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R/Rphenograph.R
In cytofkit: cytofkit: an integrated mass cytometry data analysis pipeline
Defines functions
Rphenograph
find_neighbors
Documented in
Rphenograph
#' RphenoGraph clustering
#'
#' R implementation of the phenograph algorithm
#'
#' A simple R implementation of the phenograph [PhenoGraph](http://www.cell.com/cell/abstract/S0092-8674(15)00637-6) algorithm,
#' which is a clustering method designed for high-dimensional single-cell data analysis. It works by creating a graph ("network") representing
#' phenotypic similarities between cells by calculating the Jaccard coefficient between nearest-neighbor sets, and then identifying communities
#' using the well known [Louvain method](https://sites.google.com/site/findcommunities/) in this graph.
#'
#' @param data Input data matrix.
#' @param k Number of nearest neighbours, default is 30.
#'
#' @return a communities object, the operations of this class contains:
#' \item{print}{returns the communities object itself, invisibly.}
#' \item{length}{returns an integer scalar.}
#' \item{sizes}{returns a numeric vector.}
#' \item{membership}{returns a numeric vector, one number for each vertex in the graph that was the input of the community detection.}
#' \item{modularity}{returns a numeric scalar.}
#' \item{algorithm}{returns a character scalar.}
#' \item{crossing}{returns a logical vector.}
#' \item{is_hierarchical}{returns a logical scalar.}
#' \item{merges}{returns a two-column numeric matrix.}
#' \item{cut_at}{returns a numeric vector, the membership vector of the vertices.}
#' \item{as.dendrogram}{returns a dendrogram object.}
#' \item{show_trace}{returns a character vector.}
#' \item{code_len}{returns a numeric scalar for communities found with the InfoMAP method and NULL for other methods.}
#' \item{plot}{for communities objects returns NULL, invisibly.}
#'
#' @importFrom igraph graph.data.frame cluster_louvain modularity membership
#' @importFrom Rcpp sourceCpp
#'
#' @export
#'
#' @author Chen Hao
#' @references Jacob H. Levine and et.al. Data-Driven Phenotypic Dissection of AML Reveals Progenitor-like Cells that Correlate with Prognosis. Cell, 2015.
#' @examples
#' iris_unique <- unique(iris) # Remove duplicates
#' data <- as.matrix(iris_unique[,1:4])
#' Rphenograph_out <- Rphenograph(data, k = 45)
Rphenograph <- function(data, k=30){
if(is.data.frame(data))
data <- as.matrix(data)
if(!is.matrix(data))
stop("Wrong input data, should be a data frame or matrix!")
if(k<1){
stop("k must be a positive integer!")
}else if (k > nrow(data)-2){
stop("k must be smaller than the total number of points!")
}
message("Run Rphenograph starts:","\n",
" -Input data of ", nrow(data)," rows and ", ncol(data), " columns","\n",
" -k is set to ", k)
cat(" Finding nearest neighbors...")
t1 <- system.time(neighborMatrix <- find_neighbors(data, k=k+1)[,-1])
cat("DONE ~",t1[3],"s\n", " Compute jaccard coefficient between nearest-neighbor sets...")
t2 <- system.time(links <- jaccard_coeff(neighborMatrix))
cat("DONE ~",t2[3],"s\n", " Build undirected graph from the weighted links...")
links <- links[links[,1]>0, ]
relations <- as.data.frame(links)
colnames(relations)<- c("from","to","weight")
t3 <- system.time(g <- graph.data.frame(relations, directed=FALSE))
# Other community detection algorithms:
# cluster_walktrap, cluster_spinglass,
# cluster_leading_eigen, cluster_edge_betweenness,
# cluster_fast_greedy, cluster_label_prop
cat("DONE ~",t3[3],"s\n", " Run louvain clustering on the graph ...")
t4 <- system.time(community <- cluster_louvain(g))
cat("DONE ~",t4[3],"s\n")
message("Run Rphenograph DONE, took a total of ", sum(c(t1[3],t2[3],t3[3],t4[3])), "s.")
cat(" Return a community class\n -Modularity value:", modularity(community),"\n")
cat(" -Number of clusters:", length(unique(membership(community))))
return(community)
}
#' K Nearest Neighbour Search
#'
#' Uses a kd-tree to find the p number of near neighbours for each point in an input/output dataset.
#'
#' Use the nn2 function from the RANN package, utilizes the Approximate Near Neighbor (ANN) C++ library,
#' which can give the exact near neighbours or (as the name suggests) approximate near neighbours
#' to within a specified error bound. For more information on the ANN library please
#' visit http://www.cs.umd.edu/~mount/ANN/.
#'
#' @param data Input data matrix.
#' @param k Number of nearest neighbours.
