block.plsda: N-integration with Projection to Latent Structures models...
In ajabadi/mixOmics2: Omics Data Integration Project
Description
Usage
Arguments
Details
Value
Author(s)
References
See Also
Examples
Description
Integration of multiple data sets measured on the same samples or
observations to classify a discrete outcome, ie. N-integration with
Discriminant Analysis. The method is partly based on Generalised Canonical
Correlation Analysis.
Usage
1
2
3
Arguments
X
A list of data sets (called 'blocks') measured on the same samples.
Data in the list should be arranged in matrices, samples x variables, with
samples order matching in all data sets.
Y
A factor or a class vector indicating the discrete outcome of each
sample.
indY
To be supplied if Y is missing, indicates the position of the
factor / class vector outcome in the list X
ncomp
the number of components to include in the model. Default to 2.
Applies to all blocks.
design
numeric matrix of size (number of blocks in X) x (number of
blocks in X) with values between 0 and 1. Each value indicates the strenght
of the relationship to be modelled between two blocks; a value of 0
indicates no relationship, 1 is the maximum value. If Y is provided
instead of indY, the design matrix is changed to include
relationships to Y.
scheme
Either "horst", "factorial" or "centroid". Default =
horst, see reference.
mode
character string. What type of algorithm to use, (partially)
matching one of "regression", "canonical", "invariant"
or "classic". See Details. Default = regression.
scale
boleean. If scale = TRUE, each block is standardized to zero
means and unit variances. Default = TRUE.
init
Mode of initialization use in the algorithm, either by Singular
Value Decompostion of the product of each block of X with Y ("svd") or each
block independently ("svd.single"). Default = svd.
tol
Convergence stopping value.
max.iter
integer, the maximum number of iterations.
near.zero.var
boolean, see the internal nearZeroVar
function (should be set to TRUE in particular for data with many zero
values). Default = FALSE.
all.outputs
boolean. Computation can be faster when some specific
(and non-essential) outputs are not calculated. Default = TRUE.
Details
block.plsda function fits a horizontal integration PLS-DA model with
a specified number of components per block). A factor indicating the
discrete outcome needs to be provided, either by Y or by its position
indY in the list of blocks X.
X can contain missing values. Missing values are handled by being
disregarded during the cross product computations in the algorithm
block.pls without having to delete rows with missing data.
Alternatively, missing data can be imputed prior using the nipals
function.
The type of algorithm to use is specified with the mode argument.
Four PLS algorithms are available: PLS regression ("regression"), PLS
canonical analysis ("canonical"), redundancy analysis
("invariant") and the classical PLS algorithm ("classic") (see
References and ?pls for more details).
Note that our method is partly based on Generalised Canonical Correlation
Analysis and differs from the MB-PLS approaches proposed by Kowalski et al.,
1989, J Chemom 3(1) and Westerhuis et al., 1998, J Chemom, 12(5).
Value
block.plsda returns an object of class
"block.plsda","block.pls", a list that contains the following
components:
X
the centered and standardized original predictor matrix.
indY
the position of the outcome Y in the output list X.
ncomp
the number of components included in the model for each block.
mode
the algorithm used to fit the model.
variates
list
containing the variates of each block of X.
loadings
list containing
the estimated loadings for the variates.
names
list containing the
names to be used for individuals and variables.
nzv
list containing
the zero- or near-zero predictors information.
iter
Number of
iterations of the algorthm for each component
explained_variance
Percentage of explained variance for each
component and each block
Author(s)
Florian Rohart, Benoit Gautier, Kim-Anh Lê Cao
References
On PLSDA:
Barker M and Rayens W (2003). Partial least squares for discrimination.
Journal of Chemometrics 17(3), 166-173. Perez-Enciso, M. and
Tenenhaus, M. (2003). Prediction of clinical outcome with microarray data: a
partial least squares discriminant analysis (PLS-DA) approach. Human
Genetics 112, 581-592. Nguyen, D. V. and Rocke, D. M. (2002). Tumor
classification by partial least squares using microarray gene expression
data. Bioinformatics 18, 39-50.
