library(keras) knitr::opts_chunk$set(eval = FALSE)
Keras is a high-level neural networks API developed with a focus on enabling fast experimentation. Being able to go from idea to result with the least possible delay is key to doing good research. Keras has the following key features:
Allows the same code to run on CPU or on GPU, seamlessly.
User-friendly API which makes it easy to quickly prototype deep learning models.
Built-in support for convolutional networks (for computer vision), recurrent networks (for sequence processing), and any combination of both.
Supports arbitrary network architectures: multi-input or multi-output models, layer sharing, model sharing, etc. This means that Keras is appropriate for building essentially any deep learning model, from a memory network to a neural Turing machine.
Is capable of running on top of multiple back-ends including TensorFlow, CNTK, or Theano.
This website provides documentation for the R interface to Keras. See the main Keras website at https://keras.io for additional information on the project.
First, install the keras R package from GitHub as follows:
devtools::install_github("rstudio/keras")
The Keras R interface uses the TensorFlow backend engine by default. To install both the core Keras library as well as the TensorFlow backend use the install_keras()
function:
library(keras) install_keras()
This will provide you with default CPU-based installations of Keras and TensorFlow. If you want a more customized installation, e.g. if you want to take advantage of NVIDIA GPUs, see the documentation for install_keras()
.
We can learn the basics of Keras by walking through a simple example: recognizing handwritten digits from the MNIST dataset. MNIST consists of 28 x 28 grayscale images of handwritten digits like these:
The dataset also includes labels for each image, telling us which digit it is. For example, the labels for the above images are 5, 0, 4, and 1.
The MNIST dataset is included with Keras and can be accessed using the dataset_mnist()
function. Here we load the dataset then create variables for our test and training data:
library(keras) mnist <- dataset_mnist() x_train <- mnist$train$x y_train <- mnist$train$y x_test <- mnist$test$x y_test <- mnist$test$y
The x
data is a 3-d array (images,width,height)
of grayscale values . To prepare the data for training we convert the 3-d arrays into matrices by reshaping width and height into a single dimension (28x28 images are flattened into length 784 vectors). Then, we convert the grayscale values from integers ranging between 0 to 255 into floating point values ranging between 0 and 1:
# reshape x_train <- array_reshape(x_train, c(nrow(x_train), 784)) x_test <- array_reshape(x_test, c(nrow(x_test), 784)) # rescale x_train <- x_train / 255 x_test <- x_test / 255
Note that we use the array_reshape()
function rather than the dim<-()
function to reshape the array. This is so that the data is re-interpreted using row-major semantics (as opposed to R's default column-major semantics), which is in turn compatible with the way that the numerical libraries called by Keras interpret array dimensions.
The y
data is an integer vector with values ranging from 0 to 9. To prepare this data for training we one-hot encode the vectors into binary class matrices using the Keras to_categorical()
function:
y_train <- to_categorical(y_train, 10) y_test <- to_categorical(y_test, 10)
The core data structure of Keras is a model, a way to organize layers. The simplest type of model is the Sequential model, a linear stack of layers.
We begin by creating a sequential model and then adding layers using the pipe (%>%
) operator:
model <- keras_model_sequential() model %>% layer_dense(units = 256, activation = 'relu', input_shape = c(784)) %>% layer_dropout(rate = 0.4) %>% layer_dense(units = 128, activation = 'relu') %>% layer_dropout(rate = 0.3) %>% layer_dense(units = 10, activation = 'softmax')
The input_shape
argument to the first layer specifies the shape of the input data (a length 784 numeric vector representing a grayscale image). The final layer outputs a length 10 numeric vector (probabilities for each digit) using a softmax activation function.
