Homoscedasticity: Difference between revisions
mNo edit summary |
No edit summary |
||
| Line 1: | Line 1: | ||
[[File:Homoscedasticity1.png|thumb|Plot of Homoscedasticity.]] | [[File:Homoscedasticity1.png|thumb|Plot of Homoscedasticity.]] | ||
In [[statistics]], a [[sequence]] or a vector of [[random variable]]s is '''homoscedastic''' if all random variables in the sequence or vector have the same [[finite set|finite]] [[variance]]. This is also known as '''homogeneity of variance'''. | In [[statistics]], a [[sequence]] or a vector of [[random variable]]s is '''homoscedastic''' if all random variables in the sequence or vector have the same [[finite set|finite]] [[variance]]. This is also known as '''homogeneity of variance'''. | ||
The complement is called [[heteroscedasticity]]. (Note: The alternative spelling ''homo-'' or ''heteros'''k'''edasticity'' is equally correct and is also used frequently.) | The complement is called [[heteroscedasticity]]. (Note: The alternative spelling ''homo-'' or ''heteros'''k'''edasticity'' is equally correct and is also used frequently.) | ||
Serious violations in homoscedasticity (assuming a distribution of data is homoscedastic when in actuality it is heteroscedastic) result in underemphasizing the [[Pearson product-moment correlation coefficient | Pearson coefficient]]. Assuming homoscedasticity assumes that variance is fixed throughout a distribution. | Serious violations in homoscedasticity (assuming a distribution of data is homoscedastic when in actuality it is heteroscedastic) result in underemphasizing the [[Pearson product-moment correlation coefficient | Pearson coefficient]]. Assuming homoscedasticity assumes that variance is fixed throughout a distribution. | ||
Revision as of 12:20, 20 May 2016
In statistics, a sequence or a vector of random variables is homoscedastic if all random variables in the sequence or vector have the same finite variance. This is also known as homogeneity of variance. The complement is called heteroscedasticity. (Note: The alternative spelling homo- or heteroskedasticity is equally correct and is also used frequently.)
Serious violations in homoscedasticity (assuming a distribution of data is homoscedastic when in actuality it is heteroscedastic) result in underemphasizing the Pearson coefficient. Assuming homoscedasticity assumes that variance is fixed throughout a distribution.
Assumptions of a Regression Model
In simple linear regression analysis, one assumption of the fitted model is that the standard deviation of the error terms are constant and does not depend on the x-value. Consequently, each probability distributions for each y (response variable) has the same standard deviation regardless of the x-value (predictor). In short, this assumption is homoscedasticity.
Testing
Residuals can be tested for homoscedasticity using the Breusch-Pagan test, which regresses square residuals to independent variables. The BP test is sensitive to normality so for general purpose the Koenkar-Basset or generalized Breusch-Pagan test statistic is used. For testing for groupwise heteroscedasticity, the Goldfeld-Quandt test is needed.