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I've written a backpropagation neural network in Python using NumPy for the matrix calculations and batch updating. It learns binary functions like XOR well, but when I train it on the the iris dataset (in sklearn.datasets) with one-vs-all (my target function is y = iris.target == 1) it settles on putting all 1's or all -1's on the outputs. I've tried learning rates in [0.01, 5], hidden-layer sizes in [3, 20] nodes, and up to 50k epochs with no improvement.

Below is the important code for the NN. _sigmoid is numpy's tanh function, and _dsigmoid is its derivative. I'd really appreciate any help!

def __init__(self, n_input, n_hidden, n_output):
    self.n_input = n_input + 1
    self.n_hidden = n_hidden
    self.n_output = n_output
    self.w1 = np.random.normal(scale=0.7, size=(self.n_input*self.n_hidden)).reshape(self.n_input, self.n_hidden)
    self.w2 = np.random.normal(scale=0.7, size=(self.n_hidden*self.n_output)).reshape(self.n_hidden, self.n_output)
    self.output_activation = np.zeros(n_output)
    self.hidden_activation = np.zeros(n_hidden)
    self.input_activation = np.zeros(n_input)

def feed_forward(self):
    """
    Update output vector created by feed-forward propagation of input activations
    """
    self.hidden_activation = self._sigmoid(np.dot(self.input_activation, self.w1))
    self.output_activation = self._sigmoid(np.dot(self.hidden_activation, self.w2))

def back_propagate(self, target, alpha):        
    output_error = target - self.output_activation
    output_delta = output_error * self._dsigmoid(self.output_activation)

    hidden_error = np.dot(output_delta, self.w2.T)
    hidden_delta = hidden_error * self._dsigmoid(self.hidden_activation)

    self.w2 += alpha * (np.dot(self.hidden_activation.T, output_delta))
    self.w1 += alpha * (np.dot(self.input_activation.T, hidden_delta))

def train(self, data, target, alpha, epochs=50):
    m = data.shape[0]

    # add bias to input
    X = np.ones((m, self.n_input))
    X[:, 1:] = data

    # turn target into a column vector
    target = target[:, np.newaxis]

    for epoch in range(epochs):
        self.input_activation = X
        self.feed_forward()
        self.back_propagate(target, alpha)

def predict(self, data):
    m = data.shape[0]
    self.input_activation = np.ones((m, self.n_input))
    self.input_activation[:, 1:] = data
    self.feed_forward()
    return self.output_activation
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