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bdots
This vignette is created to illustrate the use of the bdotsCorr
function, which finds the correlation between a fixed value in our dataset and the collection of fitted curves at each time points for each of the groups fit in bdotsFit
.
First, let's take an existing dataset and add a fixed value for each of the subjects
library(bdots)
library(data.table)
## Let's work with cohort_unrelated dataset, as it has multiple groups
dat <- as.data.table(cohort_unrelated)
## And add a fixed value for which we want to find a correlation
dat[, val := rnorm(1), by = Subject]
head(dat)
## Subject Time DB_cond Fixations LookType Group val
## 1: 1 0 50 0.01136364 Cohort 50 0.5911445
## 2: 1 4 50 0.01136364 Cohort 50 0.5911445
## 3: 1 8 50 0.01136364 Cohort 50 0.5911445
## 4: 1 12 50 0.01136364 Cohort 50 0.5911445
## 5: 1 16 50 0.02272727 Cohort 50 0.5911445
## 6: 1 20 50 0.02272727 Cohort 50 0.5911445
Now, we go about creating our fitted object as usual
## Create regular fit in bdots
fit <- bdotsFit(data = dat,
subject = "Subject",
time = "Time",
group = c("LookType", "Group"),
y = "Fixations", curveType = doubleGauss2(),
cores = 2)
Using this fit object, we now introduce the bdotsCorr
function, taking four arguments:
bdObj
, any object returned from a bdotsFit
callval
, a length one character vector of the value with which we want to correlate. val
should be a column in our original dataset, and it should be numericciBands
, a boolean indicating whether or not we want to return 95% confidence intervals. Default is FALSE
method
, paralleling the method
argument in cor
and cor.test
. The default is pearson
.## Returns a data.table of class bdotsCorrObj
corr_ci <- bdotsCorr(fit, val = "val", ciBands = TRUE)
head(corr_ci)
## time Correlation lower upper Group Group1 Group2
## 1: 0 -0.15244734 -0.7414972 0.5693137 Cohort 50 Cohort 50
## 2: 4 -0.09788149 -0.7154925 0.6056079 Cohort 50 Cohort 50
## 3: 8 -0.04195758 -0.6869378 0.6399976 Cohort 50 Cohort 50
## 4: 12 0.01181996 -0.6574628 0.6706769 Cohort 50 Cohort 50
## 5: 16 0.06087569 -0.6286621 0.6968255 Cohort 50 Cohort 50
## 6: 20 0.10392521 -0.6017271 0.7184596 Cohort 50 Cohort 50
## Same, without confidence intervals
corr_noci <- bdotsCorr(fit, val = "val")
head(corr_noci)
## time Correlation Group Group1 Group2
## 1: 0 -0.15244734 Cohort 50 Cohort 50
## 2: 4 -0.09788149 Cohort 50 Cohort 50
## 3: 8 -0.04195758 Cohort 50 Cohort 50
## 4: 12 0.01181996 Cohort 50 Cohort 50
## 5: 16 0.06087569 Cohort 50 Cohort 50
## 6: 20 0.10392521 Cohort 50 Cohort 50
From here, we are able to use the data.tables
themselves for whatever we may be interested in. We also have a plotting method associated with this object
## Default is no bands
plot(corr_ci)
## Try again with bands
plot(corr_ci, ciBands = TRUE)
## Narrow in on a particular window
plot(corr_ci, window = c(750, 1500))
Because this object is a data.table
, we have full use of subsetting capabilities for our plots
plot(corr_ci[Group2 == "50", ])
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.