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FGLMtrunc
FGLMtrunc
is a package that fits truncated Functional
Generalized Linear Models as described in Liu, Divani, and
Petersen (2020). It implements methods for both functional linear
and functional logistic regression models. The solution path is computed
efficiently using active set algorithm with warm start. Optimal
smoothing and truncation parameters (\(\lambda_s, \lambda_t\)) are chosen by
Bayesian information criterion (BIC).
To install FGLMtrunc
directly from CRAN, type in R
console this command:
install.packages("FGLMtrunc")
To load the FGLMtrunc
package, type in R console:
library(FGLMtrunc)
The function for fitting model is fglm_trunc
, which have
arguments to customize the fit. Below are details on some required
arguments:
X.curves
is required for matrix of functional
predictors.
Y
is required for response vector.
Either nbasis
or knots
is needed to
define the interior knots of B-spline.
Please use ?fglm_trunc
for more details on function
arguments. We will demonstrate usages of other commonly used arguments
by examples.
family="gaussian"
)Functional linear regression model is the default choice of function
fglm_trunc
with argument family="gaussian"
.
For illustration, we use dataset LinearExample
, which we
created beforehand following Case I in simulation studies section from
Liu et. al. (2020). This dataset contains \(n=200\) observations, and functional
predictors are observed at \(p=101\)
timepoints on \([0,1]\) interval. The
true truncation point is \(\delta =
0.54\).
data(LinearExample)
= LinearExample$Y
Y_linear = LinearExample$X.curves
Xcurves_linear = seq(0, 1, length.out = 101)
timeGrid plot(timeGrid, LinearExample$beta.true, type = 'l',
main = 'True coefficient function', xlab = "t", ylab=expression(beta(t)))
FGLMtrunc
model for linear regressionWe fit the model using 50 B-spline basis with default
degree=3
for cubic splines. Since argument
grid
is not specified, an equally spaced sequence of length
\(p=101\) on \([0,1]\) interval (including boundaries)
will automatically be used.
= fglm_trunc(Y_linear, Xcurves_linear, nbasis = 50) fit
fglm_trunc
also supports parallel computing to speed up
the running time of tuning regularization parameters. Parallel backend
must be registered before hand. Here is an example of using parallel
with doMC
backend (we cannot run the code here since it is
not available for Windows) :
library(doMC)
registerDoMC(cores = 2)
= fglm_trunc(Y_linear, Xcurves_linear, nbasis = 50, parallel = TRUE) fit
One can also manually provides grid
or
knots
sequences (or both). If knots
is
specified, nbasis
will be ignored.
<- 50 - 3 - 1 #Numbers of knots = nbasis - degree - 1
k <- seq(0, 1, length.out = k+2)[-c(1, k+2)] # Remove boundary knots
knots_n = fglm_trunc(Y_linear, Xcurves_linear, grid = timeGrid, knots = knots_n) fit2
fit
and fit2
fitted models will have the
same results.
fit
is an object of class FGLMtrunc
that
contains relevant estimation results. Please use
?fglm_trunc
for more details on function outputs. Function
call and truncation point will be printed with print
function:
print(fit)
#>
#> Call: fglm_trunc(Y = Y_linear, X.curves = Xcurves_linear, nbasis = 50)
#>
#>
#> Optimal truncation point: 0.52
FGLMtrunc
modelWe can visualize the estimates of functional parameter \(\beta\) directly with
plot
:
plot(fit)
#> NULL
The plot shows both smoothing and truncated estimates of \(\beta\). We can set argument
include_smooth=FALSE
to show only truncated estimate.
FGLMtrunc
modelPredict method for FGLMtrunc
fits works similar to
predict.glm
. Type "link"
is the default choice
for FGLMtrunc
object. For linear regression, both type
"link"
and "response"
return fitted values.
newX.curves
is required for these predictions.
