The hardware and bandwidth for this mirror is donated by dogado GmbH, the Webhosting and Full Service-Cloud Provider. Check out our Wordpress Tutorial.
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[@]dogado.de.
We saw in the general overview when first generating our model fits with bdotsFit
that we we could specify the curve with the argument curveType
. Presently, the bdots
package contains three options for this: doubleGauss
, logistic
, and polynomial
. Documentation is included for each of these curves.
library(bdots)
fit <- bdotsFit(data = cohort_unrelated,
subject = "Subject",
time = "Time",
y = "Fixations",
group = c("DB_cond", "LookType"),
curveType = doubleGauss(concave = TRUE),
cores = 2)
Note that each of these is a function in their own right and must be passed in as a call
object. Curve functions that include arguments further specifying the type of curve, i.e., doubleGauss(concave = TRUE)
and polynomial(degree = n)
, should include these when the call is passed into bdotsFit
as seen in the example above.
Because each of the functions exists independently of bdotsFit
, users can specify their own curve functions for the fitting and bootstrapping process. The purpose of this vignette is to demonstrate how to do so. If you find that you have a curve function that is especially useful, please create a request to have it added to the bdots
package here.
We will examine the doubleGauss
function in more detail to see how we might go about creating our own. First, let's identify the components of this function
doubleGauss
#> function (dat, y, time, params = NULL, concave = TRUE, ...)
#> {
#> if (is.null(params)) {
#> params <- dgaussPars(dat, y, time, concave)
#> }
#> else {
#> if (length(params) != 6)
#> stop("doubleGauss requires 6 parameters be specified for refitting")
#> if (!all(names(params) %in% c("mu", "ht", "sig1", "sig2",
#> "base1", "base2"))) {
#> stop("doubleGauss parameters for refitting must be correctly labeled")
#> }
#> }
#> if (is.null(params)) {
#> return(NULL)
#> }
#> y <- str2lang(y)
#> time <- str2lang(time)
#> ff <- bquote(.(y) ~ (.(time) < mu) * (exp(-1 * (.(time) -
#> mu)^2/(2 * sig1^2)) * (ht - base1) + base1) + (mu <=
#> .(time)) * (exp(-1 * (.(time) - mu)^2/(2 * sig2^2)) *
#> (ht - base2) + base2))
#> attr(ff, "parnames") <- names(params)
#> return(list(formula = ff, params = params))
#> }
#> <bytecode: 0x55b748e91a38>
#> <environment: namespace:bdots>
There are four things to note:
concave = TRUE
, which specifies the curve, we also have dat
, y
, time
, params = NULL
, and ...
. These are the names that must be used for the function to be called correctly. The first represents a data.frame
or data.table
subset from the data
argument to bdotsFit
, while y
and time
correspond to their respective arguments in bdotsFit
and should assume that the arguments are passed in as character
. It's important to remember to set params = NULL
, as this is only used during the refitting step.
params = NULL
, the body of the function computes the necessary starting parameters to be used with the gnls
fitting function. In this case, the function dgaussPars
handles the initial parameter estimation and returns a named numeric
. When params
is not NULL
, it's usually a good idea to verify that it is the correct length and has the correct parameter names.
formula
object, as it must be quoted. One may use bquote
and str2lang
to substitute in the character
values for y
and time
. Alternatively, if this is to only be used for a particular data set, one can simply use quote
with the appropriate values used for y
and time
, as we will demonstrate below. Finally, the quoted formula
should contain a single attribute parnames
which has the names of the parameters used.
formula
and params
, a named numeric
with the parameters.
Briefly, we can see how this function is used by subsetting the data to a single subject and calling it directly.
