dl.bamlss: Deep Learning BAMLSS

Description

This function interfaces keras infrastructures for high-level neural networks. The function can be used as a standalone model fitting engine such as bamlss or as an on top model engine to capture special features in the data that could not be captures by other model fitting engines.

Usage

## Deep learning bamlss.
dl.bamlss(object, optimizer = "adam",
  epochs = 30, batch_size = NULL,
  nlayers = 2, units = 100, activation = "sigmoid",
  l1 = NULL, l2 = NULL,
  verbose = TRUE, ...)
## Predict method.
# S3 method for dl.bamlss
predict(object, newdata,
  model = NULL, type = c("link", "parameter"),
  drop = TRUE, ...)

Value

For function dl.bamlss() an object of class "dl.bamlss". Note that extractor functions fitted and residuals.bamlss can be applied. For function predict.dl.bamlss() a list or vector of predicted values.

Arguments

object: An object of class "bamlss" or a bamlss.formula.
optimizer: Character or call to optimizer functions to be used within fit. For character, options are: "adam" "sgd", "rmsprop", "adagrad", "adadelta", "adamax", "adam". The default is optimizer_rmsprop with learning rate set to 1e-04.
epochs: Number of times to iterate over the training data arrays, see fit.
batch_size: Number of samples per gradient update, see fit.
nlayers: Number of hidden layers.
units: Number of nodes per hidden layer, can be a vector.
activation: Activation functions used for the hidden layers, can be a vector.
l1: Shrinkage parameter for L1 penalty.
l2: Shrinkage parameter for L2 penalty.
verbose: Print information during runtime of the algorithm.
newdata: A list or data.frame that should be used for prediction.
model: Character or integer specifying for which distributional parameter predictions should be computed.
type: If type = "link" the predictor of the corresponding model is returned. If type = "parameter" predictions on the distributional parameter scale are returned.
drop: If predictions for only one model are returned, the list structure is dropped.
...: For function dl.boost(), arguments passed to bamlss.frame.

WARNINGS

The BAMLSS deep learning infrastructure is still experimental!

Details

The default keras model is a sequential model with two hidden layers with "relu" activation function and 100 units in each layer. Between each layer is a dropout layer with 0.1 dropout rate.

Examples

Run this code

if (FALSE) ## Simulate data.
set.seed(123)
n <- 300
x <- runif(n, -3, 3)
fsigma <- -2 + cos(x)
y <- sin(x) + rnorm(n, sd = exp(fsigma))

## Setup model formula.
f <- list(
  y ~ x,
  sigma ~ x
)

## Fit neural network.
library("keras")
b <- dl.bamlss(f, epochs = 2000)

## Plot estimated functions.
par(mfrow = c(1, 2))
plot(x, y)
plot2d(fitted(b)$mu ~ x, add = TRUE)
plot2d(fitted(b)$sigma ~ x,
  ylim = range(c(fitted(b)$sigma, fsigma)))
plot2d(fsigma ~ x, add = TRUE, col.lines = "red")

## Predict with newdata.
nd <- data.frame(x = seq(-6, 6, length = 100))
nd$p <- predict(b, newdata = nd, type = "link")

par(mfrow = c(1, 2))
plot(x, y, xlim = c(-6, 6), ylim = range(c(nd$p$mu, y)))
plot2d(p$mu ~ x, data = nd, add = TRUE)
plot2d(p$sigma ~ x, data = nd,
  ylim = range(c(nd$p$sigma, fsigma)))
plot2d(fsigma ~ x, add = TRUE, col.lines = "red")

## Plot quantile residuals.
e <- residuals(b)
plot(e)

Run the code above in your browser using DataLab