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Derivation of Fisher's Linear Discriminant
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==Derivation of Fisher's Linear Discriminant==
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Main article: [Derivation of Fisher's Linear Discriminant]
 
Main article: [Derivation of Fisher's Linear Discriminant]
  
  
References
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==References==
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"`Two variations on Fisher's linear discriminant for pattern recognition <http://ieeexplore.ieee.org/Xplore/login.jsp?url=/iel5/34/21179/00982904.pdf>`_"  is a nice journal article. The paper provides two fast and simple techniques for improving on the classification performance provided by Fisher's linear discriminant for two classes.  
 
"`Two variations on Fisher's linear discriminant for pattern recognition <http://ieeexplore.ieee.org/Xplore/login.jsp?url=/iel5/34/21179/00982904.pdf>`_"  is a nice journal article. The paper provides two fast and simple techniques for improving on the classification performance provided by Fisher's linear discriminant for two classes.  
 
See the following link for the detailed information: `Two variations on Fisher's linear discriminant for pattern recognition
 
See the following link for the detailed information: `Two variations on Fisher's linear discriminant for pattern recognition
 
<http://ieeexplore.ieee.org/Xplore/login.jsp?url=/iel5/34/21179/00982904.pdf>`_.
 
<http://ieeexplore.ieee.org/Xplore/login.jsp?url=/iel5/34/21179/00982904.pdf>`_.

Revision as of 10:24, 25 March 2008

Introduction

Fisher's linear discriminant is a classification method that projects high-dimensional data onto a line and performs classification in this one-dimensional space. The projection maximizes the distance between the means of the two classes while minimizing the variance within each class. See [Lecture 10] for detailed explanation.

Finding the separating hyperplane and finding the projection direction are dual problems

Fisher's Linear Discriminant relies on dimension reduction. If we want to project D-dimensional data down to one dimension we can use $ y=\omega^T \vec{x} $ . After that, by determining a threshold $ \omega_0 $, we can select class 1 if $ y>\omega_0 $ and class 2 if $ y<\omega_0> $.

However, dimension reduction can cause considerable amount of information loss leading not being able to separate the data in reduced dimension, while the data is separable in D dimension. Fisher's Linear Discriminant method uses that idea by adjusting the weight vector $ \omega $ for projection to minimize the amount of overlapping data in reduced dimension. Here are some figures from C. M. Bishop's book to understand the idea completely.

FLD Old Kiwi.jpg


Given data $ y_1,\cdots, y_d \in \mathbb{R}^n $, from 2 classes. When n is big, it may be difficult to separate classes, because of computational issues.

In this case we try to find a projection $ \pi: R^n \rightarrow R^k, k <n $ s.t . $ \pi(y_1), \cdots, \pi(y_d) $ can be separated.


Derivation of Fisher's Linear Discriminant

Main article: [Derivation of Fisher's Linear Discriminant]


References

"`Two variations on Fisher's linear discriminant for pattern recognition <http://ieeexplore.ieee.org/Xplore/login.jsp?url=/iel5/34/21179/00982904.pdf>`_" is a nice journal article. The paper provides two fast and simple techniques for improving on the classification performance provided by Fisher's linear discriminant for two classes. See the following link for the detailed information: `Two variations on Fisher's linear discriminant for pattern recognition <http://ieeexplore.ieee.org/Xplore/login.jsp?url=/iel5/34/21179/00982904.pdf>`_.

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