Demonstration of latrend package

Niek Den Teuling

2021-01-05

This vignette describes the core functionality of the package by identifying common trends in the longitudinal dataset that is included with the package. We begin by loading the required package and the latrendData dataset.

library(latrend)
library(ggplot2)

Initial data exploration

The latrendData is a synthetic dataset for which the reference group of each trajectory is available, as indicated by the Class column. We will use this column at the end of this vignette to validate the identified model.

data(latrendData)
head(latrendData)
#>   Id      Time           Y   Class
#> 1  1 0.0000000 -1.08049205 Class 1
#> 2  1 0.2222222 -0.68024151 Class 1
#> 3  1 0.4444444 -0.65148373 Class 1
#> 4  1 0.6666667 -0.39115398 Class 1
#> 5  1 0.8888889 -0.19407876 Class 1
#> 6  1 1.1111111 -0.02991783 Class 1

Many of the functions of the package require the specification of the trajectory identifier variable (named Id) and the time variable (named Time). For convenience, we specify these variables as package options.

options(latrend.id = "Id", latrend.time = "Time")

Prior to attempting to model the data, it is worthwhile to visually inspect it.

plotTrajectories(latrendData, response = "Y")

Visualizing the trajectories of the latrend dataset.

Visualizing the trajectories of the `latrend` dataset.

The presence of clusters is not apparent from the plot. With any longitudinal analysis, one should first consider whether clustering brings any benefit to the representation of heterogeneity of the data over a single common trend representation, or a multilevel model. In this demonstration, we omit this step under the prior knowledge that the data was generated via distinct mechanisms.

Non-parametric trajectory clustering

Assuming the appropriate (cluster) trajectory model is not known in advance, non-parametric longitudinal cluster models can provide a suitable starting point.

As an example, we apply longitudinal \(k\)-means (KML). First, we need to define the method. At the very least we need to indicate the response variable the method should operate on. Secondly, we should indicate how many clusters we expect. We do not need to define the id and time arguments as we have set these as package options. We use the nbRedrawing argument provided by the KML package for reducing the number of repeated random starts to only a single model estimation, in order to reduce the run-time of this example.

kmlMethod <- lcMethodKML(response = "Y", nClusters = 2, nbRedrawing = 1)

kmlMethod
#> lcMethodKML specifying "longitudinal k-means (KML)"
#>  time:           getOption("latrend.time")
#>  id:             getOption("latrend.id")
#>  nClusters:      2
#>  nbRedrawing:    1
#>  maxIt:          200
#>  imputationMethod:"copyMean"
#>  distanceName:   "euclidean"
#>  power:          2
#>  distance:       function() {}
#>  centerMethod:   meanNA
#>  startingCond:   "nearlyAll"
#>  nbCriterion:    1000
#>  scale:          TRUE
#>  response:       "Y"

As seen in the output from the lcMethodKML object, the KML method is defined by additional arguments. These are specific to the kml package.

The KML model is estimated on the dataset via the latrend function.

kmlModel <- latrend(kmlMethod, data = latrendData)
#>  ~ Fast KmL ~
#> *

Now that we have fitted the KML model with 2 clusters, we can print a summary by calling:

kmlModel
#> Longitudinal cluster model using longitudinal k-means (KML)
#> lcMethodKML specifying "longitudinal k-means (KML)"
#>  time:           "Time"
#>  id:             "Id"
#>  nClusters:      2
#>  nbRedrawing:    1
#>  maxIt:          200
#>  imputationMethod:"copyMean"
#>  distanceName:   "euclidean"
#>  power:          2
#>  distance:       function () {}
#>  centerMethod:   `meanNA`
#>  startingCond:   "nearlyAll"
#>  nbCriterion:    1000
#>  scale:          TRUE
#>  response:       "Y"
#> 
#> Cluster sizes (K=2):
#>         A         B 
#> 120 (60%)  80 (40%) 
#> 
#> Number of obs: 2000, strata (Id): 200
#> 
#> Scaled residuals:
#>     Min.  1st Qu.   Median     Mean  3rd Qu.     Max. 
#> -3.57615 -0.62971  0.05638  0.00000  0.65400  3.20251

Identifying the number of clusters

As we do not know the best number of clusters needed to represent the data, we should consider fitting the KML model for a range of clusters. We can then select the best representation by comparing the solutions by one or more cluster metrics.

