [run [>]<filename>] [stat <par num>] [temperature <value>] [type mh|gw] [unload <range>] [walkers <value>]

If the proposal source is set to use the fit correlation matrix (the default), you must perform a fit before running any chains.

When chains are loaded (and their parameters correspond to the currently loaded model), they will be used by the various XSPEC commands that require distributions of parameter values, such as eqwidth or flux when calculating error estimations. The error command itself will also use the loaded chains, determining the error range from a central percentage of the sorted chain values. This is likely to be faster than the error command's standard algorithm when not using chains.

best
Finds the parameter and statistic values for the point in the loaded chains with the best statistic value.
burn <length>
Specifies that the first <length> steps should be thrown away prior to storing the chain.
clear
Does a reset and removes all chains from the list.
dic
Calculates the Deviance Information Criterion and the effective number of parameters for the loaded chains.
filetype fits|ascii
Chooses the format of the output chain file. fits (the default) writes the chain to a binary table in a FITS file. ascii writes the chain to a simple text file. Either format is readable when using the chain load command.
info
Prints out information on the current chains.
length <length>
Sets the length for new chains.
load <filename>
Loads a chain which has been run earlier, stored in file given by <filename>.
proposal <distr> <source>
Selects the proposal distribution and source of covariance information to be used when running new chains. For the Metropolis-Hastings algorithm this distribution is used at each step of the chain while for the Goodman-Weare algorithm it is only used to set the initial walkers. The default is proposal gaussian fit. Currently implemented <distr> options are: gaussian, cauchy, and uniform. <source> options are:
chain
Covariance is taken from the currently loaded chains.
deltas <value>
A diagonal covariance matrix is constructed from the parameter deltas multiplied by the value entered on the command line.
diagonal <values>
The values of a diagonal covariance matrix are entered directly on the command line, separated by commas and/or spaces: C_11 C_22 ... C_nn.
<filename>
Covariance is read in from a user-specified text file. The file must contain the values of an NxN matrix where N is the current number of freely varying parameters. The values of each matrix row should be entered on one line with whitespace separation. Since this matrix is always symmetrical, values above the diagonal may be omitted. For example a 2x2 matrix could be entered as:
        0.98
        0.15 0.96
fit
Covariance is taken from the correlation information produced by the current fit.
limits
Used only for the uniform option and draws uniformly from the entire parameter space defined by the parameter hard limits.
matrix <values>
The lower half and diagonal of a symmetrical square covariance matrix are entered directly on the command line, separated by commas and/or spaces: C_11 C_21 C_22 C_31 C_32 C_33 ... C_nn
The uniform <distr> option only accepts <source> values of deltas or limits. chain proposal with no other arguments will show a list of all available proposal options. For an alternative to XSPEC's <distr> <source> proposal options, the user may instead want to provide their own custom randomization algorithm. This can be done by writing their own C++ class(es) derived from an XSPEC randomizer base class. The custom class is added at runtime using the same initpackage or lmod command sequence as for local models, and is specified by proposal <name> where <name> is the unique name attribute the user provides for their class. Please see Appendix G for more information on writing a custom randomizing class, and initpackage for building and loading it.
rand on|off
Specifies whether the chain start point will be randomized, or taken from the current parameters.
recalc
A deprecated option that performs the equivalent of proposal gaussian chain.
rescale <range>
Rescale the covariance matrix used in the proposal distribution by the factor given.
run [>] <filename>
Runs a new chain written to the specified file, or append to an already loaded file if the '>' character preceeds the filename. The chain is written to the file as it runs so its performance can be monitored by examining the file. For high-chatter settings, additional information is printed to the screen. A long run may be interrupted with Ctrl-C, in which case the chain file will still exist but will not be automatically loaded. If appending to a file, the current filetype setting must match the format of the file or XSPEC will prevent it.
stat [<modName>:]<parIdx>
Writes out statistical information on a particular parameter of the chain, specified by the parameter index number. If the parameter is from a named model then it is indicated by [<model name>:]<n>. If the parameter is from a response model then use the format [<source number>:]r<n>. The information displayed is:
  • The mean of the parameter in each chain.
  • If there are multiple chains, the parameter mean over all chains and the variance between chain means.
  • The variance over all the chains.
  • If there are multiple chains the Rubin-Gelman convergence measure.
  • The Geweke convergence measure.
  • If using Metropolis-Hastings, the fraction of repeats, defined as the number of lines in the chain file for which all parameter values are identical to the previous line, divided by the number of lines in the file.
temperature <value>
Sets the temperature parameter used in the Metropolis-Hastings algorithm for the proposal acceptance or rejection. The default value is 1.0 and zero or negative values are forbidden. By using the run append option, it is possible for different sections of the chain file to use different temperatures. The temperatures and the line numbers to which they apply are stored in the header of the FITS format chain files, or in the metadata section at the top of the ASCII text format files.
type mh|gw
Determines the algorithm used to generate the chain. Choices are mh (Metropolis-Hastings) or gw (Goodman-Weare, the default). If using Goodman-Weare, must also set the walkers parameter. Also note for Goodman-Weare that the calculation of walkers sets may be sped up by adjusting the parallel command's walkers option to perform the calculations over multiple processes. The walkers are initialized in two different ways depending on whether a fit has previously been run. If a fit has been run and a covariance matrix is available then walkers are initialized by drawing from a multi-Normal distribution whose variance matrix is based on the covariance matrix. If a covariance matrix is not available then parameters in each walker are initialized by drawing from a uniform distribution centered on the current fit parameters with width ten times that of the parameter delta. Initial values for walkers can also be generated outside xspec and then imported by writing them to a standard FITS chain output file with number of rows equal to number of walkers. If a chain is now run using the append option ($>$ before the filename) then the starting values for each walker will be taken from the file.
unload <range>
Removes the chains specified by <range> from the list in xspec. Note that this does NOT delete the chain files.
walkers <value>
Sets the walkers parameter for the Goodman-Weare chain algorithm (see chain type). This must be an even integer, and both the chain length and burn length should be divisible by it (XSPEC will adjust the lengths to make them so if necessary).

