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'''DFFITS''' is a diagnostic meant to show how influential a point is in a [[statistical regression]]. It was proposed in 1980.<ref>{{cite book |last=Belsley |first=David A. |last2=Kuh |first2=Edwin |last3=Welsh |first3=Roy E. | year=1980 |title=Regression diagnostics: identifying influential data and sources of collinearity |publisher=[[John Wiley & Sons]] |location=New York |series=Wiley series in probability and mathematical statistics |isbn=0-471-05856-4}}</ref> It is defined as the change ("DFFIT"), in the predicted value for a point, obtained when that point is left out of the regression, "Studentized" by dividing by the estimated standard deviation of the fit at that point:
 
:<math>\text{DFFITS} = {\widehat{y_i} - \widehat{y_{i(i)}} \over s_{(i)} \sqrt{h_{ii}}}</math>
 
where <math>\widehat{y_i}</math> and <math>\widehat{y_{i(i)}}</math> are the prediction for point i with and without point i included in the regression,
<math>s_{(i)}</math> is the standard error estimated without the point in question, and <math>h_{ii}</math> is the [[leverage (statistics)|leverage]] for the point.
 
DFFITS is very similar to the externally [[Studentized residual]], and is in fact equal to the latter times <math>\sqrt{h_{ii}/(1-h_{ii})}</math>.<ref>{{cite book |last=Montogomery |first=Douglas C. |last2=Peck |first2=Elizabeth A. |last3=Vining |first3=G. Geoffrey |title=Introduction to Linear Regression Analysis |edition=5th |year=2012 |publisher=Wiley |isbn=978-0-470-54281-1 |page=[http://books.google.com/books?id=0yR4KUL4VDkC&lpg=PP1&dq=Introduction%20to%20Linear%20Regression%20Analysis%202nd%20edition&pg=PA218#v=onepage&q&f=false 218] |quote=Thus, ''DFFITS<sub>i</sub>'' is the value of ''R''-student multiplied by the leverage of the ''i''th observation [h<sub>ii</sub>/(1-h<sub>ii</sub>)]<sup>1/2</sup>. |url=http://www.wiley.com/WileyCDA/WileyTitle/productCd-0470542810.html |accessdate=22 February 2013}}</ref>
 
Since when the errors are [[Gaussian]] the externally Studentized residual is distributed as [[Student's t]] (with a number of [[Degrees of freedom (statistics)|degrees of freedom]] equal to the number of residual degrees of freedom minus one), DFFITS for a particular point will be distributed according to this same Student's t distribution multiplied by the [[Leverage (statistics)|leverage factor]] <math>\sqrt{h_{ii}/(1-h_{ii})}</math> for that particular point. Thus, for low leverage points, DFFITS is expected to be small, whereas as the leverage goes to 1 the distribution of the DFFITS value widens infinitely.
 
For a perfectly balanced experimental design (such as a [[factorial design]] or balanced partial factorial design), the leverage for each point is p/n, the number of parameters divided by the number of points. This means that the DFFITS values will be distributed (in the Gaussian case) as <math>\sqrt{p \over n-p} \approx \sqrt{p \over n}</math> times a t variate. Therefore, the authors suggest investigating those points with DFFITS greater than <math>2\sqrt{p \over n}</math>.
 
Although the raw values resulting from the equations are different, [[Cook's distance]] and DFFITS are conceptually identical and there is a closed-form formula to convert one value to the other (Cohen, Cohen, West & Aiken, 2003).
 
== Development ==
Previously when assessing a dataset before running a linear regression, the possibility of outliers would be assessed using histograms and scatterplots. Both methods of assessing data points were subjective and there was little way of knowing how much leverage each potential outlier had on the results data. This led to a variety of quantitative measures, including DFFIT, DFBETA.
 
==References==
<references/>
 
[[Category:Regression diagnostics]]

Revision as of 12:01, 9 July 2013

DFFITS is a diagnostic meant to show how influential a point is in a statistical regression. It was proposed in 1980.[1] It is defined as the change ("DFFIT"), in the predicted value for a point, obtained when that point is left out of the regression, "Studentized" by dividing by the estimated standard deviation of the fit at that point:

DFFITS=yi^yi(i)^s(i)hii

where yi^ and yi(i)^ are the prediction for point i with and without point i included in the regression, s(i) is the standard error estimated without the point in question, and hii is the leverage for the point.

DFFITS is very similar to the externally Studentized residual, and is in fact equal to the latter times hii/(1hii).[2]

Since when the errors are Gaussian the externally Studentized residual is distributed as Student's t (with a number of degrees of freedom equal to the number of residual degrees of freedom minus one), DFFITS for a particular point will be distributed according to this same Student's t distribution multiplied by the leverage factor hii/(1hii) for that particular point. Thus, for low leverage points, DFFITS is expected to be small, whereas as the leverage goes to 1 the distribution of the DFFITS value widens infinitely.

For a perfectly balanced experimental design (such as a factorial design or balanced partial factorial design), the leverage for each point is p/n, the number of parameters divided by the number of points. This means that the DFFITS values will be distributed (in the Gaussian case) as pnppn times a t variate. Therefore, the authors suggest investigating those points with DFFITS greater than 2pn.

Although the raw values resulting from the equations are different, Cook's distance and DFFITS are conceptually identical and there is a closed-form formula to convert one value to the other (Cohen, Cohen, West & Aiken, 2003).

Development

Previously when assessing a dataset before running a linear regression, the possibility of outliers would be assessed using histograms and scatterplots. Both methods of assessing data points were subjective and there was little way of knowing how much leverage each potential outlier had on the results data. This led to a variety of quantitative measures, including DFFIT, DFBETA.

References

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