We can specify a range of lcMethodKML methods based on a prototype method using the lcMethods function. This method outputs a list of lcMethod objects. A structured summary is obtained by calling as.data.frame.

kmlMethods <- lcMethods(kmlMethod, nClusters = 1:7)

as.data.frame(kmlMethods)
#>        .class time id nClusters nbRedrawing maxIt imputationMethod distanceName
#> 1 lcMethodKML Time Id         1           1   200         copyMean    euclidean
#> 2 lcMethodKML Time Id         2           1   200         copyMean    euclidean
#> 3 lcMethodKML Time Id         3           1   200         copyMean    euclidean
#> 4 lcMethodKML Time Id         4           1   200         copyMean    euclidean
#> 5 lcMethodKML Time Id         5           1   200         copyMean    euclidean
#> 6 lcMethodKML Time Id         6           1   200         copyMean    euclidean
#> 7 lcMethodKML Time Id         7           1   200         copyMean    euclidean
#>   power      distance centerMethod startingCond nbCriterion scale response
#> 1     2 function() {}       meanNA    nearlyAll        1000  TRUE        Y
#> 2     2 function() {}       meanNA    nearlyAll        1000  TRUE        Y
#> 3     2 function() {}       meanNA    nearlyAll        1000  TRUE        Y
#> 4     2 function() {}       meanNA    nearlyAll        1000  TRUE        Y
#> 5     2 function() {}       meanNA    nearlyAll        1000  TRUE        Y
#> 6     2 function() {}       meanNA    nearlyAll        1000  TRUE        Y
#> 7     2 function() {}       meanNA    nearlyAll        1000  TRUE        Y

The list of lcMethod objects can be fitted using the latrendBatch function, returning a list of lcModel objects.

kmlModels <- latrendBatch(kmlMethods, data = latrendData, verbose = FALSE)

kmlModels
#> List of 7 lcModels with
#>   .name .method       seed nClusters
#> 1     1     kml 1753232290         1
#> 2     2     kml 1711075799         2
#> 3     3     kml  690659598         3
#> 4     4     kml  265368763         4
#> 5     5     kml  758296545         5
#> 6     6     kml 1649722645         6
#> 7     7     kml 2137634742         7

We can compare each of the solutions via one or more cluster metrics. Considering the consistent improvements achieved by KML for an increasing number of clusters, identifying the best solution by minimizing a metric would lead to an overestimation. Instead, we perform the selection via a manual elbow method, using the plotMetric function.

plotMetric(kmlModels, c("logLik", "BIC", "WMAE"))

Elbow plots of three relevant cluster metrics across the fitted models.

Elbow plots of three relevant cluster metrics across the fitted models.

Investigating the preferred model

We have selected the 4-cluster model as the preferred representation. We will now inspect this solution in more detail. Before we can start, we first obtain the fitted lcModel object from the list of fitted models.

kmlModel4 <- subset(kmlModels, nClusters == 4, drop = TRUE)

kmlModel4
#> Longitudinal cluster model using longitudinal k-means (KML)
#> lcMethodKML specifying "longitudinal k-means (KML)"
#>  seed:           265368763
#>  time:           "Time"
#>  id:             "Id"
#>  nClusters:      4
#>  nbRedrawing:    1
#>  maxIt:          200
#>  imputationMethod:"copyMean"
#>  distanceName:   "euclidean"
#>  power:          2
#>  distance:       function () {}
#>  centerMethod:   `meanNA`
#>  startingCond:   "nearlyAll"
#>  nbCriterion:    1000
#>  scale:          TRUE
#>  response:       "Y"
#> 
#> Cluster sizes (K=4):
#>          A          B          C          D 
#>   70 (35%)   50 (25%) 45 (22.5%) 35 (17.5%) 
#> 
#> Number of obs: 2000, strata (Id): 200
#> 
#> Scaled residuals:
#>     Min.  1st Qu.   Median     Mean  3rd Qu.     Max. 
#> -3.22269 -0.61623 -0.05837  0.00000  0.62240  3.63398

The plotClusterTrajectories function shows the estimated cluster trajectories of the model.

plotClusterTrajectories(kmlModel4)

Cluster trajectories for KML model with 4 clusters.

Cluster trajectories for KML model with 4 clusters.

We can get a better sense of the representation of the cluster trajectories when plotted against the trajectories that have been assigned to the respective cluster.

plot(kmlModel4)

Cluster trajectories for KML model with 4 clusters, along with the assigned trajectories.

Cluster trajectories for KML model with 4 clusters, along with the assigned trajectories.

Model adequacy

The list of currently supported internal model metrics can be obtained by calling the getInternalMetricNames function.

getInternalMetricNames()
#>  [1] "AIC"              "APPA.mean"        "APPA.min"         "ASW"             
#>  [5] "BIC"              "CAIC"             "CLC"              "CalinskiHarabasz"
#>  [9] "DaviesBouldin"    "Dunn"             "ED"               "ED.fit"          
#> [13] "ICL.BIC"          "MAE"              "MSE"              "Mahalanobis"     
#> [17] "RE"               "RMSE"             "RSS"              "SED"             
#> [21] "SED.fit"          "WMAE"             "WMSE"             "WRMSE"           
#> [25] "WRSS"             "converged"        "deviance"         "entropy"         
#> [29] "estimationTime"   "logLik"           "relativeEntropy"  "scaledEntropy"   
#> [33] "sigma"            "ssBIC"

As an example, we will compute the APPA (a measure of cluster separation), and the WRSS and WMAE metrics (measures of model error).

metric(kmlModel, c("APPA.mean", "WRSS", "WMAE"))
#>   APPA.mean        WRSS        WMAE 
#>   0.9999979 152.7557738   0.2158131

The quantile-quantile (QQ) plot can be used to assess the model for structural deviations.

qqPlot(kmlModel4)
#> Loading required namespace: qqplotr

QQ-plot of the selected KML model.

