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406 lines
17 KiB
Python
406 lines
17 KiB
Python
"""
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Linear Discriminant Analysis
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Assumptions About Data :
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1. The input variables has a gaussian distribution.
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2. The variance calculated for each input variables by class grouping is the
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same.
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3. The mix of classes in your training set is representative of the problem.
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Learning The Model :
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The LDA model requires the estimation of statistics from the training data :
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1. Mean of each input value for each class.
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2. Probability of an instance belong to each class.
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3. Covariance for the input data for each class
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Calculate the class means :
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mean(x) = 1/n ( for i = 1 to i = n --> sum(xi))
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Calculate the class probabilities :
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P(y = 0) = count(y = 0) / (count(y = 0) + count(y = 1))
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P(y = 1) = count(y = 1) / (count(y = 0) + count(y = 1))
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Calculate the variance :
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We can calculate the variance for dataset in two steps :
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1. Calculate the squared difference for each input variable from the
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group mean.
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2. Calculate the mean of the squared difference.
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------------------------------------------------
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Squared_Difference = (x - mean(k)) ** 2
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Variance = (1 / (count(x) - count(classes))) *
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(for i = 1 to i = n --> sum(Squared_Difference(xi)))
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Making Predictions :
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discriminant(x) = x * (mean / variance) -
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((mean ** 2) / (2 * variance)) + Ln(probability)
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---------------------------------------------------------------------------
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After calculating the discriminant value for each class, the class with the
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largest discriminant value is taken as the prediction.
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Author: @EverLookNeverSee
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"""
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from math import log
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from os import name, system
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from random import gauss, seed
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# Make a training dataset drawn from a gaussian distribution
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def gaussian_distribution(mean: float, std_dev: float, instance_count: int) -> list:
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"""
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Generate gaussian distribution instances based-on given mean and standard deviation
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:param mean: mean value of class
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:param std_dev: value of standard deviation entered by usr or default value of it
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:param instance_count: instance number of class
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:return: a list containing generated values based-on given mean, std_dev and
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instance_count
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>>> gaussian_distribution(5.0, 1.0, 20) # doctest: +NORMALIZE_WHITESPACE
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[6.288184753155463, 6.4494456086997705, 5.066335808938262, 4.235456349028368,
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3.9078267848958586, 5.031334516831717, 3.977896829989127, 3.56317055489747,
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5.199311976483754, 5.133374604658605, 5.546468300338232, 4.086029056264687,
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5.005005283626573, 4.935258239627312, 3.494170998739258, 5.537997178661033,
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5.320711100998849, 7.3891120432406865, 5.202969177309964, 4.855297691835079]
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"""
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seed(1)
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return [gauss(mean, std_dev) for _ in range(instance_count)]
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# Make corresponding Y flags to detecting classes
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def y_generator(class_count: int, instance_count: list) -> list:
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"""
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Generate y values for corresponding classes
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:param class_count: Number of classes(data groupings) in dataset
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:param instance_count: number of instances in class
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:return: corresponding values for data groupings in dataset
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>>> y_generator(1, [10])
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[0, 0, 0, 0, 0, 0, 0, 0, 0, 0]
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>>> y_generator(2, [5, 10])
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[0, 0, 0, 0, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1]
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>>> y_generator(4, [10, 5, 15, 20]) # doctest: +NORMALIZE_WHITESPACE
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[0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 1, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2,
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2, 2, 2, 2, 2, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3]
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"""
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return [k for k in range(class_count) for _ in range(instance_count[k])]
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# Calculate the class means
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def calculate_mean(instance_count: int, items: list) -> float:
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"""
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Calculate given class mean
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:param instance_count: Number of instances in class
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:param items: items that related to specific class(data grouping)
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:return: calculated actual mean of considered class
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>>> items = gaussian_distribution(5.0, 1.0, 20)
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>>> calculate_mean(len(items), items)
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5.011267842911003
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"""
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# the sum of all items divided by number of instances
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return sum(items) / instance_count
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# Calculate the class probabilities
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def calculate_probabilities(instance_count: int, total_count: int) -> float:
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"""
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Calculate the probability that a given instance will belong to which class
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:param instance_count: number of instances in class
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:param total_count: the number of all instances
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:return: value of probability for considered class
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>>> calculate_probabilities(20, 60)
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0.3333333333333333
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>>> calculate_probabilities(30, 100)
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0.3
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"""
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# number of instances in specific class divided by number of all instances
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return instance_count / total_count
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# Calculate the variance
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def calculate_variance(items: list, means: list, total_count: int) -> float:
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"""
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Calculate the variance
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:param items: a list containing all items(gaussian distribution of all classes)
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:param means: a list containing real mean values of each class
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:param total_count: the number of all instances
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:return: calculated variance for considered dataset
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>>> items = gaussian_distribution(5.0, 1.0, 20)
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>>> means = [5.011267842911003]
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>>> total_count = 20
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>>> calculate_variance([items], means, total_count)
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0.9618530973487491
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"""
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squared_diff = [] # An empty list to store all squared differences
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# iterate over number of elements in items
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for i in range(len(items)):
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# for loop iterates over number of elements in inner layer of items
