# ConvNetJS ConvNetJS is a Javascript implementation of Neural networks, together with nice browser-based demos. It currently supports: - Common **Neural Network modules** (fully connected layers, non-linearities) - Classification (SVM/Softmax) and Regression (L2) **cost functions** - Ability to specify and train **Convolutional Networks** that process images - An experimental **Reinforcement Learning** module, based on Deep Q Learning For much more information, see the main page at [convnetjs.com](http://convnetjs.com) **Note**: I am not actively maintaining ConvNetJS anymore because I simply don't have time. I think the npm repo might not work at this point. ## Online Demos - [Convolutional Neural Network on MNIST digits](http://cs.stanford.edu/~karpathy/convnetjs/demo/mnist.html) - [Convolutional Neural Network on CIFAR-10](http://cs.stanford.edu/~karpathy/convnetjs/demo/cifar10.html) - [Toy 2D data](http://cs.stanford.edu/~karpathy/convnetjs/demo/classify2d.html) - [Toy 1D regression](http://cs.stanford.edu/~karpathy/convnetjs/demo/regression.html) - [Training an Autoencoder on MNIST digits](http://cs.stanford.edu/~karpathy/convnetjs/demo/autoencoder.html) - [Deep Q Learning Reinforcement Learning demo](http://cs.stanford.edu/people/karpathy/convnetjs/demo/rldemo.html) - [Image Regression ("Painting")](http://cs.stanford.edu/~karpathy/convnetjs/demo/image_regression.html) - [Comparison of SGD/Adagrad/Adadelta on MNIST](http://cs.stanford.edu/people/karpathy/convnetjs/demo/trainers.html) ## Example Code Here's a minimum example of defining a **2-layer neural network** and training it on a single data point: ```javascript // species a 2-layer neural network with one hidden layer of 20 neurons var layer_defs = []; // input layer declares size of input. here: 2-D data // ConvNetJS works on 3-Dimensional volumes (sx, sy, depth), but if you're not dealing with images // then the first two dimensions (sx, sy) will always be kept at size 1 layer_defs.push({type:'input', out_sx:1, out_sy:1, out_depth:2}); // declare 20 neurons, followed by ReLU (rectified linear unit non-linearity) layer_defs.push({type:'fc', num_neurons:20, activation:'relu'}); // declare the linear classifier on top of the previous hidden layer layer_defs.push({type:'softmax', num_classes:10}); var net = new convnetjs.Net(); net.makeLayers(layer_defs); // forward a random data point through the network var x = new convnetjs.Vol([0.3, -0.5]); var prob = net.forward(x); // prob is a Vol. Vols have a field .w that stores the raw data, and .dw that stores gradients console.log('probability that x is class 0: ' + prob.w[0]); // prints 0.50101 var trainer = new convnetjs.SGDTrainer(net, {learning_rate:0.01, l2_decay:0.001}); trainer.train(x, 0); // train the network, specifying that x is class zero var prob2 = net.forward(x); console.log('probability that x is class 0: ' + prob2.w[0]); // now prints 0.50374, slightly higher than previous 0.50101: the networks // weights have been adjusted by the Trainer to give a higher probability to // the class we trained the network with (zero) ``` and here is a small **Convolutional Neural Network** if you wish to predict on images: ```javascript var layer_defs = []; layer_defs.push({type:'input', out_sx:32, out_sy:32, out_depth:3}); // declare size of input // output Vol is of size 32x32x3 here layer_defs.push({type:'conv', sx:5, filters:16, stride:1, pad:2, activation:'relu'}); // the layer will perform convolution with 16 kernels, each of size 5x5. // the input will be padded with 2 pixels on all sides to make the output Vol of the same size // output Vol will thus be 32x32x16 at this point layer_defs.push({type:'pool', sx:2, stride:2}); // output Vol is of size 16x16x16 here layer_defs.push({type:'conv', sx:5, filters:20, stride:1, pad:2, activation:'relu'}); // output Vol is of size 16x16x20 here layer_defs.push({type:'pool', sx:2, stride:2}); // output Vol is of size 8x8x20 here layer_defs.push({type:'conv', sx:5, filters:20, stride:1, pad:2, activation:'relu'}); // output Vol is of size 8x8x20 here layer_defs.push({type:'pool', sx:2, stride:2}); // output Vol is of size 4x4x20 here layer_defs.push({type:'softmax', num_classes:10}); // output Vol is of size 1x1x10 here net = new convnetjs.Net(); net.makeLayers(layer_defs); // helpful utility for converting images into Vols is included var x = convnetjs.img_to_vol(document.getElementById('#some_image')) var output_probabilities_vol = net.forward(x) ``` ## Getting Started A [Getting Started](http://cs.stanford.edu/people/karpathy/convnetjs/started.html) tutorial is available on main page. The full [Documentation](http://cs.stanford.edu/people/karpathy/convnetjs/docs.html) can also be found there. See the **releases** page for this project to get the minified, compiled library, and a direct link to is also available below for convenience (but please host your own copy) - [convnet.js](http://cs.stanford.edu/people/karpathy/convnetjs/build/convnet.js) - [convnet-min.js](http://cs.stanford.edu/people/karpathy/convnetjs/build/convnet-min.js) ## Compiling the library from src/ to build/ If you would like to add features to the library, you will have to change the code in `src/` and then compile the library into the `build/` directory. The compilation script simply concatenates files in `src/` and then minifies the result. The compilation is done using an ant task: it compiles `build/convnet.js` by concatenating the source files in `src/` and then minifies the result into `build/convnet-min.js`. Make sure you have **ant** installed (on Ubuntu you can simply *sudo apt-get install* it), then cd into `compile/` directory and run: $ ant -lib yuicompressor-2.4.8.jar -f build.xml The output files will be in `build/` ## Use in Node The library is also available on *node.js*: 1. Install it: `$ npm install convnetjs` 2. Use it: `var convnetjs = require("convnetjs");` ## License MIT