The hardware and bandwidth for this mirror is donated by METANET, the Webhosting and Full Service-Cloud Provider.
If you wish to report a bug, or if you are interested in having us mirror your free-software or open-source project, please feel free to contact us at mirror[@]metanet.ch.

Fujita2023_analysis

Introduction

In this vignette we examine and model the Fujita2023 data in more detail.

library(parafac4microbiome)
library(dplyr)
#> 
#> Attaching package: 'dplyr'
#> The following objects are masked from 'package:stats':
#> 
#>     filter, lag
#> The following objects are masked from 'package:base':
#> 
#>     intersect, setdiff, setequal, union
library(ggplot2)
library(ggpubr)

Processing the data cube

The data cube in Fujita2023$data contains unprocessed counts. The function processDataCube() performs the processing of these counts with the following steps:

The outcome of processing is a new version of the dataset. Please refer to the documentation of processDataCube() for more information.

processedFujita = processDataCube(Fujita2023, sparsityThreshold=0.99, CLR=TRUE, centerMode=1, scaleMode=2)

Determining the correct number of components

A critical aspect of PARAFAC modelling is to determine the correct number of components. We have developed the functions assessModelQuality() and assessModelStability() for this purpose. First, we will assess the model quality and specify the minimum and maximum number of components to investigate and the number of randomly initialized models to try for each number of components.

Note: this vignette reflects a minimum working example for analyzing this dataset due to computational limitations in automatic vignette rendering. Hence, we only look at 1-3 components with 5 random initializations each. These settings are not ideal for real datasets. Please refer to the documentation of assessModelQuality() for more information.

# Setup
minNumComponents = 1
maxNumComponents = 3
numRepetitions = 5 # number of randomly initialized models
numFolds = 8 # number of jack-knifed models
ctol = 1e-6
maxit = 200
numCores= 1

# Plot settings
colourCols = c("", "Genus", "")
legendTitles = c("", "Genus", "")
xLabels = c("Replicate", "Feature index", "Time point")
legendColNums = c(0,5,0)
arrangeModes = c(FALSE, TRUE, FALSE)
continuousModes = c(FALSE,FALSE,TRUE)

# Assess the metrics to determine the correct number of components
qualityAssessment = assessModelQuality(processedFujita$data, minNumComponents, maxNumComponents, numRepetitions, ctol=ctol, maxit=maxit, numCores=numCores)

We will now inspect the output plots of interest for Fujita2023.

qualityAssessment$plots$overview

The overview plots show that we can reach ~40% explained variation if we take 3 components. The CORCONDIA for those models are ~98, which is well above the minimum requirement of 60. Based on this overview, either 2 or 3 components seems fine.

Jack-knifed models

Next, we investigate the stability of the models when jack-knifing out samples using assessModelStability(). This will give us more information to choose between 2 or 3 components.

stabilityAssessment = assessModelStability(processedFujita, minNumComponents=1, maxNumComponents=3, numFolds=numFolds, considerGroups=FALSE,
                                           groupVariable="", colourCols, legendTitles, xLabels, legendColNums, arrangeModes,
                                           ctol=ctol, maxit=maxit, numCores=numCores)
stabilityAssessment$modelPlots[[1]]

stabilityAssessment$modelPlots[[2]]

stabilityAssessment$modelPlots[[3]]

The three-component model is stable and can be safely chosen as the final model.

Model selection

We have decided that a three-component model is the most appropriate for the Fujita2023 dataset. We can now select one of the random initializations from the assessModelQuality() output as our final model. We’re going to select the random initialization that corresponded the maximum amount of variation explained for three components.

numComponents = 3
modelChoice = which(qualityAssessment$metrics$varExp[,numComponents] == max(qualityAssessment$metrics$varExp[,numComponents]))
finalModel = qualityAssessment$models[[numComponents]][[modelChoice]]

Finally, we visualize the model using plotPARAFACmodel().

plotPARAFACmodel(finalModel$Fac, processedFujita, 3, colourCols, legendTitles, xLabels, legendColNums, arrangeModes,
  continuousModes = c(FALSE,FALSE,TRUE),
  overallTitle = "Fujita PARAFAC model")

You will observe that the loadings for some modes in some components are negative. This is due to sign flipping: two modes having negative loadings cancel out but describe the same subspace as two positive loadings. We can manually sign flip these loadings to obtain a more interpretable plot.

finalModel$Fac[[1]][,2] = -1 * finalModel$Fac[[1]][,2] # mode 1 component 2
finalModel$Fac[[1]][,3] = -1 * finalModel$Fac[[1]][,3] # mode 1 component 3
finalModel$Fac[[2]][,3] = -1 * finalModel$Fac[[2]][,3] # mode 2 component 3
finalModel$Fac[[3]][,2] = -1 * finalModel$Fac[[3]][,2] # mode 3 component 2

plotPARAFACmodel(finalModel$Fac, processedFujita, 3, colourCols, legendTitles, xLabels, legendColNums, arrangeModes,
  continuousModes = c(FALSE,FALSE,TRUE),
  overallTitle = "Fujita PARAFAC model")

These binaries (installable software) and packages are in development.
They may not be fully stable and should be used with caution. We make no claims about them.