The geneUsageAnalysis function deploys several
data analysis methods, including PCA, multidimensional scaling,
Jensen-Shannon divergence, k-means, hierarchical clustering, DBscan, and different
correlation coefficients.
geneUsageAnalysis(
.data,
.method = c("js+hclust", "pca+kmeans", "anova", "js+pca+kmeans"),
.base = 2,
.norm.entropy = FALSE,
.cor = c("pearson", "kendall", "spearman"),
.do.norm = TRUE,
.laplace = 1e-12,
.verbose = TRUE,
.k = 2,
.eps = 0.01,
.perp = 1,
.theta = 0.1
)Depends on the last element in the .method string. See immunr_tsne for more info.
The geneUsageAnalysis function runs on the output from
geneUsage.
A string that defines the type of analysis to perform. Can be "pca",
"mds", "js", "kmeans", "hclust", "dbscan" or "cor" if you want to calculate
correlation coefficient. In the latter case you have to provide .cor argument.
A numerical value that defines the logarithm base for Jensen-Shannon divergence.
A logical value. Set TRUE to normalise your data if you haven't done it already.
A string that defines the correlation coefficient for analysis. Can be "pearson", "kendall" or "spearman".
A logical value. If TRUE it forces Laplace smoothing, if NA it checks if smoothing is necessary, if FALSE does nothing.
The numeric value, which is used as a pseudocount for Laplace smoothing.
A logical value.
The number of clusters to create, passed as k to hcut or as centers to kmeans.
A numerical value, DBscan epsylon parameter, see
immunr_dbscan.
A numerical value, t-SNE perplexity, see immunr_tsne.
A numerical value, t-SNE theta parameter, see immunr_tsne.
data(immdata)
gu <- geneUsage(immdata$data, .norm = TRUE)
geneUsageAnalysis(gu, "js+hclust", .verbose = FALSE) %>% vis()
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