plotPCA: Plot PCA for an SCESet object
In dynverse/scaterlegacy: Single-cell analysis toolkit for gene expression data in R
Description
Usage
Arguments
Details
Value
Examples
Description
Produce a principal components analysis (PCA) plot of two or more principal
components for an SCESet dataset.
Usage
1
2
3
4
5
6
7
8
9
10
11
12
13
plotPCASCESet(object, ntop = 500, ncomponents = 2, exprs_values = "exprs",
colour_by = NULL, shape_by = NULL, size_by = NULL, feature_set = NULL,
return_SCESet = FALSE, scale_features = TRUE, draw_plot = TRUE,
pca_data_input = "exprs", selected_variables = NULL,
detect_outliers = FALSE, theme_size = 10, legend = "auto")
## S4 method for signature 'SCESet'
plotPCA(object, ntop = 500, ncomponents = 2,
exprs_values = "exprs", colour_by = NULL, shape_by = NULL,
size_by = NULL, feature_set = NULL, return_SCESet = FALSE,
scale_features = TRUE, draw_plot = TRUE, pca_data_input = "exprs",
selected_variables = NULL, detect_outliers = FALSE, theme_size = 10,
legend = "auto")
Arguments
object
an SCESet object
ntop
numeric scalar indicating the number of most variable features to
use for the PCA. Default is 500, but any ntop argument is
overrided if the feature_set argument is non-NULL.
ncomponents
numeric scalar indicating the number of principal
components to plot, starting from the first principal component. Default is
2. If ncomponents is 2, then a scatterplot of PC2 vs PC1 is produced.
If ncomponents is greater than 2, a pairs plots for the top components
is produced.
exprs_values
character string indicating which values should be used
as the expression values for this plot. Valid arguments are "tpm"
(transcripts per million), "norm_tpm" (normalised TPM
values), "fpkm" (FPKM values), "norm_fpkm" (normalised FPKM
values), "counts" (counts for each feature), "norm_counts",
"cpm" (counts-per-million), "norm_cpm" (normalised
counts-per-million), "exprs" (whatever is in the 'exprs' slot
of the SCESet object; default), "norm_exprs" (normalised
expression values) or "stand_exprs" (standardised expression values)
or any other named element of the assayData slot of the SCESet
object that can be accessed with the get_exprs function.
colour_by
character string defining the column of pData(object) to
be used as a factor by which to colour the points in the plot. Alternatively,
a data frame with one column, containing values to map to colours for all cells.
shape_by
character string defining the column of pData(object) to
be used as a factor by which to define the shape of the points in the plot.
Alternatively, a data frame with one column containing values to map to shapes.
size_by
character string defining the column of pData(object) to
be used as a factor by which to define the size of points in the plot.
Alternatively, a data frame with one column containing values to map to sizes.
feature_set
character, numeric or logical vector indicating a set of
features to use for the PCA. If character, entries must all be in
featureNames(object). If numeric, values are taken to be indices for
features. If logical, vector is used to index features and should have length
equal to nrow(object).
return_SCESet
logical, should the function return an SCESet
object with principal component values for cells in the
reducedDimension slot. Default is FALSE, in which case a
ggplot object is returned.
scale_features
logical, should the expression values be standardised
so that each feature has unit variance? Default is TRUE.
draw_plot
logical, should the plot be drawn on the current graphics
device? Only used if return_SCESet is TRUE, otherwise the plot
is always produced.
pca_data_input
character argument defining which data should be used
as input for the PCA. Possible options are "exprs" (default), which
uses expression data to produce a PCA at the cell level; "pdata" which
uses numeric variables from pData(object) to do PCA at the cell level;
and "fdata" which uses numeric variables from fData(object) to
do PCA at the feature level.
selected_variables
character vector indicating which variables in
pData(object) to use for the phenotype-data based PCA. Ignored if
the argument pca_data_input is anything other than "pdata".
detect_outliers
logical, should outliers be detected in the PC plot?
Only an option when pca_data_input argument is "pdata". Default
is FALSE.
theme_size
numeric scalar giving default font size for plotting theme
(default is 10).
legend
character, specifying how the legend(s) be shown? Default is
"auto", which hides legends that have only one level and shows others.
Alternatives are "all" (show all legends) or "none" (hide all legends).
...
further arguments passed to plotPCASCESet
Details
The function prcomp is used internally to do the PCA.
The function checks whether the object has standardised
expression values (by looking at stand_exprs(object)). If yes, the
existing standardised expression values are used for the PCA. If not, then
standardised expression values are computed using scale (with
feature-wise unit variances or not according to the scale_features
argument), added to the object and PCA is done using these new standardised
expression values.
If the arguments detect_outliers and return_SCESet are both
TRUE, then the element $outlier is added to the pData
(phenotype data) slot of the SCESet object. This element contains
indicator values about whether or not each cell has been designated as an
outlier based on the PCA. These values can be accessed for filtering
low quality cells with, foe example, example_sceset$outlier.