QQ-plot of the selected KML model.

Overall, the unexplained errors closely follow a normal distribution. In situations where structural deviations from the expected distribution are apparent, it may be fruitful to investigate the QQ plot on a per-cluster basis.

qqPlot(kmlModel4, byCluster = TRUE, detrend = TRUE)

Cluster-specific detrended QQ-plot for the selected KML model.

Cluster-specific detrended QQ-plot for the selected KML model.

Parametric trajectory clustering

The KML analysis has provided us with clues on an appropriate model for the cluster trajectories. We can use these insights to define a parametric representation of each of the trajectories and cluster them using k-means.

lmkmMethod <- lcMethodLMKM(formula = Y ~ Time)

lmkmMethod
#> lcMethodLMKM specifying "lm-kmeans"
#>  time:           getOption("latrend.time")
#>  id:             getOption("latrend.id")
#>  nClusters:      2
#>  center:         meanNA
#>  standardize:    scale
#>  method:         "qr"
#>  model:          TRUE
#>  y:              FALSE
#>  qr:             TRUE
#>  singular.ok:    TRUE
#>  contrasts:      NULL
#>  iter.max:       10
#>  nstart:         1
#>  algorithm:      c("Hartigan-Wong", "Lloyd", "Forgy", "Ma
#>  formula:        Y ~ Time

We fit LMKM for 1 to 4 clusters.

lmkmMethods <- lcMethods(lmkmMethod, nClusters = 1:5)

lmkmModels <- latrendBatch(lmkmMethods, data = latrendData, verbose = FALSE)
plotMetric(lmkmModels, c("logLik", "BIC", "WMAE"))

Three cluster metrics for each of the GBTMs.

Three cluster metrics for each of the GBTMs.

All metrics clearly point to the three-cluster solution.

bestLmkmModel <- subset(lmkmModels, nClusters == 3, drop=TRUE)
plot(bestLmkmModel)

Comparison to the reference

Since we have established a preferred clustered representation of the data heterogeneity, we can now compare the resulting cluster assignments to the ground truth from which the latrendData data was generated.

Using the reference assignments, we can also plot a non-parametric estimate of the cluster trajectories. Note how it looks similar to the cluster trajectories found by our model.

plotClusterTrajectories(latrendData, response = "Y", cluster = "Class")

Non-parametric estimates of the cluster trajectories based on the reference assignments.

Non-parametric estimates of the cluster trajectories based on the reference assignments.

In order to compare the reference assignments to the trajectory assignments generated by our model, we can create a lcModel object based on the reference assignments using the lcModelPartition function.

refTrajAssigns <- aggregate(Class ~ Id, data = latrendData, FUN = data.table::first)
refModel <- lcModelPartition(data = latrendData, response = "Y", trajectoryAssignments = refTrajAssigns$Class)
refModel
#> Longitudinal cluster model using part
#> lcMethod specifying "undefined"
#> no arguments
#> 
#> Cluster sizes (K=3):
#>  Class 1  Class 2  Class 3 
#> 80 (40%) 70 (35%) 50 (25%) 
#> 
#> Number of obs: 2000, strata (Id): 200
#> 
#> Scaled residuals:
#>     Min.  1st Qu.   Median     Mean  3rd Qu.     Max. 
#> -3.67125 -0.55452 -0.04079  0.00000  0.58663  3.76931
plot(refModel)

Cluster trajectories of the reference model.

Cluster trajectories of the reference model.

By constructing a reference model, we can make use of the standardized way in which lcModel objects can be compared. A list of supported comparison metrics can be obtained via the getExternalMetricNames function.

getExternalMetricNames()
#>  [1] "CohensKappa"    "F"              "F1"             "FolkesMallows" 
#>  [5] "Hubert"         "Jaccard"        "Kulczynski"     "MI"            
#>  [9] "MaximumMatch"   "McNemar"        "MeilaHeckerman" "Mirkin"        
#> [13] "NMI"            "NSJ"            "NVI"            "Overlap"       
#> [17] "PD"             "Phi"            "Rand"           "RogersTanimoto"
#> [21] "RusselRao"      "SMC"            "SokalSneath1"   "SokalSneath2"  
#> [25] "VI"             "WMMAE"          "WMMAE.ref"      "WMMSE"         
#> [29] "WMMSE.ref"      "WMRSS"          "WMRSS.ref"      "Wallace1"      
#> [33] "Wallace2"       "adjustedRand"   "jointEntropy"   "precision"     
#> [37] "recall"         "splitJoin"      "splitJoin.ref"

Lastly, we compare the agreement in trajectory assignments via the adjusted Rand index.

externalMetric(bestLmkmModel, refModel, "adjustedRand")
#> adjustedRand 
#>    0.9669189

With a score of externalMetric(bestLmkmModel, refModel, "adjustedRand"), we have a near-perfect match. This result is expected, as the dataset was generated using a growth mixture model.