Rancovr: Cluster detection in R with Random Neighbourhood Covering

rancovr is a statistical software package written in R for disease cluster and anomaly detection. It implements the Random Neighbourhood Covering (RaNCover) approach of reference [1]. RaNCover assigns a score w ∈ [0, 1] to each records. A high score suggests that the record is likely to be part of a cluster (e.g., it is an infection case caused by a local outbreak), while a low score suggests that the record is consistent with a baseline of sporadic cases.

install.packages("devtools")
devtools::install_github("mcavallaro/rancovr")

As a demonstration, we consider the spatio-temporal coordinates in Data/synthetic_dataset.csv. The entries of this data set represent (simulated) locations and detection dates of infected patients generated by an endemic disease (end.) and cases due to a local outbreak (epi.) in England. See also reference [1] for the simulation details.

data("simulation_data")
head(simulation_data)

##   postcode week population  sim type latitude  longitude Postcode Total
## 1  AL100AZ   59         67 epi.    1 51.76421 -0.2309368  AL100AZ    67
## 2  AL100AZ   41         67 epi.    2 51.76421 -0.2309368  AL100AZ    67
## 3  AL100AZ   51         67 epi.    2 51.76421 -0.2309368  AL100AZ    67
## 4  AL100DR   50         64 epi.    1 51.76370 -0.2360576  AL100DR    64
## 5  AL100DR   47         64 epi.    1 51.76370 -0.2360576  AL100DR    64
## 6  AL100DR   51         64 epi.    1 51.76370 -0.2360576  AL100DR    64
##          y         x
## 1 5756.180 -8.074648
## 2 5756.180 -8.074648
## 3 5756.180 -8.074648
## 4 5756.123 -8.254003
## 5 5756.123 -8.254003
## 6 5756.123 -8.254003

data("GB_region_boundaries")
plotBaseMap(add=F, xlim=range(simulation_data$longitude), ylim=range(simulation_data$latitude))
points(simulation_data$longitude, simulation_data$latitude,
       col=ifelse(simulation_data$sim=='epi.', tab.red, tab.blue),
       pch=ifelse(simulation_data$sim=='epi.', 1, 20),
       cex=ifelse(simulation_data$sim=='epi.', 0.6, 0.2))
legend('topright',c('end.','epi.'), pch=c(20,1), col=c(tab.blue, tab.red))

For convenience, all observations are arranged in a sparseMatrix object named observation.matrix and saved on disk.

CreateObservationMatrices(simulation_data)

## The variable `observation.matrix` has been saved on disk in file `/home/massimo/Documents/rancovr/observation_matrix.RData`.
## Load on memory with `load("/home/massimo/Documents/rancovr/observation_matrix.RData", verbose=1)`.

Observations must be compared with an appropriate baseline model. If the numbers of these observations significantly exceeded the model prediction, an outbreak might be occurring. Estimating the baseline involves finding a temporal trend (using the function TimeFactor) and a spatial trend based on the spatial population distribution.

load(file.path(getwd(), "observation_matrix.RData"), verbose=1)

## Loading objects:
##   observation.matrix

time.factor = TimeFactor(simulation_data, n.iterations=5)

## Computing the temporal baseline.
## Estimating parameters for temporal trend, step  1  of  5 .Estimating parameters for temporal trend, step  2  of  5 .Estimating parameters for temporal trend, step  3  of  5 .Estimating parameters for temporal trend, step  4  of  5 .Estimating parameters for temporal trend, step  5  of  5 .The variable `Parameters` has been saved on disk in file `/home/massimo/Documents/rancovr/timefactor_parameters.RData`.
## Load on memory with `load("/home/massimo/Documents/rancovr/timefactor_parameters.RData", verbose=1)`.
## The variable `time.factor` has been saved on disk in file `/home/massimo/Documents/rancovr/timefactor.RData`.
## Load on memory with `load("/home/massimo/Documents/rancovr/timefactor.RData", verbose=1)`.

baseline.matrix = CreateBaselineMatrix(simulation_data, save.on.dir = T)

## Temporal baseline loaded.
## Compiling the table that maps the rows of the observation/baseline matrix to geo-coordinates and population.
## Loading objects:
##   postcode2coord

## Warning in as.character(postcode2coord[, postcode.field]) == rownames(matrix):
## longer object length is not a multiple of shorter object length

## Data loaded from `postcode2coord.RData` is for a different matrix and will be overwritten by the map for the current matrix.
## The variable `postcode2coord` has been saved on disk in file `/home/massimo/Documents/rancovr/postcode2coord.RData`.
## Load on memory with `load("/home/massimo/Documents/rancovr/postcode2coord.RData", verbose=1)`.
## The variable `baseline.matrix` has been saved on disk in file `/home/massimo/Documents/rancovr/baseline_matrix.RData`.
## Load on memory with `load("/home/massimo/Documents/rancovr/baseline_matrix.RData", verbose=1)`.

load(file.path(getwd(), "observation_matrix.RData"), verbose=1)

