Eigendecomposition of a matrix: Difference between revisions

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In [[statistics]], the '''variance inflation factor (VIF)''' quantifies the severity of [[multicollinearity]] in an [[ordinary least squares]] [[Linear regression|regression]] analysis. It provides an index that measures how much the [[variance]] (the square of the estimate's [[standard deviation]]) of an estimated regression coefficient is increased because of collinearity.
 
==Definition==
 
Consider the following [[linear model]] with ''k'' independent variables:
 
: ''Y'' = ''β''<sub>0</sub> + ''β''<sub>1</sub> ''X''<sub>1</sub> + ''β''<sub>2</sub> ''X'' <sub>2</sub> + ... + ''β''<sub>''k''</sub> ''X''<sub>''k''</sub> + ''ε''.
 
The [[Standard error (statistics)|standard error]] of the estimate of ''β''<sub>''j''</sub> is the square root of the ''j''+1, ''j''+1 element of ''s<sup>2</sup>''(''X''<sup>&prime;</sup>''X'')<sup>&minus;1</sup>, where ''s'' is the root mean squared error (RMSE) (note that RMSE<sup>2</sup> is an unbiased estimator of the true variance of the error term, <math> \sigma^2 </math>); ''X'' is the regression [[design matrix]] &mdash; a matrix such that ''X''<sub>''i'', ''j''+1</sub> is the value of the ''j''<sup>''th''</sup> independent variable for the ''i''<sup>''th''</sup> case or observation, and such that ''X''<sub>''i'', 1</sub> equals 1 for all ''i''.  It turns out that the square of this standard error, the estimated variance of the estimate of ''β''<sub>''j''</sub>, can be equivalently expressed as{{Citation needed|date=July 2010}}
 
:<math>
{\rm \hat{var}}(\hat{\beta}_j) = \frac{s^2}{(n-1)\widehat{\rm var}(X_j)}\cdot \frac{1}{1-R_j^2},
</math>
 
where ''R''<sub>''j''</sub><sup>2</sup> is the [[coefficient of determination|multiple ''R''<sup>2</sup>]] for the regression of ''X''<sub>''j''</sub> on the other covariates (a regression that does not involve the response variable ''Y''). This identity separates the influences of several distinct factors on the variance of the coefficient estimate:
 
* ''s''<sup>2</sup>: greater scatter in the data around the regression surface leads to proportionately more variance in the coefficient estimates
 
* ''n'': greater sample size results in proportionately less variance in the coefficient estimates
 
* <math>\widehat{\rm var}(X_j)</math>: greater variability in a particular covariate leads to proportionately less variance in the corresponding coefficient estimate
 
The remaining term, 1&nbsp;/&nbsp;(1&nbsp;&minus;&nbsp;''R''<sub>''j''</sub><sup>2</sup>) is the VIF.  It reflects all other factors that influence the uncertainty in the coefficient estimates.  The VIF equals 1 when the vector ''X''<sub>''j''</sub> is [[orthogonal]] to each column of the design matrix for the regression of ''X''<sub>''j''</sub> on the other covariates. By contrast, the VIF is greater than 1 when the vector ''X''<sub>''j''</sub> is not orthogonal to all columns of the design matrix for the regression of ''X''<sub>''j''</sub> on the other covariates.  Finally, note that the VIF is invariant to the scaling of the variables (that is, we could scale each variable ''X''<sub>''j''</sub> by a constant ''c''<sub>''j''</sub> without changing the VIF).
 
==Calculation and analysis==
 
The VIF can be calculated and analyzed in three steps:
 
=== Step one ===
Calculate ''k'' different VIFs, one for each ''X''<sub>''i''</sub> by first running an ordinary least square regression that has ''X''<sub>''i''</sub> as a function of all the other explanatory variables in the first equation.<br /> If ''i'' = 1, for example, the equation would be
:<math>X_1=\alpha_2 X_2 + \alpha_3 X_3 + \cdots + \alpha_k X_k + c_0 +e</math>
 
where ''c''<sub>0</sub> is a constant and ''e'' is the [[errors and residuals in statistics|error term]].
 
=== Step two ===
 
Then, calculate the VIF factor for <math>\hat\beta_i</math> with the following formula:
 
: <math>\mathrm{VIF}= \frac{1}{1-R^2_i}</math>
 
where ''R''<sup>2</sup><sub>''i''</sub> is the [[coefficient of determination]] of the regression equation in step one, but with <math> X_i </math> on the left hand side, and all other predictor variables (all the other X variables) on the right hand side.
 
=== Step three ===
Analyze the magnitude of [[multicollinearity]] by considering the size of the <math>\operatorname{VIF}(\hat \beta_i)</math>. A common rule of thumb is that if <math>\operatorname{VIF}(\hat \beta_i) > 5</math> then multicollinearity is high. Also 10 has been proposed (see Kutner book referenced below) as a cut off value.
 
Some software calculates the tolerance which is just the reciprocal of the VIF. The choice of which to use is a matter of personal preference of the researcher.
 
== Interpretation ==
The square root of the variance inflation factor tells you how much larger the standard error is, compared with what it would be if that variable were uncorrelated with the other predictor variables in the model.
 
'''Example'''<br />
If the variance inflation factor of a predictor variable were 5.27 (√5.27&nbsp;=&nbsp;2.3) this means that the standard error for the coefficient of that predictor variable is 2.3 times as large as it would be if that predictor variable were uncorrelated with the other predictor variables.
 
