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==Correlation==
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==Introduction==
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Covariance and correlation are very similarly related. Correlation is used to identify the relationship of two random variables, X and Y. In order to determine the dependence of the two events, the correlation coefficient,<math> \rho </math>, is calculated as:
  
 
<math> \rho (X,Y) =  \frac{cov(X,Y)}{ \sqrt{var(X)var(Y)} } </math>
 
<math> \rho (X,Y) =  \frac{cov(X,Y)}{ \sqrt{var(X)var(Y)} } </math>
  
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The covariance is defined as: E(X-E[X])(Y-E[X]))
  
===Auto-Correlation===
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If X and Y are independent of each other, that means they are uncorrelated with each other, or cov(X,Y) = 0. However, if X and Y are uncorrelated, that does not mean they are independent of each other. 1, -1, and 0 are the three extreme points <math>p\rho X,Y)</math> can represent. 1 represents that X and Y are linearly dependent of each other. In other words, Y-E[X] is a positive multiple of X-E[X]. -1 represents that X and Y are inversely dependent of each other. In other words, Y-E[X] is a negative multiple of X-E[X].
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==Covariance==
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===Examples===
 
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===Auto-Covariance===
 
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==References==
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[[2013_Spring_ECE_302_Boutin|Back to ECE302 Spring 2013, Prof. Boutin]]
 
[[2013_Spring_ECE_302_Boutin|Back to ECE302 Spring 2013, Prof. Boutin]]

Revision as of 18:04, 30 April 2013


Correlation vs Covariance

Student project for ECE302

by Blue



Introduction

Covariance and correlation are very similarly related. Correlation is used to identify the relationship of two random variables, X and Y. In order to determine the dependence of the two events, the correlation coefficient,$ \rho $, is calculated as:

$ \rho (X,Y) = \frac{cov(X,Y)}{ \sqrt{var(X)var(Y)} } $

The covariance is defined as: E(X-E[X])(Y-E[X]))

If X and Y are independent of each other, that means they are uncorrelated with each other, or cov(X,Y) = 0. However, if X and Y are uncorrelated, that does not mean they are independent of each other. 1, -1, and 0 are the three extreme points $ p\rho X,Y) $ can represent. 1 represents that X and Y are linearly dependent of each other. In other words, Y-E[X] is a positive multiple of X-E[X]. -1 represents that X and Y are inversely dependent of each other. In other words, Y-E[X] is a negative multiple of X-E[X].

Examples

text



References

Back to ECE302 Spring 2013, Prof. Boutin

Alumni Liaison

Ph.D. 2007, working on developing cool imaging technologies for digital cameras, camera phones, and video surveillance cameras.

Buyue Zhang