Neural Networks
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Consider a supervised learning problem where we have access to labeled training examples <math>(x^{(i)}, y^{(i)})</math>. Neural networks give a way of defining a complex, non-linear form of hypotheses <math>h_{W,b}(x)</math>, with parameters <math>W,b</math> that we can fit to our data. To describe neural networks, we will begin by describing the simplest possible neural network, one which comprises a single "neuron." We will use the following diagram to denote a single neuron: [[Image:SingleNeuron.png|400px|center]] This "neuron" is a computational unit that takes as input <math>x_1, x_2, x_3</math> (and a +1 intercept term), and outputs <math>h_{W,b}(x) = f(W^Tx) = f(\sum_{i=1}^3 W_{i}x_i +b)</math>, where <math>f : \Re \mapsto \Re</math> is called the '''activation function'''. In these notes, we will choose <math>f(\cdot)</math> to be the sigmoid function: :<math> f(z) = \frac{1}{1+\exp(-z)}. </math> Thus, our single neuron corresponds exactly to the input-output mapping defined by logistic regression. Although these notes will use the sigmoid function, it is worth noting that another common choice for <math>f</math> is the hyperbolic tangent, or tanh, function: :<math> f(z) = \tanh(z) = \frac{e^z - e^{-z}}{e^z + e^{-z}}, </math> Here are plots of the sigmoid and <math>\tanh</math> functions: [[Image:Sigmoid_Function.png|400px|center|Sigmoid activation function.]] [[Image:Tanh_Function.png|400px|center|Tanh activation function.]] The <math>\tanh(z)</math> function is a rescaled version of the sigmoid, and its output range is <math>[-1,1]</math> instead of <math>[0,1]</math>. Note that unlike CS221 and (parts of) CS229, we are not using the convention here of <math>x_0=1</math>. Instead, the intercept term is handled separately by the parameter <math>b</math>. Finally, one identity that'll be useful later: If <math>f(z) = 1/(1+\exp(-z))</math> is the sigmoid function, then its derivative is given by <math>f'(z) = f(z) (1-f(z))</math>. (If <math>f</math> is the tanh function, then its derivative is given by <math>f'(z) = 1- (f(z))^2</math>.) You can derive this yourself using the definition of the sigmoid (or tanh) function. == Neural Network formulation == A neural network is put together by hooking together many of our simple ``neurons,'' so that the output of a neuron can be the input of another. For example, here is a small neural network: [[Image:Network331.png|400px|center]] In this figure, we have used circles to also denote the inputs to the network. The circles labeled ``+1'' are called '''bias units''', and correspond to the intercept term. The leftmost layer of the network is called the '''input layer''', and the rightmost layer the '''output layer''' (which, in this example, has only one node). The middle layer of nodes is called the '''hidden layer''', because its values are not observed in the training set. We also say that our example neural network has 3 '''input units''' (not counting the bias unit), 3 '''hidden units''', and 1 '''output unit'''. We will let <math>n_l</math> denote the number of layers in our network; thus <math>n_l=3</math> in our example. We label layer <math>l</math> as <math>L_l</math>, so layer <math>L_1</math> is the input layer, and layer <math>L_{n_l}</math> the output layer. Our neural network has parameters <math>(W,b) = (W^{(1)}, b^{(1)}, W^{(2)}, b^{(2)})</math>, where we write <math>W^{(l)}_{ij}</math> to denote the parameter (or weight) associated with the connection between unit <math>j</math> in layer <math>l</math>, and unit <math>i</math> in layer <math>l+1</math>. (Note the order of the indices.) Also, <math>b^{(l)}_i</math> is the bias associated with unit <math>i</math> in layer <math>l+1</math>. Thus, in our example, we have <math>W^{(1)} \in \Re^{3\times 3}</math>, and <math>W^{(2)} \in \Re^{1\times 3}</math>. Note that bias units don't have inputs or connections going into them, since they always output the value +1. We also let <math>s_l</math> denote the number of nodes in layer <math>l</math> (not counting the bias unit). We will write <math>a^{(l)}_i</math> to denote the '''activation''' (meaning output value) of unit <math>i</math> in layer <math>l</math>. For <math>l=1</math>, we also use <math>a^{(1)}_i = x_i</math> to denote the <math>i</math>-th input. Given a fixed setting of the parameters <math>W,b</math>, our neural network defines a hypothesis <math>h_{W,b}(x)</math> that outputs a real number. Specifically, the computation that this neural network represents is given by: :<math> \begin{align} a_1^{(2)} &= f(W_{11}^{(1)}x_1 + W_{12}^{(1)} x_2 + W_{13}^{(1)} x_3 + b_1^{(1)}) \\ a_2^{(2)} &= f(W_{21}^{(1)}x_1 + W_{22}^{(1)} x_2 + W_{23}^{(1)} x_3 + b_2^{(1)}) \\ a_3^{(2)} &= f(W_{31}^{(1)}x_1 + W_{32}^{(1)} x_2 + W_{33}^{(1)} x_3 + b_3^{(1)}) \\ h_{W,b}(x) &= a_1^{(3)} = f(W_{11}^{(2)}a_1^{(2)} + W_{12}^{(2)} a_2^{(2)} + W_{13}^{(2)} a_3^{(2)} + b_1^{(2)}) \end{align} </math> In the sequel, we also let <math>z^{(l)}_i</math> denote the total weighted sum of inputs to unit <math>i</math> in layer <math>l</math>, including the bias term (e.g., <math>z_i^{(2)} = \sum_{j=1}^n W^{(1)}_{ij} x_j + b^{(1)}_i</math>), so that <math>a^{(l)}_i = f(z^{(l)}_i)</math>.
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