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for j in range(len(items[i])):
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# appending squared differences to 'squared_diff' list
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squared_diff.append((items[i][j] - means[i]) ** 2)
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# one divided by (the number of all instances - number of classes) multiplied by
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# sum of all squared differences
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n_classes = len(means) # Number of classes in dataset
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return 1 / (total_count - n_classes) * sum(squared_diff)
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# Making predictions
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def predict_y_values(
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x_items: list, means: list, variance: float, probabilities: list
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) -> list:
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""" This function predicts new indexes(groups for our data)
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:param x_items: a list containing all items(gaussian distribution of all classes)
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:param means: a list containing real mean values of each class
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:param variance: calculated value of variance by calculate_variance function
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:param probabilities: a list containing all probabilities of classes
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:return: a list containing predicted Y values
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>>> x_items = [[6.288184753155463, 6.4494456086997705, 5.066335808938262,
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... 4.235456349028368, 3.9078267848958586, 5.031334516831717,
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... 3.977896829989127, 3.56317055489747, 5.199311976483754,
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... 5.133374604658605, 5.546468300338232, 4.086029056264687,
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... 5.005005283626573, 4.935258239627312, 3.494170998739258,
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... 5.537997178661033, 5.320711100998849, 7.3891120432406865,
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... 5.202969177309964, 4.855297691835079], [11.288184753155463,
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... 11.44944560869977, 10.066335808938263, 9.235456349028368,
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... 8.907826784895859, 10.031334516831716, 8.977896829989128,
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... 8.56317055489747, 10.199311976483754, 10.133374604658606,
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... 10.546468300338232, 9.086029056264687, 10.005005283626572,
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... 9.935258239627313, 8.494170998739259, 10.537997178661033,
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... 10.320711100998848, 12.389112043240686, 10.202969177309964,
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... 9.85529769183508], [16.288184753155463, 16.449445608699772,
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... 15.066335808938263, 14.235456349028368, 13.907826784895859,
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... 15.031334516831716, 13.977896829989128, 13.56317055489747,
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... 15.199311976483754, 15.133374604658606, 15.546468300338232,
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... 14.086029056264687, 15.005005283626572, 14.935258239627313,
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... 13.494170998739259, 15.537997178661033, 15.320711100998848,
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... 17.389112043240686, 15.202969177309964, 14.85529769183508]]
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>>> means = [5.011267842911003, 10.011267842911003, 15.011267842911002]
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>>> variance = 0.9618530973487494
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>>> probabilities = [0.3333333333333333, 0.3333333333333333, 0.3333333333333333]
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>>> predict_y_values(x_items, means, variance,
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... probabilities) # doctest: +NORMALIZE_WHITESPACE
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[0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 1, 1,
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1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2,
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2, 2, 2, 2, 2, 2, 2, 2, 2]
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"""
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# An empty list to store generated discriminant values of all items in dataset for
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# each class
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results = []
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# for loop iterates over number of elements in list
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for i in range(len(x_items)):
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# for loop iterates over number of inner items of each element
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for j in range(len(x_items[i])):
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temp = [] # to store all discriminant values of each item as a list
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# for loop iterates over number of classes we have in our dataset
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for k in range(len(x_items)):
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# appending values of discriminants for each class to 'temp' list
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temp.append(
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x_items[i][j] * (means[k] / variance)
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- (means[k] ** 2 / (2 * variance))
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+ log(probabilities[k])
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)
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# appending discriminant values of each item to 'results' list
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results.append(temp)
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return [result.index(max(result)) for result in results]
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# Calculating Accuracy
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def accuracy(actual_y: list, predicted_y: list) -> float:
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"""
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Calculate the value of accuracy based-on predictions
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:param actual_y:a list containing initial Y values generated by 'y_generator'
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function
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:param predicted_y: a list containing predicted Y values generated by
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'predict_y_values' function
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:return: percentage of accuracy
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>>> actual_y = [0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1,
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... 1, 1 ,1 ,1 ,1 ,1 ,1]
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>>> predicted_y = [0, 0, 0, 1, 1, 1, 0, 0, 1, 1, 0, 0,
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... 0, 0, 1, 1, 1, 0, 1, 1, 1]
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>>> accuracy(actual_y, predicted_y)
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50.0
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>>> actual_y = [0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 1, 1,
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... 1, 1, 1, 1, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2]
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>>> predicted_y = [0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 1,
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... 1, 1, 1, 1, 1, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2]
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>>> accuracy(actual_y, predicted_y)
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100.0
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"""
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# iterate over one element of each list at a time (zip mode)
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# prediction is correct if actual Y value equals to predicted Y value
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correct = sum(1 for i, j in zip(actual_y, predicted_y) if i == j)
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# percentage of accuracy equals to number of correct predictions divided by number
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# of all data and multiplied by 100
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return (correct / len(actual_y)) * 100
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# Main Function
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def main():
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""" This function starts execution phase """
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while True:
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print(" Linear Discriminant Analysis ".center(50, "*"))
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print("*" * 50, "\n")
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print("First of all we should specify the number of classes that")
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print("we want to generate as training dataset")
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# Trying to get number of classes
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n_classes = 0
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while True:
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try:
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user_input = int(
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input("Enter the number of classes (Data Groupings): ").strip()
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)
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if user_input > 0:
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n_classes = user_input
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break
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else:
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print(
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f"Your entered value is {user_input} , Number of classes "
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f"should be positive!"