On multiple integration with PLS-DA: Gunther O., Shin H., Ng R. T. ,
McMaster W. R., McManus B. M. , Keown P. A. , Tebbutt S.J. , Lê Cao K-A. ,
(2014) Novel multivariate methods for integration of genomics and proteomics
data: Applications in a kidney transplant rejection study, OMICS: A journal
of integrative biology, 18(11), 682-95.
On multiple integration with sPLS-DA and 4 data blocks:
Singh A., Gautier B., Shannon C., Vacher M., Rohart F., Tebbutt S. and Lê
Cao K.A. (2016). DIABLO: multi omics integration for biomarker discovery.
BioRxiv available here:
http://biorxiv.org/content/early/2016/08/03/067611
mixOmics article:
Rohart F, Gautier B, Singh A, Lê Cao K-A. mixOmics: an R package for 'omics
feature selection and multiple data integration. PLoS Comput Biol 13(11):
e1005752
See Also
plotIndiv, plotArrow,
plotLoadings, plotVar, predict,
perf, selectVar, block.pls,
block.splsda and http://www.mixOmics.org for more details.
Examples
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
data = list(gene = nutrimouse$gene, lipid = nutrimouse$lipid, Y = nutrimouse$diet)
# with this design, all blocks are connected
design = matrix(c(0,1,1,1,0,1,1,1,0), ncol = 3, nrow = 3,
byrow = TRUE, dimnames = list(names(data), names(data)))
res = block.plsda(X = data, indY = 3) # indY indicates where the outcome Y is in the list X
plotIndiv(res, ind.names = FALSE, legend = TRUE)
plotVar(res)
## Not run:
# when Y is provided
res2 = block.plsda(list(gene = nutrimouse$gene, lipid = nutrimouse$lipid),
Y = nutrimouse$diet, ncomp = 2)
plotIndiv(res2)
plotVar(res2)
## End(Not run)
ajabadi/mixOmics2 documentation built on Aug. 9, 2019, 1:08 a.m.
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Description Usage Arguments Details Value Author(s) References See Also Examples
Description
Integration of multiple data sets measured on the same samples or observations to classify a discrete outcome, ie. N-integration with Discriminant Analysis. The method is partly based on Generalised Canonical Correlation Analysis.
Usage
1 2 3 |
Arguments
X |
A list of data sets (called 'blocks') measured on the same samples. Data in the list should be arranged in matrices, samples x variables, with samples order matching in all data sets. |
Y |
A factor or a class vector indicating the discrete outcome of each sample. |
indY |
To be supplied if Y is missing, indicates the position of the
factor / class vector outcome in the list |
ncomp |
the number of components to include in the model. Default to 2. Applies to all blocks. |
design |
numeric matrix of size (number of blocks in X) x (number of
blocks in X) with values between 0 and 1. Each value indicates the strenght
of the relationship to be modelled between two blocks; a value of 0
indicates no relationship, 1 is the maximum value. If |
scheme |
Either "horst", "factorial" or "centroid". Default =
|
mode |
character string. What type of algorithm to use, (partially)
matching one of |
scale |
boleean. If scale = TRUE, each block is standardized to zero
means and unit variances. Default = |
init |
Mode of initialization use in the algorithm, either by Singular
Value Decompostion of the product of each block of X with Y ("svd") or each
block independently ("svd.single"). Default = |
tol |
Convergence stopping value. |
max.iter |
integer, the maximum number of iterations. |
near.zero.var |
boolean, see the internal |
all.outputs |
boolean. Computation can be faster when some specific
(and non-essential) outputs are not calculated. Default = |
Details
block.plsda function fits a horizontal integration PLS-DA model with
a specified number of components per block). A factor indicating the
discrete outcome needs to be provided, either by Y or by its position
indY in the list of blocks X.