Use the summary()
function to print the details of the model:
summary(model)
Model
________________________________________________________________________________
Layer (type) Output Shape Param #
================================================================================
dense_1 (Dense) (None, 256) 200960
________________________________________________________________________________
dropout_1 (Dropout) (None, 256) 0
________________________________________________________________________________
dense_2 (Dense) (None, 128) 32896
________________________________________________________________________________
dropout_2 (Dropout) (None, 128) 0
________________________________________________________________________________
dense_3 (Dense) (None, 10) 1290
================================================================================
Total params: 235,146
Trainable params: 235,146
Non-trainable params: 0
________________________________________________________________________________
Next, compile the model with appropriate loss function, optimizer, and metrics:
model %>% compile( loss = 'categorical_crossentropy', optimizer = optimizer_rmsprop(), metrics = c('accuracy') )
Use the fit()
function to train the model for 30 epochs using batches of 128 images:
history <- model %>% fit( x_train, y_train, epochs = 30, batch_size = 128, validation_split = 0.2 )
The history
object returned by fit()
includes loss and accuracy metrics which we can plot:
plot(history)
{width=757 height=489 .r-plot}
Evaluate the model's performance on the test data:
model %>% evaluate(x_test, y_test)
$loss [1] 0.1149 $acc [1] 0.9807
Generate predictions on new data:
model %>% predict_classes(x_test)
[1] 7 2 1 0 4 1 4 9 5 9 0 6 9 0 1 5 9 7 3 4 9 6 6 5 4 0 7 4 0 1 3 1 3 4 7 2 7 1 2 [40] 1 1 7 4 2 3 5 1 2 4 4 6 3 5 5 6 0 4 1 9 5 7 8 9 3 7 4 6 4 3 0 7 0 2 9 1 7 3 2 [79] 9 7 7 6 2 7 8 4 7 3 6 1 3 6 9 3 1 4 1 7 6 9 [ reached getOption("max.print") -- omitted 9900 entries ]
Keras provides a vocabulary for building deep learning models that is simple, elegant, and intuitive. Building a question answering system, an image classification model, a neural Turing machine, or any other model is just as straightforward.
To learn the basics of Keras, we recommend the following sequence of tutorials:
Basic Classification --- In this tutorial, we train a neural network model to classify images of clothing, like sneakers and shirts.
Text Classification --- This tutorial classifies movie reviews as positive or negative using the text of the review.
Basic Regression --- This tutorial builds a model to predict the median price of homes in a Boston suburb during the mid-1970s.
Overfitting and Underfitting --- In this tutorial, we explore two common regularization techniques (weight regularization and dropout) and use them to improve our movie review classification results.
Save and Restore Models --- This tutorial demonstrates various ways to save and share models (after as well as during training).
These tutorials walk you through the main components of the Keras library and demonstrate the core workflows used for training and improving the performance of neural networks. The Guide to Keras Basics provides a more condensed summary of this material.
The Deep Learning with Keras cheat sheet also provides a condensed high level guide to using Keras.
To learn more about Keras, you can check out these articles:
If you want a more comprehensive introduction to both Keras and the concepts and practice of deep learning, we recommend the Deep Learning with R book from Manning. This book is a collaboration between François Chollet, the creator of Keras, and J.J. Allaire, who wrote the R interface to Keras.
The book presumes no significant knowledge of machine learning and deep learning, and goes all the way from basic theory to advanced practical applications, all using the R interface to Keras.
Keras (κέρας) means horn in Greek. It is a reference to a literary image from ancient Greek and Latin literature, first found in the Odyssey, where dream spirits (Oneiroi, singular Oneiros) are divided between those who deceive men with false visions, who arrive to Earth through a gate of ivory, and those who announce a future that will come to pass, who arrive through a gate of horn. It's a play on the words κέρας (horn) / κραίνω (fulfill), and ἐλέφας (ivory) / ἐλεφαίρομαι (deceive).
Keras was initially developed as part of the research effort of project ONEIROS (Open-ended Neuro-Electronic Intelligent Robot Operating System).
"Oneiroi are beyond our unravelling --who can be sure what tale they tell? Not all that men look for comes to pass. Two gates there are that give passage to fleeting Oneiroi; one is made of horn, one of ivory. The Oneiroi that pass through sawn ivory are deceitful, bearing a message that will not be fulfilled; those that come out through polished horn have truth behind them, to be accomplished for men who see them." Homer, Odyssey 19. 562 ff (Shewring translation).
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