#'
#' @return a n-by-k matrix of neighbor indices
#'
#' @noRd
#'
#' @importFrom RANN nn2
find_neighbors <- function(data, k){
nearest <- nn2(data, data, k, treetype = "kd", searchtype = "standard")
return(nearest[[1]])
}
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Defines functions Rphenograph find_neighbors
Documented in Rphenograph
#' RphenoGraph clustering
#'
#' R implementation of the phenograph algorithm
#'
#' A simple R implementation of the phenograph [PhenoGraph](http://www.cell.com/cell/abstract/S0092-8674(15)00637-6) algorithm,
#' which is a clustering method designed for high-dimensional single-cell data analysis. It works by creating a graph ("network") representing
#' phenotypic similarities between cells by calculating the Jaccard coefficient between nearest-neighbor sets, and then identifying communities
#' using the well known [Louvain method](https://sites.google.com/site/findcommunities/) in this graph.
#'
#' @param data Input data matrix.
#' @param k Number of nearest neighbours, default is 30.
#'
#' @return a communities object, the operations of this class contains:
#' \item{print}{returns the communities object itself, invisibly.}
#' \item{length}{returns an integer scalar.}
#' \item{sizes}{returns a numeric vector.}
#' \item{membership}{returns a numeric vector, one number for each vertex in the graph that was the input of the community detection.}
#' \item{modularity}{returns a numeric scalar.}
#' \item{algorithm}{returns a character scalar.}
#' \item{crossing}{returns a logical vector.}
#' \item{is_hierarchical}{returns a logical scalar.}
#' \item{merges}{returns a two-column numeric matrix.}
#' \item{cut_at}{returns a numeric vector, the membership vector of the vertices.}
#' \item{as.dendrogram}{returns a dendrogram object.}
#' \item{show_trace}{returns a character vector.}
#' \item{code_len}{returns a numeric scalar for communities found with the InfoMAP method and NULL for other methods.}
#' \item{plot}{for communities objects returns NULL, invisibly.}
#'
#' @importFrom igraph graph.data.frame cluster_louvain modularity membership
#' @importFrom Rcpp sourceCpp
#'
#' @export
#'
#' @author Chen Hao
#' @references Jacob H. Levine and et.al. Data-Driven Phenotypic Dissection of AML Reveals Progenitor-like Cells that Correlate with Prognosis. Cell, 2015.
#' @examples
#' iris_unique <- unique(iris) # Remove duplicates
#' data <- as.matrix(iris_unique[,1:4])
#' Rphenograph_out <- Rphenograph(data, k = 45)
Rphenograph <- function(data, k=30){
if(is.data.frame(data))
data <- as.matrix(data)
if(!is.matrix(data))
stop("Wrong input data, should be a data frame or matrix!")
if(k<1){
stop("k must be a positive integer!")
}else if (k > nrow(data)-2){
stop("k must be smaller than the total number of points!")
}
message("Run Rphenograph starts:","\n",
" -Input data of ", nrow(data)," rows and ", ncol(data), " columns","\n",
" -k is set to ", k)
cat(" Finding nearest neighbors...")
t1 <- system.time(neighborMatrix <- find_neighbors(data, k=k+1)[,-1])
cat("DONE ~",t1[3],"s\n", " Compute jaccard coefficient between nearest-neighbor sets...")
t2 <- system.time(links <- jaccard_coeff(neighborMatrix))
cat("DONE ~",t2[3],"s\n", " Build undirected graph from the weighted links...")
links <- links[links[,1]>0, ]
relations <- as.data.frame(links)
colnames(relations)<- c("from","to","weight")
t3 <- system.time(g <- graph.data.frame(relations, directed=FALSE))
# Other community detection algorithms:
# cluster_walktrap, cluster_spinglass,
# cluster_leading_eigen, cluster_edge_betweenness,
# cluster_fast_greedy, cluster_label_prop
cat("DONE ~",t3[3],"s\n", " Run louvain clustering on the graph ...")
t4 <- system.time(community <- cluster_louvain(g))
cat("DONE ~",t4[3],"s\n")
message("Run Rphenograph DONE, took a total of ", sum(c(t1[3],t2[3],t3[3],t4[3])), "s.")
cat(" Return a community class\n -Modularity value:", modularity(community),"\n")
cat(" -Number of clusters:", length(unique(membership(community))))
return(community)
}
#' K Nearest Neighbour Search
#'
#' Uses a kd-tree to find the p number of near neighbours for each point in an input/output dataset.
#'
#' Use the nn2 function from the RANN package, utilizes the Approximate Near Neighbor (ANN) C++ library,
#' which can give the exact near neighbours or (as the name suggests) approximate near neighbours
#' to within a specified error bound. For more information on the ANN library please
#' visit http://www.cs.umd.edu/~mount/ANN/.
#'
#' @param data Input data matrix.
#' @param k Number of nearest neighbours.
#'
#' @return a n-by-k matrix of neighbor indices
#'
#' @noRd
#'
#' @importFrom RANN nn2
find_neighbors <- function(data, k){
nearest <- nn2(data, data, k, treetype = "kd", searchtype = "standard")
return(nearest[[1]])
}
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