All loaded chains must contain the same fit parameters. xspec will prevent the loading of a chain with a different number of parameters from the currently loaded chains.

Algorithm notes

For the Goodman-Weare (gw) choice the method used to derive new parameter values for the walkers is as follows.

  • Divide the walkers into two sets (to allow parallelization)
  • For each walker, W, randomly choose a walker, U, from the other set
  • Draw a random number Z from the distribution 1/$\sqrt(z)$, where z lies between 0.5 and 2.0.
  • Set the new parameters for W to Z*parameters(W) + (1-Z)*parameters(U)
  • Calculate a new fit statistic with these parameters then calculate T = (N-1)*log(Z) - 0.5*(newStat-oldStat) where N is the number of fit parameters
  • Draw a random number from a uniform distribution between 0 and 1 and if the ln of this random number is less than T then accept the new parameter values otherwise repeat the old parameter values.

Examples:

XSPEC12>chain length 100 
//Sets length of chains produced by the run command to 100.
XSPEC12>chain run chain_file1.out
//Runs a chain based on current valid fit parameters, output to 
//chain_file1.out
XSPEC12>chain run >chain_file1.out
//Appends another run of length 100 to the end of chain_file1.out
XSPEC12>chain load chain_old.out
//Loads a pre-existing chain file, the result of an earlier run 
//command.  Warning is issued if not the same length as 
//chain_file1.out
XSPEC12>chain stat 3
//Prints statistical information on the 3rd parameter of the chain.
XSPEC12>chain proposal gaussian myfile.txt
//New chain proposals will be a normal distribution using
//covariance values stored in myfile.txt rather than fit
//correlation matrix. 
XSPEC12>chain prop gauss diag .1 .001 .0001
// New chain proposals will be a normal distribution using a 3x3
// diagonal covariance matrix with the values from the
// command line. 
XSPEC12>chain temperature .8
// Sets the Metropolis-Hastings temperature value to .8 for
// future chain runs, replacing the default 1.0.
XSPEC12>chain clear
//Removes the 2 loaded chains from xspec's chain list.


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