clustering: Clustering analysis
In metan: Multi Environment Trials Analysis
clustering R Documentation
Clustering analysis
Description
![[Stable]](../help/figures/lifecycle-stable.svg)
\loadmathjax
Performs clustering analysis with selection of variables.
Usage
clustering(
.data,
...,
by = NULL,
scale = FALSE,
selvar = FALSE,
verbose = TRUE,
distmethod = "euclidean",
clustmethod = "average",
nclust = NA
)
Arguments
.data
The data to be analyzed. It can be a data frame, possible with
grouped data passed from dplyr::group_by().
...
The variables in .data to compute the distances. Set to
NULL, i.e., all the numeric variables in .data are used.
by
One variable (factor) to compute the function by. It is a shortcut
to dplyr::group_by(). To compute the statistics by more than
one grouping variable use that function.
scale
Should the data be scaled before computing the distances? Set to
FALSE. If TRUE, then, each observation will be divided by the standard
deviation of the variable \mjseqnZ_ij = X_ij / sd_j
selvar
Logical argument, set to FALSE. If TRUE, then an
algorithm for selecting variables is implemented. See the section
Details for additional information.
verbose
Logical argument. If TRUE (default) then the results
for variable selection are shown in the console.
distmethod
The distance measure to be used. This must be one of
'euclidean', 'maximum', 'manhattan',
'canberra', 'binary', 'minkowski', 'pearson',
'spearman', or 'kendall'. The last three are
correlation-based distance.
clustmethod
The agglomeration method to be used. This should be one of
'ward.D', 'ward.D2', 'single', 'complete',
'average' (= UPGMA), 'mcquitty' (= WPGMA), 'median' (=
WPGMC) or 'centroid' (= UPGMC).
nclust
The number of clusters to be formed. Set to NA
Details
When selvar = TRUE a variable selection algorithm is executed. The
objective is to select a group of variables that most contribute to explain
the variability of the original data. The selection of the variables is based
on eigenvalue/eigenvectors solution based on the following steps.
compute the distance matrix and the cophenetic correlation with the original
variables (all numeric variables in dataset);
compute the eigenvalues and eigenvectors of the correlation matrix between
the variables;
Delete the variable with the largest weight (highest eigenvector in
the lowest eigenvalue);
Compute the distance matrix and cophenetic correlation with the remaining
variables;
Compute the Mantel's correlation between the obtained distances matrix and
the original distance matrix;
Iterate steps 2 to 5 p - 2 times, where p is the number of original
variables.
At the end of the p - 2 iterations, a summary of the models is returned.
The distance is calculated with the variables that generated the model with
the largest cophenetic correlation. I suggest a careful evaluation aiming at
choosing a parsimonious model, i.e., the one with the fewer number of
variables, that presents acceptable cophenetic correlation and high
similarity with the original distances.
Value
-
data The data that was used to compute the distances.
-
cutpoint The cutpoint of the dendrogram according to Mojena (1977).
-
distance The matrix with the distances.
-
de The distances in an object of class dist.
-
hc The hierarchical clustering.
-
Sqt The total sum of squares.
-
tab A table with the clusters and similarity.
-
clusters The sum of square and the mean of the clusters for each
variable.
-
cofgrap If selectvar = TRUE, then, cofpgrap is a
ggplot2-based graphic showing the cophenetic correlation for each model
(with different number of variables). Else, will be a NULL object.
-
statistics If selectvar = TRUE, then, statistics shows
the summary of the models fitted with different number of variables,
including cophenetic correlation, Mantel's correlation with the original
distances (all variables) and the p-value associated with the Mantel's
test. Else, will be a NULL object.