## Loading objects:
##   observation.matrix

plot(time.factor, xlab = 'Week', ylab='Number of cases', xaxt='n')
# lines(colSums(baseline.matrix))
points(Matrix::colSums(observation.matrix), pch='+')
axis(side=1, at=1:length(time.factor), labels = names(time.factor))
legend('bottomright',legend=c('Baseline', 'Observations'), pch=c('o', '+'))

Create 100,000 cylinders to cover the observed cases using the estimated baseline.

cylinders = CreateCylinders(observation.matrix, baseline.matrix, week.range = c(0,99), n.cylinders = 100000)

## Compiling the table that maps the rows of the observation/baseline matrix to geo-coordinates and population.
## Loading objects:
##   postcode2coord
## Using data loaded from `postcode2coord.RData`
## Time difference of 2.711282 mins

head(cylinders)

##             x        y      rho t.low t.upp n_obs         mu        p.val
## 1  -67.146412 5769.807 8.163869    73    86     4  1.4463302 5.908811e-02
## 2  -48.661207 5657.672 6.752909    16    35     6  4.9730974 3.793189e-01
## 3   -6.483721 5755.764 8.497225    45    57    52  7.1205952 2.478737e-27
## 4    4.666002 5739.594 8.497225    51    63    30 28.9189980 4.448458e-01
## 5  -82.407466 6106.174 9.811750    11    20     1  0.8217982 5.603596e-01
## 6 -202.852164 5593.081 8.497225    51    63     4  1.4597384 6.069135e-02
##   warning
## 1   FALSE
## 2   FALSE
## 3    TRUE
## 4   FALSE
## 5   FALSE
## 6   FALSE

Some cylinders contain much more cases than the baseline predicts. These cylinders cover epidemic (outbreak) events.

plotCylindersCI(cylinders, confidence.level = 0.95)

The “true” baseline matrix used to generate the endemic events is available as data(). Let’s use it in place of the estimated baseline matrix. Notice that the true baseline matrix has higher dimensionality than the estimated baseline matrix (it includes entries for more postcodes and times) and requires a matching observation matrix.

print(dim(baseline.matrix))

## [1] 3446  101

print(dim(observation.matrix))

## [1] 3446  101

data(baseline_for_sim)
print(dim(baseline_for_sim))

## [1] 10000   101

CreateObservationMatrices(simulation_data,
                          more.postcodes=rownames(baseline_for_sim),
                          more.weeks=colnames(baseline_for_sim))

## Warning in unlist(as.integer(more.weeks)): NAs introduced by coercion

## Warning in unlist(as.integer(more.weeks)): NAs introduced by coercion

## The variable `observation.matrix` has been saved on disk in file `/home/massimo/Documents/rancovr/observation_matrix.RData`.
## Load on memory with `load("/home/massimo/Documents/rancovr/observation_matrix.RData", verbose=1)`.

load("/home/massimo/Documents/rancovr/observation_matrix.RData", verbose=1)

## Loading objects:
##   observation.matrix

print(dim(observation.matrix))

## [1] 10000   101

cylinders.2 = CreateCylinders(observation.matrix, baseline_for_sim, week.range = c(0,99), n.cylinders = 100000)

## Compiling the table that maps the rows of the observation/baseline matrix to geo-coordinates and population.
## Loading objects:
##   postcode2coord

## Warning in as.character(postcode2coord[, postcode.field]) == rownames(matrix):
## longer object length is not a multiple of shorter object length

## Data loaded from `postcode2coord.RData` is for a different matrix and will be overwritten by the map for the current matrix.
## The variable `postcode2coord` has been saved on disk in file `/home/massimo/Documents/rancovr/postcode2coord.RData`.
## Load on memory with `load("/home/massimo/Documents/rancovr/postcode2coord.RData", verbose=1)`.
## Time difference of 4.289573 mins

head(cylinders.2)

##             x        y      rho t.low t.upp n_obs        mu       p.val warning
## 1    6.678267 5739.376 11.57249    61    80    69 50.048042 0.006371698    TRUE
## 2  -61.256464 5990.645 29.12347    13    16    18 14.994925 0.250711342   FALSE
## 3  -39.164635 5993.963 14.56173    34    46     9  7.299818 0.310751009   FALSE
## 4  -80.617268 5957.438 15.20923    88    99    14 15.389119 0.672984536   FALSE
## 5  -53.665732 5691.094 17.83441    14    22     3  2.850717 0.542547486   FALSE
## 6 -139.710085 5747.082 10.29670    57    81     8  8.312945 0.589804564   FALSE

plotCylindersCI(cylinders.2, confidence.level = 0.95)

Compute the warning scores for each case:

simulation_data[,'warning.score'] = apply(simulation_data, 1, FUN=warning.score, cylinders)
simulation_data[,'warning.score.2'] = apply(simulation_data, 1, FUN=warning.score, cylinders.2)
head(simulation_data)