## Return a unique subject/group permutation
dat <- cohort_unrelated[Subject == 1 & DB_cond == 50 & LookType == "Cohort", ]
dat
#> Subject Time DB_cond Fixations LookType Group
#> 1: 1 0 50 0.01136364 Cohort 50
#> 2: 1 4 50 0.01136364 Cohort 50
#> 3: 1 8 50 0.01136364 Cohort 50
#> 4: 1 12 50 0.01136364 Cohort 50
#> 5: 1 16 50 0.02272727 Cohort 50
#> ---
#> 497: 1 1984 50 0.02272727 Cohort 50
#> 498: 1 1988 50 0.02272727 Cohort 50
#> 499: 1 1992 50 0.02272727 Cohort 50
#> 500: 1 1996 50 0.02272727 Cohort 50
#> 501: 1 2000 50 0.02272727 Cohort 50
## See return value
doubleGauss(dat = dat, y = "Fixations", time = "Time", concave = TRUE)
#> $formula
#> Fixations ~ (Time < mu) * (exp(-1 * (Time - mu)^2/(2 * sig1^2)) *
#> (ht - base1) + base1) + (mu <= Time) * (exp(-1 * (Time -
#> mu)^2/(2 * sig2^2)) * (ht - base2) + base2)
#> attr(,"parnames")
#> [1] "mu" "ht" "sig1" "sig2" "base1" "base2"
#>
#> $params
#> mu ht sig1 sig2 base1 base2
#> 428.00000000 0.21590909 152.00000000 396.00000000 0.01136364 0.02272727
We will now create an entirely new function that is not included in bdots
to demonstrate that it works the same; the only change we will make is to substitute in the values for y
and time
without using str2lang
. For our data set here, the corresponding values to y
and time
are "Fixations"
and "Time"
, respectively
doubleGauss2 <- function (dat, y, time, params = NULL, concave = TRUE, ...) {
if (is.null(params)) {
## Instead of defining our own, just reuse the one in bdots
params <- bdots:::dgaussPars(dat, y, time, concave)
}
else {
if (length(params) != 6)
stop("doubleGauss requires 6 parameters be specified for refitting")
if (!all(names(params) %in% c("mu", "ht", "sig1", "sig2",
"base1", "base2"))) {
stop("doubleGauss parameters for refitting must be correctly labeled")
}
}
## Here, we use Fixations and Time directly
ff <- bquote(Fixations ~ (Time < mu) * (exp(-1 * (Time - mu)^2 /
(2 * sig1^2)) * (ht - base1) + base1) + (mu <= Time) *
(exp(-1 * (Time - mu)^2/(2 * sig2^2)) * (ht - base2) + base2))
return(list(formula = ff, params = params))
}
same_fit_different_day <- bdotsFit(data = cohort_unrelated,
subject = "Subject",
time = "Time",
y = "Fixations",
group = c("DB_cond", "LookType"),
curveType = doubleGauss2(concave = TRUE),
cores = 2)
Seeds have not yet been implemented, so there is some possibility that the resulting parameters are slightly different; however, using the coef
function, we can roughly confirm their equivalence
## Original fit
head(coef(fit))
#> mu ht sig1 sig2 base1 base2
#> [1,] 429.7595 0.1985978 159.8869 314.6389 0.009709772 0.03376106
#> [2,] 634.9292 0.2635044 303.8081 215.3845 -0.020636092 0.02892360
#> [3,] 647.0655 0.2543769 518.9632 255.9871 -0.213087597 0.01368195
#> [4,] 723.0551 0.2582110 392.9509 252.9381 -0.054827082 0.03197292
#> [5,] 501.4843 0.2247729 500.8605 158.4164 -0.331698893 0.02522686
#> [6,] 460.7152 0.3067659 382.7323 166.0833 -0.243308940 0.03992168
## "New" fit
head(coef(same_fit_different_day))
#> mu ht sig1 sig2 base1 base2
#> [1,] 424.0311 0.1985000 154.2040 319.4740 0.01136408 0.03363656
#> [2,] 634.8093 0.2635148 303.6648 215.4307 -0.02058587 0.02893339
#> [3,] 646.9448 0.2544417 517.6521 255.9967 -0.21165093 0.01357057
#> [4,] 723.0861 0.2582117 393.0037 252.9037 -0.05485216 0.03197492
#> [5,] 501.6132 0.2247893 500.9494 158.3115 -0.33217172 0.02522935
#> [6,] 460.7371 0.3067971 382.5232 165.9932 -0.24285941 0.03993349
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.
Health stats visible at Monitor.