Author(s)
Tiago Olivoto tiagoolivoto@gmail.com
References
Mojena, R. 2015. Hierarchical grouping methods and stopping
rules: an evaluation. Comput. J. 20:359-363. doi: 10.1093/comjnl/20.4.359
Examples
library(metan)
# All rows and all numeric variables from data
d1 <- clustering(data_ge2)
# Based on the mean for each genotype
mean_gen <-
data_ge2 %>%
mean_by(GEN) %>%
column_to_rownames("GEN")
d2 <- clustering(mean_gen)
# Select variables for compute the distances
d3 <- clustering(mean_gen, selvar = TRUE)
# Compute the distances with standardized data
# Define 4 clusters
d4 <- clustering(data_ge,
by = ENV,
scale = TRUE,
nclust = 4)
metan documentation built on March 7, 2023, 5:34 p.m.
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| clustering | R Documentation |
Clustering analysis
Description
\loadmathjax
Performs clustering analysis with selection of variables.
Usage
clustering( .data, ..., by = NULL, scale = FALSE, selvar = FALSE, verbose = TRUE, distmethod = "euclidean", clustmethod = "average", nclust = NA )
Arguments
.data |
The data to be analyzed. It can be a data frame, possible with
grouped data passed from |
... |
The variables in |
by |
One variable (factor) to compute the function by. It is a shortcut
to |
scale |
Should the data be scaled before computing the distances? Set to FALSE. If TRUE, then, each observation will be divided by the standard deviation of the variable \mjseqnZ_ij = X_ij / sd_j |
selvar |
Logical argument, set to |
verbose |
Logical argument. If |
distmethod |
The distance measure to be used. This must be one of
|
clustmethod |
The agglomeration method to be used. This should be one of
|
nclust |
The number of clusters to be formed. Set to |
Details
When selvar = TRUE a variable selection algorithm is executed. The
objective is to select a group of variables that most contribute to explain
the variability of the original data. The selection of the variables is based
on eigenvalue/eigenvectors solution based on the following steps.
compute the distance matrix and the cophenetic correlation with the original variables (all numeric variables in dataset);
compute the eigenvalues and eigenvectors of the correlation matrix between the variables;
Delete the variable with the largest weight (highest eigenvector in the lowest eigenvalue);
Compute the distance matrix and cophenetic correlation with the remaining variables;
Compute the Mantel's correlation between the obtained distances matrix and the original distance matrix;
Iterate steps 2 to 5 p - 2 times, where p is the number of original variables.
At the end of the p - 2 iterations, a summary of the models is returned. The distance is calculated with the variables that generated the model with the largest cophenetic correlation. I suggest a careful evaluation aiming at choosing a parsimonious model, i.e., the one with the fewer number of variables, that presents acceptable cophenetic correlation and high similarity with the original distances.
Value
-
data The data that was used to compute the distances.
-
cutpoint The cutpoint of the dendrogram according to Mojena (1977).
-
distance The matrix with the distances.
-
de The distances in an object of class
dist. -
hc The hierarchical clustering.
-
Sqt The total sum of squares.
-
tab A table with the clusters and similarity.
-
clusters The sum of square and the mean of the clusters for each variable.
-
cofgrap If
selectvar = TRUE, then,cofpgrapis a ggplot2-based graphic showing the cophenetic correlation for each model (with different number of variables). Else, will be aNULLobject. -
statistics If
selectvar = TRUE, then,statisticsshows the summary of the models fitted with different number of variables, including cophenetic correlation, Mantel's correlation with the original distances (all variables) and the p-value associated with the Mantel's test. Else, will be aNULLobject.
Author(s)
Tiago Olivoto tiagoolivoto@gmail.com
References
Mojena, R. 2015. Hierarchical grouping methods and stopping rules: an evaluation. Comput. J. 20:359-363. doi: 10.1093/comjnl/20.4.359
Examples
library(metan)
# All rows and all numeric variables from data
d1 <- clustering(data_ge2)
# Based on the mean for each genotype
mean_gen <-
data_ge2 %>%
mean_by(GEN) %>%
column_to_rownames("GEN")
d2 <- clustering(mean_gen)
# Select variables for compute the distances
d3 <- clustering(mean_gen, selvar = TRUE)
# Compute the distances with standardized data
# Define 4 clusters
d4 <- clustering(data_ge,
by = ENV,
scale = TRUE,
nclust = 4)
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