AuerGervini-class | R Documentation |
Auer and Gervini [1] described a graphical Bayesian method for
estimating the number of statistically significant principal
components. We have implemented their method in the AuerGervini
class, and enhanced it by automating the final selection.
AuerGervini(Lambda, dd=NULL, epsilon = 2e-16) agDimension(object, agfun=agDimTwiceMean)
Lambda |
Either a |
dd |
A vector of length 2 containing the dimensions of the data
used to created the Auer-Gervini object. If |
epsilon |
A numeric value. Used to remove any variances that are
less than |
object |
An object of the |
agfun |
A function that takes one argument (a vector of step lengths) and returns a logical vector of the same length (where true indicates "long" as opposed to "short" steps). |
The Auer-Gervini method for determining the number of principal components is based on a Bayesian model that assaerts that the vector of explained variances (eigenvalues) should have the form
a_1 ≤ a_2 ≤ … ≤ a_d < a_{d+1} = a_{d+2} = … a_n
with the goal being to find the true dimension d. They consider
a set of prior distributions on d \in \{1, …, n\} that decay
exponentially, with the rate of decay controlled by a parameter
θ. For each value of θ, one selects the value
of d that has the maximum a posteriori (MAP) probability. Auer
and Gervini show that the dimensions selected by this procedure write
d as a non-increasing step function of θ. The values
of θ where the steps change are stored in the
changePoints
slot, and the corresponding d-values are
stored in the dLevels
slot.
Auer and Gervini go on to advise using their method as a graphical
approach, manually (or visually?) selecting the highest step that is
"long". Our implementation provides several different algorithms for
automatically deciding what is "long" enough. The simplest (but
fairly naive) approach is to take anything that is longer than twice
the mean; other algorithms are described in
agDimFunction
.
The AuerGervini
function constructs and returns an object of
the AuerGervini
class.
The agDimension
function computes the number of significant
principal components. The general idea is that one starts by
computing the length of each step in the Auer-Gerivni plot, and must
then separate these into "long" and "short" classes. We provide a
variety of different algorithms to carry out this process; the
default algorithm in the function agDimTwiceMean
defines
a step as "long" if it more than twice the mean step length.
Objects should be created using the AuerGervini
constructor.
Lambda
:A numeric
vector containing
the explained variances in decreasing order.
dimensions
Numeric vector of length 2 containing the dimnesions of the underlying data matrix.
dLevels
:Object of class numeric
; see details
changePoints
:Object of class numeric
; see details
signature(x = "AuerGervini", y = "missing")
: ...
signature(object = "AuerGervini")
: ...
Kevin R. Coombes <krc@silicovore.com>
[1] P Auer, D Gervini. Choosing principal components: a new graphical method based on Bayesian model selection. Communications in Statistics-Simulation and Computation 37 (5), 962-977.
[2] Wang M, Kornbla SM, Coombes KR. Decomposing the Apoptosis Pathway Into Biologically Interpretable Principal Components. Preprint: bioRxiv, 2017. <doi://10.1101/237883>.
agDimFunction
to get a complete list of the functions
implementing different algorithms to separate the step lengths into
two classes.
showClass("AuerGervini") # simulate variances lambda <- rev(sort(diff(sort(c(0, 1, runif(9)))))) # apply the Auer-Gervini method ag <- AuerGervini(lambda, dd=c(3,10)) # Review the results summary(ag) agDimension(ag) agDimension(ag, agDimKmeans) # Look at the results graphically plot(ag, agfun=list(agDimTwiceMean, agDimKmeans))
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