User:Ping/Python Perceptron
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The code below defines two classes: Perceptron (which produces a floating-point output) and BooleanPerceptron (which produces a Boolean output). Internally, a bias input is built-in by appending an extra 1 to the given inputs.
#!/usr/bin/env python
__author__ = 'Ka-Ping Yee <ping@zesty.ca>'
def dot_product(inputs, weights):
return sum(input*weight for input, weight in zip(inputs, weights))
class Perceptron:
def __init__(self, size):
"""The 'size' parameter sets the number of inputs to this Perceptron."""
self.weights = [0.0]*size + [0.0]
def __repr__(self):
"""Display the internal weights of this Perceptron."""
weights = ', '.join('%.3g' % weight for weight in self.weights)
return '<%s: [%s]>' % (self.__class__.__name__, weights)
def evaluate(self, inputs):
"""Evaluate this Perceptron with the given inputs, giving 0 or 1.
'inputs' should be a list of numbers, and the length of the list
should equal the 'size' used to construct this Perceptron."""
return dot_product(self.weights, inputs + [1])
def adjust(self, inputs, rate):
"""Adjust the weights of this Perceptron for the given inputs, using
the given training rate."""
for i, input in enumerate(inputs + [1]):
self.weights[i] += rate*input
def train(self, inputs, expected_output, rate):
"""Train this Perceptron for a single test case."""
self.adjust(inputs, rate*(expected_output - self.evaluate(inputs)))
def train_all(self, training_set, rate):
"""Train this Perceptron for all cases in the given training set."""
for inputs, expected_output in training_set:
self.train(inputs, expected_output, rate)
def print_all(self, training_set):
"""Print out what the Perceptron produces for the given training set."""
print self
for inputs, expected_output in training_set:
output = self.evaluate(inputs)
print ' %r -> %r (want %r)' % (inputs, output, expected_output)
print 'RMS error:', self.rms_error(training_set)
print
def rms_error(self, training_set):
"""Compute the root-mean-square error across all the training cases."""
error = sum((self.evaluate(inputs) - expected_output)**2
for inputs, expected_output in training_set)
return (float(error)/len(training_set))**0.5
class BooleanPerceptron(Perceptron):
def evaluate(self, inputs):
"""Just like Perceptron.evaluate, but apply a threshold."""
return int(Perceptron.evaluate(self, inputs) > 0)
def train_perceptron(perceptron, training_set,
initial_rate, minimum_rate, damping_factor,
error_threshold):
rate = initial_rate
while rate > minimum_rate:
perceptron.print_all(training_set)
if perceptron.rms_error(training_set) < error_threshold:
print 'Success:', perceptron
break
perceptron.train_all(training_set, rate)
rate *= damping_factor
# Train a Boolean Perceptron to be a three-input NAND gate.
training_set = [
([1, 0, 0], 1),
([1, 0, 1], 1),
([1, 1, 0], 1),
([1, 1, 1], 0),
([0, 1, 0], 1),
([0, 0, 1], 1),
([0, 1, 1], 1),
([0, 0, 0], 1),
]
train_perceptron(BooleanPerceptron(3), training_set, 0.1, 1e-9, 0.9999, 1e-3)
# Train a floating-point Perceptron to fit a straight line.
training_set = [
([1.0], 2.0),
([1.5], 3.0),
([2.0], 4.0),
]
train_perceptron(Perceptron(1), training_set, 0.1, 1e-9, 0.9999, 1e-3)