Value
either a ggplot plot object or an SCESet object
Examples
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
## Set up an example SCESet
data("sc_example_counts")
data("sc_example_cell_info")
pd <- new("AnnotatedDataFrame", data = sc_example_cell_info)
example_sceset <- newSCESet(countData = sc_example_counts, phenoData = pd)
drop_genes <- apply(exprs(example_sceset), 1, function(x) {var(x) == 0})
example_sceset <- example_sceset[!drop_genes, ]
## Examples plotting PC1 and PC2
plotPCA(example_sceset)
plotPCA(example_sceset, colour_by = "Cell_Cycle")
plotPCA(example_sceset, colour_by = "Cell_Cycle", shape_by = "Treatment")
plotPCA(example_sceset, colour_by = "Cell_Cycle", shape_by = "Treatment",
size_by = "Mutation_Status")
plotPCA(example_sceset, shape_by = "Treatment", size_by = "Mutation_Status")
plotPCA(example_sceset, feature_set = 1:100, colour_by = "Treatment",
shape_by = "Mutation_Status")
## experiment with legend
example_subset <- example_sceset[, example_sceset$Treatment == "treat1"]
plotPCA(example_subset, colour_by = "Cell_Cycle", shape_by = "Treatment", legend = "all")
plotPCA(example_sceset, shape_by = "Treatment", return_SCESet = TRUE)
## Examples plotting more than 2 PCs
plotPCA(example_sceset, ncomponents = 8)
plotPCA(example_sceset, ncomponents = 4, colour_by = "Treatment",
shape_by = "Mutation_Status")
dynverse/scaterlegacy documentation built on Feb. 17, 2020, 5:07 a.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 Examples
Description
Produce a principal components analysis (PCA) plot of two or more principal
components for an SCESet dataset.
Usage
1 2 3 4 5 6 7 8 9 10 11 12 13 | plotPCASCESet(object, ntop = 500, ncomponents = 2, exprs_values = "exprs",
colour_by = NULL, shape_by = NULL, size_by = NULL, feature_set = NULL,
return_SCESet = FALSE, scale_features = TRUE, draw_plot = TRUE,
pca_data_input = "exprs", selected_variables = NULL,
detect_outliers = FALSE, theme_size = 10, legend = "auto")
## S4 method for signature 'SCESet'
plotPCA(object, ntop = 500, ncomponents = 2,
exprs_values = "exprs", colour_by = NULL, shape_by = NULL,
size_by = NULL, feature_set = NULL, return_SCESet = FALSE,
scale_features = TRUE, draw_plot = TRUE, pca_data_input = "exprs",
selected_variables = NULL, detect_outliers = FALSE, theme_size = 10,
legend = "auto")
|
Arguments
object |
an |
ntop |
numeric scalar indicating the number of most variable features to
use for the PCA. Default is |
ncomponents |
numeric scalar indicating the number of principal
components to plot, starting from the first principal component. Default is
2. If |
exprs_values |
character string indicating which values should be used
as the expression values for this plot. Valid arguments are |
colour_by |
character string defining the column of |
shape_by |
character string defining the column of |
size_by |
character string defining the column of |
feature_set |
character, numeric or logical vector indicating a set of
features to use for the PCA. If character, entries must all be in
|
return_SCESet |
logical, should the function return an |
scale_features |
logical, should the expression values be standardised
so that each feature has unit variance? Default is |
draw_plot |
logical, should the plot be drawn on the current graphics
device? Only used if |
pca_data_input |
character argument defining which data should be used
as input for the PCA. Possible options are |
selected_variables |
character vector indicating which variables in
|
detect_outliers |
logical, should outliers be detected in the PC plot?
Only an option when |
theme_size |
numeric scalar giving default font size for plotting theme (default is 10). |
legend |
character, specifying how the legend(s) be shown? Default is
|
... |
further arguments passed to |
Details
The function prcomp is used internally to do the PCA.
The function checks whether the object has standardised
expression values (by looking at stand_exprs(object)). If yes, the
existing standardised expression values are used for the PCA. If not, then
standardised expression values are computed using scale (with
feature-wise unit variances or not according to the scale_features
argument), added to the object and PCA is done using these new standardised
expression values.
If the arguments detect_outliers and return_SCESet are both
TRUE, then the element $outlier is added to the pData
(phenotype data) slot of the SCESet object. This element contains
indicator values about whether or not each cell has been designated as an
outlier based on the PCA. These values can be accessed for filtering
low quality cells with, foe example, example_sceset$outlier.
Value
either a ggplot plot object or an SCESet object
Examples
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 | ## Set up an example SCESet
data("sc_example_counts")
data("sc_example_cell_info")
pd <- new("AnnotatedDataFrame", data = sc_example_cell_info)
example_sceset <- newSCESet(countData = sc_example_counts, phenoData = pd)
drop_genes <- apply(exprs(example_sceset), 1, function(x) {var(x) == 0})
example_sceset <- example_sceset[!drop_genes, ]
## Examples plotting PC1 and PC2
plotPCA(example_sceset)
plotPCA(example_sceset, colour_by = "Cell_Cycle")
plotPCA(example_sceset, colour_by = "Cell_Cycle", shape_by = "Treatment")
plotPCA(example_sceset, colour_by = "Cell_Cycle", shape_by = "Treatment",
size_by = "Mutation_Status")
plotPCA(example_sceset, shape_by = "Treatment", size_by = "Mutation_Status")
plotPCA(example_sceset, feature_set = 1:100, colour_by = "Treatment",
shape_by = "Mutation_Status")
## experiment with legend
example_subset <- example_sceset[, example_sceset$Treatment == "treat1"]
plotPCA(example_subset, colour_by = "Cell_Cycle", shape_by = "Treatment", legend = "all")
plotPCA(example_sceset, shape_by = "Treatment", return_SCESet = TRUE)
## Examples plotting more than 2 PCs
plotPCA(example_sceset, ncomponents = 8)
plotPCA(example_sceset, ncomponents = 4, colour_by = "Treatment",
shape_by = "Mutation_Status")
|
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.