==References==
*Longnecker, M.T & Ott, R.L :''A First Course in Statistical Methods'', page 615. Thomson Brooks/Cole, 2004.
*Studenmund, A.H: ''Using Econometrics: A practical guide'', 5th Edition, page 258&ndash;259. Pearson International Edition, 2006.
*Hair JF, Anderson R, Tatham RL, Black WC: ''Multivariate Data Analysis''. Prentice Hall: Upper Saddle River, N.J. 2006.
*Marquardt, D.W. 1970 "Generalized Inverses, Ridge Regression, Biased Linear Estimation, and Nonlinear Estimation", ''Technometrics'' 12(3), 591, 605&ndash;07
*Allison, P.D. ''Multiple Regression: a primer'', page 142.  Pine Forge Press: Thousand Oaks, C.A. 1999.
*Kutner MH, Nachtsheim CJ, Neter J, ''Applied Linear Regression Models'', 4th edition, McGraw-Hill Irwin, 2004.
 
[[Category:Regression diagnostics]]
[[Category:Statistical ratios]]
 
[[de:Multikollinearit%C3%A4t#Varianzinflationsfaktor]]

Revision as of 17:27, 24 December 2013

Template:No footnotes

In statistics, the variance inflation factor (VIF) quantifies the severity of multicollinearity in an ordinary least squares regression analysis. It provides an index that measures how much the variance (the square of the estimate's standard deviation) of an estimated regression coefficient is increased because of collinearity.

Definition

Consider the following linear model with k independent variables:

Y = β0 + β1 X1 + β2 X 2 + ... + βk Xk + ε.

The standard error of the estimate of βj is the square root of the j+1, j+1 element of s2(XX)−1, where s is the root mean squared error (RMSE) (note that RMSE2 is an unbiased estimator of the true variance of the error term, σ2); X is the regression design matrix — a matrix such that Xi, j+1 is the value of the jth independent variable for the ith case or observation, and such that Xi, 1 equals 1 for all i. It turns out that the square of this standard error, the estimated variance of the estimate of βj, can be equivalently expressed asPotter or Ceramic Artist Truman Bedell from Rexton, has interests which include ceramics, best property developers in singapore developers in singapore and scrabble. Was especially enthused after visiting Alejandro de Humboldt National Park.

var^(β^j)=s2(n1)var^(Xj)11Rj2,

where Rj2 is the multiple R2 for the regression of Xj on the other covariates (a regression that does not involve the response variable Y). This identity separates the influences of several distinct factors on the variance of the coefficient estimate:

  • s2: greater scatter in the data around the regression surface leads to proportionately more variance in the coefficient estimates
  • n: greater sample size results in proportionately less variance in the coefficient estimates
  • var^(Xj): greater variability in a particular covariate leads to proportionately less variance in the corresponding coefficient estimate

The remaining term, 1 / (1 − Rj2) is the VIF. It reflects all other factors that influence the uncertainty in the coefficient estimates. The VIF equals 1 when the vector Xj is orthogonal to each column of the design matrix for the regression of Xj on the other covariates. By contrast, the VIF is greater than 1 when the vector Xj is not orthogonal to all columns of the design matrix for the regression of Xj on the other covariates. Finally, note that the VIF is invariant to the scaling of the variables (that is, we could scale each variable Xj by a constant cj without changing the VIF).

Calculation and analysis

The VIF can be calculated and analyzed in three steps:

Step one

Calculate k different VIFs, one for each Xi by first running an ordinary least square regression that has Xi as a function of all the other explanatory variables in the first equation.
If i = 1, for example, the equation would be

X1=α2X2+α3X3++αkXk+c0+e

where c0 is a constant and e is the error term.

Step two

Then, calculate the VIF factor for β^i with the following formula:

VIF=11Ri2

where R2i is the coefficient of determination of the regression equation in step one, but with Xi on the left hand side, and all other predictor variables (all the other X variables) on the right hand side.

Step three

Analyze the magnitude of multicollinearity by considering the size of the VIF(β^i). A common rule of thumb is that if VIF(β^i)>5 then multicollinearity is high. Also 10 has been proposed (see Kutner book referenced below) as a cut off value.

Some software calculates the tolerance which is just the reciprocal of the VIF. The choice of which to use is a matter of personal preference of the researcher.

Interpretation

The square root of the variance inflation factor tells you how much larger the standard error is, compared with what it would be if that variable were uncorrelated with the other predictor variables in the model.

Example
If the variance inflation factor of a predictor variable were 5.27 (√5.27 = 2.3) this means that the standard error for the coefficient of that predictor variable is 2.3 times as large as it would be if that predictor variable were uncorrelated with the other predictor variables.

References

  • Longnecker, M.T & Ott, R.L :A First Course in Statistical Methods, page 615. Thomson Brooks/Cole, 2004.
  • Studenmund, A.H: Using Econometrics: A practical guide, 5th Edition, page 258–259. Pearson International Edition, 2006.
  • Hair JF, Anderson R, Tatham RL, Black WC: Multivariate Data Analysis. Prentice Hall: Upper Saddle River, N.J. 2006.
  • Marquardt, D.W. 1970 "Generalized Inverses, Ridge Regression, Biased Linear Estimation, and Nonlinear Estimation", Technometrics 12(3), 591, 605–07
  • Allison, P.D. Multiple Regression: a primer, page 142. Pine Forge Press: Thousand Oaks, C.A. 1999.
  • Kutner MH, Nachtsheim CJ, Neter J, Applied Linear Regression Models, 4th edition, McGraw-Hill Irwin, 2004.

de:Multikollinearität#Varianzinflationsfaktor