##   postcode week population  sim type latitude  longitude Postcode Total
## 1  AL100AZ   59         67 epi.    1 51.76421 -0.2309368  AL100AZ    67
## 2  AL100AZ   41         67 epi.    2 51.76421 -0.2309368  AL100AZ    67
## 3  AL100AZ   51         67 epi.    2 51.76421 -0.2309368  AL100AZ    67
## 4  AL100DR   50         64 epi.    1 51.76370 -0.2360576  AL100DR    64
## 5  AL100DR   47         64 epi.    1 51.76370 -0.2360576  AL100DR    64
## 6  AL100DR   51         64 epi.    1 51.76370 -0.2360576  AL100DR    64
##          y         x warning.score warning.score.2
## 1 5756.180 -8.074648     0.8711019       0.8396465
## 2 5756.180 -8.074648     0.8900256       0.7675676
## 3 5756.180 -8.074648     0.9727149       0.9410526
## 4 5756.123 -8.254003     0.9842932       0.9739312
## 5 5756.123 -8.254003     0.9815603       0.9662542
## 6 5756.123 -8.254003     0.9744280       0.9413613

Assess concordance with ROC-AUC:

library(pROC)

## Type 'citation("pROC")' for a citation.

## 
## Attaching package: 'pROC'

## The following objects are masked from 'package:stats':
## 
##     cov, smooth, var

ROC = roc(ifelse(simulation_data$sim == 'end.', FALSE, TRUE), simulation_data$warning.score)

## Setting levels: control = FALSE, case = TRUE

## Setting direction: controls < cases

plot(ROC)
print(ROC$auc)

## Area under the curve: 0.9993

ROC = roc(ifelse(simulation_data$sim == 'end.', FALSE, TRUE), simulation_data$warning.score.2)

## Setting levels: control = FALSE, case = TRUE
## Setting direction: controls < cases

plot(ROC, add=T, col='red')
print(ROC$auc)

## Area under the curve: 0.9993

legend('bottomright', legend =  c('Using estimated baseline', 'Using true baseline'), lty=1, col=c('black','red'))

With mean squared error:

simulation_data$Y = ifelse(simulation_data$sim == 'epi.',1,0)
simulation_data$sqerr = (simulation_data$Y - simulation_data$warning.score)^2
cat("MSE using estimated baseline:", mean(simulation_data$sqerr), '\n') 

## MSE using estimated baseline: 0.02625492

simulation_data$sqerr.2 = (simulation_data$Y - simulation_data$warning.score.2)^2
cat("MSE using true baseline:", mean(simulation_data$sqerr.2), '\n') 

## MSE using true baseline: 0.0318318

And with a map:

data("GB_region_boundaries")
#plotBaseMap(add=F, xlim=c(-0.6,0.6), ylim=c(51.648,51.65))
plotBaseMap(add=F, xlim=c(-1,1), ylim=c(50.648,52.65))
points(simulation_data$longitude, simulation_data$latitude,
       col=ifelse(simulation_data$sim=='epi.', tab.red, tab.blue),
       pch=ifelse(simulation_data$sim=='epi.', 4, 20),
       cex=ifelse(simulation_data$sim=='epi.', 1, 0.5))
points(simulation_data[simulation_data$warning.score>0.95,]$longitude,
       simulation_data[simulation_data$warning.score>0.95,]$latitude,
       col=tab.orange,
       pch=1,
       cex=1)
# case.df$color = rgb(colorRamp(c("blue", "red"))(case.df$warning.score) / 255)
# plot(case.df$longitude, case.df$latitude, col=case.df$color)

legend('topright',c('end.','true epi.', 'w>0.95'), pch=c(20,4,1), col=c(tab.blue, tab.red, tab.orange))

plotBaseMap(add=F, xlim=c(-0.6,0.6), ylim=c(51.648,51.65))
#plotBaseMap(add=F, xlim=c(-1,1), ylim=c(50.648,52.65))
points(simulation_data$longitude, simulation_data$latitude,
       col=ifelse(simulation_data$sim=='epi.', tab.red, tab.blue),
       pch=ifelse(simulation_data$sim=='epi.', 4, 20),
       cex=ifelse(simulation_data$sim=='epi.', 1, 0.5))
points(simulation_data[simulation_data$warning.score.2>0.95,]$longitude,
       simulation_data[simulation_data$warning.score.2>0.95,]$latitude,
       col=tab.orange,
       pch=1,
       cex=1)
# case.df$color = rgb(colorRamp(c("blue", "red"))(case.df$warning.score) / 255)
# plot(case.df$longitude, case.df$latitude, col=case.df$color)

legend('topright',c('end.','true epi.', 'w>0.95'), pch=c(20,4,1), col=c(tab.blue, tab.red, tab.orange))

[1] M. Cavallaro, J. Coelho, D. Ready, V. Decraene, T. Lamagni, N. D. McCarthy, D. Todkill, M. J. Keeling (2022) Cluster detection with random neighbourhood covering: Application to invasive Group A Streptococcal disease. PLoS Comput Biol 18(11): e1010726. https://doi.org/10.1371/journal.pcbi.1010726