simule: A constrained l1 minimization approach for estimating...
In simule: A Constrained L1 Minimization Approach for Estimating Multiple Sparse Gaussian or Nonparanormal Graphical Models
Description
Usage
Arguments
Details
Value
Author(s)
References
Examples
Description
models from multiple related datasets using the SIMULE algorithm. Please
run demo(simule) to learn the basic functions provided by this package.
For further details, please read the original paper: Beilun Wang,
Ritambhara Singh, Yanjun Qi (2017) <DOI:10.1007/s10994-017-5635-7>.
Usage
1
Arguments
X
A List of input matrices. They can be data matrices or
covariance/correlation matrices. If every matrix in the X is a symmetric
matrix, the matrices are assumed to be covariance/correlation matrices.
More details at <https://github.com/QData/SIMULE>
lambda
A positive number. The hyperparameter controls the sparsity
level of the matrices. The \eqn\lambda_n in the following section:
Details.
epsilon
A positive number. The hyperparameter controls the
differences between the shared pattern among graphs and the individual part
of each graph. The \eqn\epsilon in the following section: Details. If
epsilon becomes larger, the generated graphs will be more similar to each
other. The default value is 1, which means that we set the same weights to
the shared pattern among graphs and the individual part of each graph.
covType
A parameter to decide which Graphical model we choose to
estimate from the input data.
If covType = "cov", it means that we estimate multiple sparse Gaussian
Graphical models. This option assumes that we calculate (when input X
represents data directly) or use (when X elements are symmetric
representing covariance matrices) the sample covariance matrices as input
to the simule algorithm.
If covType = "kendall", it means that we estimate multiple nonparanormal
Graphical models. This option assumes that we calculate (when input X
represents data directly) or use (when X elements are symmetric
representing correlation matrices) the kendall's tau correlation matrices
as input to the simule algorithm.
parallel
A boolean. This parameter decides if the package will use
the multithreading architecture or not.
Details
The SIMULE algorithm is a constrained l1 minimization method that can
detect both the shared and the task-specific parts of multiple graphs
explicitly from data (through jointly estimating multiple sparse Gaussian
graphical models or Nonparanormal graphical models). It solves the
following equation: \deqn \hat\Omega^(1)_I, \hat\Omega^(2)_I,
\dots, \hat\Omega^(K)_I, \hat\Omega_S =
\min\limits_\Omega^(i)_I,\Omega_S\sum\limits_i ||\Omega^(i)_I||_1+
\epsilon K||\Omega_S||_1 Subject to : \deqn
||\Sigma^(i)(\Omega^(i)_I + \Omega_S) - I||_\infty \le \lambda_n, i
= 1,\dots,K \nonumber Please also see the equation (7) in our paper. The
\eqn\lambda_n is the hyperparameter controlling the sparsity level of the
matrices and it is the \codelambda in our function. The \eqn\epsilon is
the hyperparameter controlling the differences between the shared pattern
among graphs and the individual part of each graph. It is the
\codeepsilon parameter in our function and the default value is 1. For
further details, please see our paper:
<http://link.springer.com/article/10.1007/s10994-017-5635-7>.
Value
\itemGraphsA list of the estimated inverse
covariance/correlation matrices. \itemshareThe share graph among
multiple tasks.
Author(s)
Beilun Wang
References
Beilun Wang, Ritambhara Singh, Yanjun Qi (2017). A constrained
L1 minimization approach for estimating multiple Sparse Gaussian or
Nonparanormal Graphical Models.
http://link.springer.com/article/10.1007/s10994-017-5635-7
Examples
1
2
3
4
5
6
## Not run:
data(exampleData)
result = simule(X = exampleData , lambda = 0.1, epsilon = 0.45, covType = "cov", FALSE)
plot.simule(result)
## End(Not run)
simule documentation built on May 1, 2019, 6:47 p.m.
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
Description Usage Arguments Details Value Author(s) References Examples
Description
models from multiple related datasets using the SIMULE algorithm. Please run demo(simule) to learn the basic functions provided by this package. For further details, please read the original paper: Beilun Wang, Ritambhara Singh, Yanjun Qi (2017) <DOI:10.1007/s10994-017-5635-7>.
Usage
1 |
Arguments
X |
A List of input matrices. They can be data matrices or covariance/correlation matrices. If every matrix in the X is a symmetric matrix, the matrices are assumed to be covariance/correlation matrices. More details at <https://github.com/QData/SIMULE> |
lambda |
A positive number. The hyperparameter controls the sparsity level of the matrices. The \eqn\lambda_n in the following section: Details. |
epsilon |
A positive number. The hyperparameter controls the differences between the shared pattern among graphs and the individual part of each graph. The \eqn\epsilon in the following section: Details. If epsilon becomes larger, the generated graphs will be more similar to each other. The default value is 1, which means that we set the same weights to the shared pattern among graphs and the individual part of each graph. |
covType |
A parameter to decide which Graphical model we choose to estimate from the input data. If covType = "cov", it means that we estimate multiple sparse Gaussian Graphical models. This option assumes that we calculate (when input X represents data directly) or use (when X elements are symmetric representing covariance matrices) the sample covariance matrices as input to the simule algorithm. If covType = "kendall", it means that we estimate multiple nonparanormal Graphical models. This option assumes that we calculate (when input X represents data directly) or use (when X elements are symmetric representing correlation matrices) the kendall's tau correlation matrices as input to the simule algorithm. |
parallel |
A boolean. This parameter decides if the package will use the multithreading architecture or not. |
Details
The SIMULE algorithm is a constrained l1 minimization method that can detect both the shared and the task-specific parts of multiple graphs explicitly from data (through jointly estimating multiple sparse Gaussian graphical models or Nonparanormal graphical models). It solves the following equation: \deqn \hat\Omega^(1)_I, \hat\Omega^(2)_I, \dots, \hat\Omega^(K)_I, \hat\Omega_S = \min\limits_\Omega^(i)_I,\Omega_S\sum\limits_i ||\Omega^(i)_I||_1+ \epsilon K||\Omega_S||_1 Subject to : \deqn ||\Sigma^(i)(\Omega^(i)_I + \Omega_S) - I||_\infty \le \lambda_n, i = 1,\dots,K \nonumber Please also see the equation (7) in our paper. The \eqn\lambda_n is the hyperparameter controlling the sparsity level of the matrices and it is the \codelambda in our function. The \eqn\epsilon is the hyperparameter controlling the differences between the shared pattern among graphs and the individual part of each graph. It is the \codeepsilon parameter in our function and the default value is 1. For further details, please see our paper: <http://link.springer.com/article/10.1007/s10994-017-5635-7>.
Value
\itemGraphsA list of the estimated inverse covariance/correlation matrices. \itemshareThe share graph among multiple tasks.
Author(s)
Beilun Wang
References
Beilun Wang, Ritambhara Singh, Yanjun Qi (2017). A constrained L1 minimization approach for estimating multiple Sparse Gaussian or Nonparanormal Graphical Models. http://link.springer.com/article/10.1007/s10994-017-5635-7
Examples
1 2 3 4 5 6 | ## Not run:
data(exampleData)
result = simule(X = exampleData , lambda = 0.1, epsilon = 0.45, covType = "cov", FALSE)
plot.simule(result)
## End(Not run)
|
R Package Documentation
Browse R Packages
We want your feedback!
Note that we can't provide technical support on individual packages. You should contact the package authors for that.
Embedding an R snippet on your website
Add the following code to your website.
For more information on customizing the embed code, read Embedding Snippets.