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i'm beginner in machine learning and i'm trying to implement my first Naive Bayes by myself for better understanding. So, i have dataset from (american census data, classes are '<=50k' and '>50k').

Here is my python code:


import sys
import csv

words_stats = {} # {'word': {'class1': cnt, 'class2': cnt'}}
words_cnt = 0

targets_stats = {} # {'class1': 3234, 'class2': 884} how many words in each class
class_stats = {} # {'class1': 7896, 'class2': 3034} how many lines in each class
items_cnt = 0

def train(dataset, targets):
    global words_stats, words_cnt, targets_stats, items_cnt, class_stats

    num = len(dataset)
    for item in xrange(num):
        class_stats[targets[item]] = class_stats.get(targets[item], 0) + 1

        for i in xrange(len(dataset[item])):
            word = dataset[item][i]
            if not words_stats.has_key(word):
                words_stats[word] = {}

            tgt = targets[item]

            cnt = words_stats[word].get(tgt, 0)
            words_stats[word][tgt] = cnt + 1

            targets_stats[tgt] = targets_stats.get(tgt, 0) + 1
            words_cnt += 1

    items_cnt = num

def classify(doc, tgt_set):
    global words_stats, words_cnt, targets_stats, items_cnt

    probs = {} #the probability itself P(c|W) = P(W|c) * P(c) / P(W)
    pc = {} #probability of the class in document set P(c)
    pwc = {} #probability of the word set in particular class. P(W|c)
    pw = 1 #probability of the word set in documet set

    for word in doc:
        if word not in words_stats:
            continue #dirty, very dirty 
        pw = pw * float(sum(words_stats[word].values())) / words_cnt

    for tgt in tgt_set:
        pc[tgt] = class_stats[tgt] / float(items_cnt)
        for word in doc:
            if word not in words_stats:
                continue #dirty, very dirty
            tgt_wrd_cnt = words_stats[word].get(tgt, 0)
            pwc[tgt] = pwc.get(tgt, 1) * float(tgt_wrd_cnt) / targets_stats[tgt]

        probs[tgt] = (pwc[tgt] * pc[tgt]) / pw

    l = sorted(probs.items(), key = lambda i: i[1], reverse=True)
    print probs
    return l[0][0]

def check_results(dataset, targets):
    num = len(dataset)
    tgt_set = set(targets)
    correct = 0
    incorrect = 0

    for item in xrange(num):
        res = classify(dataset[item], tgt_set)
        if res == targets[item]:
            correct = correct + 1
            incorrect = incorrect + 1

    print 'correct:', float(correct) / num, ' incorrect:', float(incorrect) / num

def load_data(fil):
    data = []
    tgts = []

    reader = csv.reader(fil)
    for line in reader:
        d = [x.strip() for x in line]
        if '?' in d:

        if not len(d):


    return data, tgts

if __name__ == '__main__':
    if len(sys.argv) < 3:
        print './program train_data.txt test_data.txt'

    filename = sys.argv[1]
    fil = open(filename, 'r')
    data, tgt = load_data(fil)
    train(data, tgt)

    test_file = open(sys.argv[2], 'r')
    test_data, test_tgt = load_data(test_file)

    check_results(test_data, tgt)

it gives ~61% of correct results. when i print probabilities i get the following:

{'<=50K': 0.07371606889800396, '>50K': 15.325378327213354}

but in case of correct classifier i expect to see sum of both probabilities equal to 1. At first i thought the problem is in float underflow and tried to make all calculations in logarithms, but results were similiar. i understand that omitting some words is gonna affect accuracy, but the probabilities are sooo wrong.

What do i do wrong or don't understand?

for your convinience i've uploaded dataset and python script here:

Thank you for your help.

share|improve this question
Consider using more readable variable names than e.g. pw and pwc. – Amber Oct 13 '13 at 19:57
you are absolutely right. but i wrote this code as training code just for me. sorry about this. – milo Oct 13 '13 at 20:07
up vote 1 down vote accepted

Naive Bayes doesn't compute a probability directly, rather it computes a "raw score" that is relatively compared to the other scores for each label in order to classify an instance. This score can easily be converted to a "probability" in the range of [0, 1]:

total = sum(probs.itervalues())
for label, score in probs.iteritems():
    probs[label] = score / total

However, keep in mind this still doesn't represent a true probability, as mentioned in this answer:

naive Bayes tends to predict probabilities that are almost always either very close to zero or very close to one.

share|improve this answer
The result from Naive Bayes is a true probability, just a poorly calibrated one. – larsmans Oct 13 '13 at 21:43
but result "15.32" still seems unreal. and i got result even in -23 power. is it ok? – milo Oct 14 '13 at 18:53

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