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GitHub - jbrukh/bayesian: Naive Bayesian Classification for Golang.
Naive Bayesian Classification for Golang. Contribute to jbrukh/bayesian development by creating an account on GitHub.
Visit SiteGitHub - jbrukh/bayesian: Naive Bayesian Classification for Golang.
Naive Bayesian Classification for Golang. Contribute to jbrukh/bayesian development by creating an account on GitHub.
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Naive Bayesian Classification
Perform naive Bayesian classification into an arbitrary number of classes on sets of strings. bayesian also supports term frequency-inverse document frequency calculations (TF-IDF).
Copyright (c) 2011-2017. Jake Brukhman. ([email protected]). All rights reserved. See the LICENSE file for BSD-style license.
Background
This is meant to be an low-entry barrier Go library for basic Bayesian classification. See code comments for a refresher on naive Bayesian classifiers, and please take some time to understand underflow edge cases as this otherwise may result in innacurate classifications.
Installation
Using the go command:
go get github.com/jbrukh/bayesian
go install !$
Documentation
See the GoPkgDoc documentation here.
Features
- Conditional probability and "log-likelihood"-like scoring.
- Underflow detection.
- Simple persistence of classifiers.
- Statistics.
- TF-IDF support.
Example 1 (Simple Classification)
To use the classifier, first you must create some classes and train it:
import "github.com/jbrukh/bayesian"
const (
Good bayesian.Class = "Good"
Bad bayesian.Class = "Bad"
)
classifier := bayesian.NewClassifier(Good, Bad)
goodStuff := []string{"tall", "rich", "handsome"}
badStuff := []string{"poor", "smelly", "ugly"}
classifier.Learn(goodStuff, Good)
classifier.Learn(badStuff, Bad)
Then you can ascertain the scores of each class and the most likely class your data belongs to:
scores, likely, _ := classifier.LogScores(
[]string{"tall", "girl"},
)
Magnitude of the score indicates likelihood. Alternatively (but with some risk of float underflow), you can obtain actual probabilities:
probs, likely, _ := classifier.ProbScores(
[]string{"tall", "girl"},
)
Example 2 (TF-IDF Support)
To use the TF-IDF classifier, first you must create some classes
and train it and you need to call ConvertTermsFreqToTfIdf() AFTER training
and before calling classification methods such as LogScores, SafeProbScores, and ProbScores)
import "github.com/jbrukh/bayesian"
const (
Good bayesian.Class = "Good"
Bad bayesian.Class = "Bad"
)
// Create a classifier with TF-IDF support.
classifier := bayesian.NewClassifierTfIdf(Good, Bad)
goodStuff := []string{"tall", "rich", "handsome"}
badStuff := []string{"poor", "smelly", "ugly"}
classifier.Learn(goodStuff, Good)
classifier.Learn(badStuff, Bad)
// Required
classifier.ConvertTermsFreqToTfIdf()
Then you can ascertain the scores of each class and the most likely class your data belongs to:
scores, likely, _ := classifier.LogScores(
[]string{"tall", "girl"},
)
Magnitude of the score indicates likelihood. Alternatively (but with some risk of float underflow), you can obtain actual probabilities:
probs, likely, _ := classifier.ProbScores(
[]string{"tall", "girl"},
)
Use wisely.
GoLang Resources
are all listed below.
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