X can contain missing values. Missing values are handled by being
disregarded during the cross product computations in the algorithm
block.pls without having to delete rows with missing data.
Alternatively, missing data can be imputed prior using the nipals
function.
The type of algorithm to use is specified with the mode argument.
Four PLS algorithms are available: PLS regression ("regression"), PLS
canonical analysis ("canonical"), redundancy analysis
("invariant") and the classical PLS algorithm ("classic") (see
References and ?pls for more details).
Note that our method is partly based on Generalised Canonical Correlation Analysis and differs from the MB-PLS approaches proposed by Kowalski et al., 1989, J Chemom 3(1) and Westerhuis et al., 1998, J Chemom, 12(5).
Value
block.plsda returns an object of class
"block.plsda","block.pls", a list that contains the following
components:
X |
the centered and standardized original predictor matrix. |
indY |
the position of the outcome Y in the output list X. |
ncomp |
the number of components included in the model for each block. |
mode |
the algorithm used to fit the model. |
variates |
list containing the variates of each block of X. |
loadings |
list containing the estimated loadings for the variates. |
names |
list containing the names to be used for individuals and variables. |
nzv |
list containing the zero- or near-zero predictors information. |
iter |
Number of iterations of the algorthm for each component |
explained_variance |
Percentage of explained variance for each component and each block |
Author(s)
Florian Rohart, Benoit Gautier, Kim-Anh Lê Cao
References
On PLSDA:
Barker M and Rayens W (2003). Partial least squares for discrimination. Journal of Chemometrics 17(3), 166-173. Perez-Enciso, M. and Tenenhaus, M. (2003). Prediction of clinical outcome with microarray data: a partial least squares discriminant analysis (PLS-DA) approach. Human Genetics 112, 581-592. Nguyen, D. V. and Rocke, D. M. (2002). Tumor classification by partial least squares using microarray gene expression data. Bioinformatics 18, 39-50.
On multiple integration with PLS-DA: Gunther O., Shin H., Ng R. T. , McMaster W. R., McManus B. M. , Keown P. A. , Tebbutt S.J. , Lê Cao K-A. , (2014) Novel multivariate methods for integration of genomics and proteomics data: Applications in a kidney transplant rejection study, OMICS: A journal of integrative biology, 18(11), 682-95.
On multiple integration with sPLS-DA and 4 data blocks:
Singh A., Gautier B., Shannon C., Vacher M., Rohart F., Tebbutt S. and Lê Cao K.A. (2016). DIABLO: multi omics integration for biomarker discovery. BioRxiv available here: http://biorxiv.org/content/early/2016/08/03/067611
mixOmics article:
Rohart F, Gautier B, Singh A, Lê Cao K-A. mixOmics: an R package for 'omics feature selection and multiple data integration. PLoS Comput Biol 13(11): e1005752
See Also
plotIndiv, plotArrow,
plotLoadings, plotVar, predict,
perf, selectVar, block.pls,
block.splsda and http://www.mixOmics.org for more details.
Examples
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 | data = list(gene = nutrimouse$gene, lipid = nutrimouse$lipid, Y = nutrimouse$diet)
# with this design, all blocks are connected
design = matrix(c(0,1,1,1,0,1,1,1,0), ncol = 3, nrow = 3,
byrow = TRUE, dimnames = list(names(data), names(data)))
res = block.plsda(X = data, indY = 3) # indY indicates where the outcome Y is in the list X
plotIndiv(res, ind.names = FALSE, legend = TRUE)
plotVar(res)
## Not run:
# when Y is provided
res2 = block.plsda(list(gene = nutrimouse$gene, lipid = nutrimouse$lipid),
Y = nutrimouse$diet, ncomp = 2)
plotIndiv(res2)
plotVar(res2)
## End(Not run)
|
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