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)
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continue
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except ValueError:
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print("Your entered value is not numerical!")
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print("-" * 100)
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std_dev = 1.0 # Default value for standard deviation of dataset
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# Trying to get the value of standard deviation
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while True:
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try:
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user_sd = float(
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input(
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"Enter the value of standard deviation"
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"(Default value is 1.0 for all classes): "
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).strip()
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or "1.0"
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)
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if user_sd >= 0.0:
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std_dev = user_sd
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break
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else:
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print(
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f"Your entered value is {user_sd}, Standard deviation should "
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f"not be negative!"
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)
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continue
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except ValueError:
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print("Your entered value is not numerical!")
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print("-" * 100)
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# Trying to get number of instances in classes and theirs means to generate
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# dataset
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counts = [] # An empty list to store instance counts of classes in dataset
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for i in range(n_classes):
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while True:
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try:
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user_count = int(
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input(f"Enter The number of instances for class_{i+1}: ")
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)
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if user_count > 0:
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counts.append(user_count)
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break
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else:
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print(
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f"Your entered value is {user_count}, Number of "
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"instances should be positive!"
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)
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continue
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except ValueError:
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print("Your entered value is not numerical!")
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print("-" * 100)
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# An empty list to store values of user-entered means of classes
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user_means = []
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for a in range(n_classes):
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while True:
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try:
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user_mean = float(
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input(f"Enter the value of mean for class_{a+1}: ")
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)
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if isinstance(user_mean, float):
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user_means.append(user_mean)
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break
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print(f"You entered an invalid value: {user_mean}")
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except ValueError:
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print("Your entered value is not numerical!")
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print("-" * 100)
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print("Standard deviation: ", std_dev)
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# print out the number of instances in classes in separated line
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for i, count in enumerate(counts, 1):
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print(f"Number of instances in class_{i} is: {count}")
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print("-" * 100)
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# print out mean values of classes separated line
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for i, user_mean in enumerate(user_means, 1):
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print(f"Mean of class_{i} is: {user_mean}")
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print("-" * 100)
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# Generating training dataset drawn from gaussian distribution
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x = [
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gaussian_distribution(user_means[j], std_dev, counts[j])
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for j in range(n_classes)
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]
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print("Generated Normal Distribution: \n", x)
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print("-" * 100)
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# Generating Ys to detecting corresponding classes
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y = y_generator(n_classes, counts)
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print("Generated Corresponding Ys: \n", y)
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print("-" * 100)
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# Calculating the value of actual mean for each class
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actual_means = [calculate_mean(counts[k], x[k]) for k in range(n_classes)]
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# for loop iterates over number of elements in 'actual_means' list and print
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# out them in separated line
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for i, actual_mean in enumerate(actual_means, 1):
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print(f"Actual(Real) mean of class_{i} is: {actual_mean}")
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print("-" * 100)
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# Calculating the value of probabilities for each class
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probabilities = [
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calculate_probabilities(counts[i], sum(counts)) for i in range(n_classes)
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]
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# for loop iterates over number of elements in 'probabilities' list and print
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# out them in separated line
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for i, probability in enumerate(probabilities, 1):
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print(f"Probability of class_{i} is: {probability}")
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print("-" * 100)
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# Calculating the values of variance for each class
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variance = calculate_variance(x, actual_means, sum(counts))
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print("Variance: ", variance)
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print("-" * 100)
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# Predicting Y values
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# storing predicted Y values in 'pre_indexes' variable
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pre_indexes = predict_y_values(x, actual_means, variance, probabilities)
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print("-" * 100)
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# Calculating Accuracy of the model
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print(f"Accuracy: {accuracy(y, pre_indexes)}")
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print("-" * 100)
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print(" DONE ".center(100, "+"))
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if input("Press any key to restart or 'q' for quit: ").strip().lower() == "q":
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print("\n" + "GoodBye!".center(100, "-") + "\n")
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break
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system("cls" if name == "nt" else "clear")
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if __name__ == "__main__":
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main()
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