predict(fit, newX.curves = Xcurves_linear[1:5,])
#> [,1]
#> [1,] 2.1337413
#> [2,] 1.2286605
#> [3,] 1.8207552
#> [4,] -0.2430198
#> [5,] 0.5901628
To get truncated estimate of \(\beta\), we can use either
fit$beta.truncated
or predict
function:
predict(fit, type = "coefficients")
#> [1] -1.194642e+00 -1.233189e+00 -1.274041e+00 -1.321971e+00 -1.382684e+00
#> [6] -1.461724e+00 -1.560226e+00 -1.676778e+00 -1.806592e+00 -1.942359e+00
#> [11] -2.075460e+00 -2.195993e+00 -2.293871e+00 -2.358836e+00 -2.381285e+00
#> [16] -2.352969e+00 -2.266606e+00 -2.117256e+00 -1.901351e+00 -1.619372e+00
#> [21] -1.273650e+00 -8.713600e-01 -4.219470e-01 6.139018e-02 5.633530e-01
#> [26] 1.068248e+00 1.560120e+00 2.023704e+00 2.444542e+00 2.810437e+00
#> [31] 3.112588e+00 3.344368e+00 3.503214e+00 3.588157e+00 3.601536e+00
#> [36] 3.546803e+00 3.429575e+00 3.256279e+00 3.034685e+00 2.773190e+00
#> [41] 2.481013e+00 2.167832e+00 1.843081e+00 1.516008e+00 1.196723e+00
#> [46] 8.962979e-01 6.237543e-01 3.847519e-01 1.897238e-01 6.071026e-02
#> [51] 8.314897e-03 1.796018e-06 0.000000e+00 0.000000e+00 0.000000e+00
#> [56] 0.000000e+00 0.000000e+00 0.000000e+00 0.000000e+00 0.000000e+00
....
family="binomial"
)For logistic regression, we use dataset LogisticExample
,
which is similar to LinearExample
, but the response \(Y\) was generated as Bernoulli random
variable.
data(LogisticExample)
= LogisticExample$Y
Y_logistic = LogisticExample$X.curves Xcurves_logistic
FGLMtrunc
model for logistic regressionSimilarly, we fit the model using 50 B-spline basis with default
choice of cubic splines. We need to set family="binomial"
for logistic regression. Printing and plotting are the same as
before.
= fglm_trunc(Y_logistic, Xcurves_logistic, family="binomial", nbasis = 50) fit4
print(fit4)
#>
#> Call: fglm_trunc(Y = Y_logistic, X.curves = Xcurves_logistic, family = "binomial", nbasis = 50)
#>
#>
#> Optimal truncation point: 0.58
plot(fit4)
#> NULL
FGLMtrunc
model for logistic
regressionFor functional logistic regression, each type
option
returns a different prediction:
type="link"
gives the linear predictors which are
log-odds.
type="response"
gives the predicted
probabilities.
type="coefficients"
gives truncated estimate of
functional parameter \(\beta\) as
before.
= predict(fit4, newX.curves = Xcurves_logistic, type="link")
logistic_link_pred plot(logistic_link_pred, ylab="log-odds")
= predict(fit4, newX.curves = Xcurves_logistic, type="response")
logistic_response_pred plot(logistic_response_pred, ylab="predicted probabilities")
FGLMtrunc
modelFGLMtrunc
allows using scalar predictors together with
functional predictors. First, we randomly generate observations for
scalar predictors:
<- c(1, -1, 0.5) # True coefficients for scalar predictors
scalar_coef set.seed(1234)
<- cbind(matrix(rnorm(400), nrow=200), rbinom(200, 1, 0.5)) # Randomly generated observations for scalar predictors. Binary coded as 0 and 1.
S colnames(S) <- c("s1", "s2", "s3")
Next, we modify the response vector from LinearExample
so that it takes into account scalar predictors:
<- Y_linear + (S %*% scalar_coef) Y_scalar
Then we fit FGLMtrunc
model with the matrix of scalar
predictors S
:
= fglm_trunc(X.curves=Xcurves_linear, Y=Y_scalar, S=S, nbasis = 50)
fit_scalar
fit_scalar#>
#> Call: fglm_trunc(Y = Y_scalar, X.curves = Xcurves_linear, S = S, nbasis = 50)
#>
#> Intercept s1 s2 s3
#> 1.0865 1.0937 -1.0411 0.4233
#>
#> Optimal truncation point: 0.49
Fitted coefficients for scalar predictors are close to the true values.
To make prediction with fitted model using scalar predictors, we need
to specified argument newS
:
predict(fit_scalar, newX.curves = Xcurves_linear[1:5,], newS=S[1:5,])
#> [,1]
#> [1,] 0.3837103
#> [2,] 1.2553910
#> [3,] 3.2764746
#> [4,] -3.4882131
#> [5,] 0.7946992
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.