This tutorial will be similar to the Instacart Multitask tutorial. The only difference is that we will not use multitasking to train our neural network. Recall the data originially comes from a Kaggle challenge (kaggle.com/c/instacart-market-basket-analysis). We removed users that only made 1 order using the instacart app and then took 5000 users out of the remaining to be part of the data for this tutorial.
For each order, we have information on the product the user purchased. For example, there is information on the product name, what aisle it is found in, and the department it falls under. To construct features, we extracted indicators representing whether or not a user purchased a product in the given aisles for each order. In total there are 134 aisles. The targets were whether or not a user will buy a product in the breakfast department in the next order. As mentioned, we will not use any auxiliary targets.
Because of temporal dependencies within the data, we used a LSTM network for our model.
To download the data, we will create a temporary directory that will store the data files, extract the tar.gz file from the url, and place it in the specified directory.
val DATA_URL ="https://dl4jdata.blob.core.windows.net/training/tutorials/instacart.tar.gz"val DATA_PATH = FilenameUtils.concat(System.getProperty("java.io.tmpdir"), "dl4j_instacart/")
We will then extract the data from the tar.gz file, recreate directories within the tar.gz file into our temporary directories, and copy the files from the tar.gz file.
Next we will convert the raw data (csv files) into DataSetIterators, which will be fed into a neural network. Our training data will have 4000 examples which will be represented by a single DataSetIterator, and the testing data will have 1000 examples which will be represented by a separate DataSetIterator.
val path = FilenameUtils.concat(DATA_PATH, "instacart/") // set parent directoryval featureBaseDir = FilenameUtils.concat(path, "features") // set feature directoryval targetsBaseDir = FilenameUtils.concat(path, "breakfast") // set label directory
We first initialize CSVSequenceRecordReaders, which will parse the raw data into record-like format. Then the SequenceRecordReaderDataSetIterators can be created using the RecordReaders. Since each example has sequences of different lengths, an alignment mode of align end is needed.
The next task is to set up the neural network configuration. We will use a MultiLayerNetwork and the configuration will be similar to the multitask model from before. Again we use one GravesLSTM layer but this time only one RnnOutputLayer.
val conf =new NeuralNetConfiguration.Builder() .optimizationAlgo(OptimizationAlgorithm.STOCHASTIC_GRADIENT_DESCENT) .seed(12345) .dropOut(0.25) .weightInit(WeightInit.XAVIER) .updater(new Adam()) .list() .layer(0, new LSTM.Builder() .activation(Activation.TANH) .gradientNormalization(GradientNormalization.ClipElementWiseAbsoluteValue) .gradientNormalizationThreshold(10) .nIn(134) .nOut(150) .build()) .layer(1, new RnnOutputLayer.Builder(LossFunction.XENT) .activation(Activation.SOFTMAX) .nIn(150) .nOut(2) .build()).build();
We must then initialize the neural network.
val net =new MultiLayerNetwork(conf);net.init();
Model Training
To train the model, we use 5 epochs with a simple call to the fit method of the MultiLayerNetwork.
net.fit( train , 5);
Model Evaluation
We will now evaluate our trained model. Note that we will use the area under the curve (AUC) metric of the ROC curve.
// Evaluate the modelval roc =new ROC(100);while(test.hasNext()){val next = test.next();val features = next.getFeatures();val output = net.output(features); roc.evalTimeSeries(next.getLabels(), output);}println(roc.calculateAUC());