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Frisch–Waugh–Lovell theorem

The Frisch–Waugh–Lovell theorem states that if the regression we are concerned with is expressed in terms of two separate sets of predictor variables:

${\displaystyle Y=X_{1}\beta _{1}+X_{2}\beta _{2}+u}$

where ${\displaystyle X_{1}}$ and ${\displaystyle X_{2}}$ are matrices, ${\displaystyle \beta _{1}}$ and ${\displaystyle \beta _{2}}$ are vectors (and ${\displaystyle u}$ is the error term), then the estimate of ${\displaystyle \beta _{2}}$ will be the same as the estimate of it from a modified regression of the form:

${\displaystyle M_{X_{1}}Y=M_{X_{1}}X_{2}\beta _{2}+M_{X_{1}}u,}$

where ${\displaystyle M_{X_{1}}}$ projects onto the orthogonal complement of the image of the projection matrix ${\displaystyle X_{1}(X_{1}^{\mathsf {T}}X_{1})^{-1}X_{1}^{\mathsf {T}}}$. Equivalently, M_X1 projects onto the orthogonal complement of the column space of X₁. Specifically,

${\displaystyle M_{X_{1}}=I-X_{1}(X_{1}^{\mathsf {T}}X_{1})^{-1}X_{1}^{\mathsf {T}},}$

and this particular orthogonal projection matrix is known as the residual maker matrix or annihilator matrix.^[4][5]

The vector ${\textstyle M_{X_{1}}Y}$ is the vector of residuals from regression of ${\textstyle Y}$ on the columns of ${\textstyle X_{1}}$.

The most relevant consequence of the theorem is that the parameters in ${\textstyle \beta _{2}}$ do not apply to ${\textstyle X_{2}}$ but to ${\textstyle M_{X_{1}}X_{2}}$, that is: the part of ${\textstyle X_{2}}$ uncorrelated with ${\textstyle X_{1}}$. This is the basis for understanding the contribution of each single variable to a multivariate regression (see, for instance, Ch. 13 in ^[6]).

The theorem also implies that the secondary regression used for obtaining ${\displaystyle M_{X_{1}}}$ is unnecessary when the predictor variables are uncorrelated: using projection matrices to make the explanatory variables orthogonal to each other will lead to the same results as running the regression with all non-orthogonal explanators included.

Moreover, the standard errors from the partial regression equal those from the full regression.^[7]

History[edit]

The origin of the theorem is uncertain, but it was well-established in the realm of linear regression before the Frisch and Waugh paper. George Udny Yule's comprehensive analysis of partial regressions, published in 1907, included the theorem in section 9 on page 184.^[8] Yule emphasized the theorem's importance for understanding multiple and partial regression and correlation coefficients, as mentioned in section 10 of the same paper.^[8]

By 1933, Yule's findings were generally recognized^{[weasel words]}, thanks in part to the detailed discussion of partial correlation and the introduction of his innovative notation in 1907.^{[citation needed]} The theorem, later associated with Frisch, Waugh, and Lovell, was also included in chapter 10 of Yule's successful statistics textbook, first published in 1911. The book reached its tenth edition by 1932.^[9]

In a 1931 paper co-authored with Mudgett, Frisch cited Yule's results.^[10] Yule's formulas for partial regressions were quoted and explicitly attributed to him in order to rectify a misquotation by another author.^[10] Although Yule was not explicitly mentioned in the 1933 paper by Frisch and Waugh, they utilized the notation for partial regression coefficients initially introduced by Yule in 1907, which was widely accepted by 1933^{[original research?]}.

In 1963, Lovell published a proof^[11] considered more straightforward and intuitive. In recognition, people generally add his name to the theorem name.

References[edit]

Further reading[edit]

• Davidson, Russell; MacKinnon, James G. (1993). Estimation and Inference in Econometrics. New York: Oxford University Press. pp. 19–24. ISBN 0-19-506011-3.
• Davidson, Russell; MacKinnon, James G. (2004). Econometric Theory and Methods. New York: Oxford University Press. pp. 62–75. ISBN 0-19-512372-7.
• Hastie, Trevor; Tibshirani, Robert; Friedman, Jerome (2017). "Multiple Regression from Simple Univariate Regression" (PDF). The Elements of Statistical Learning : Data Mining, Inference, and Prediction (2nd ed.). New York: Springer. pp. 52–55. ISBN 978-0-387-84857-0.
• Ruud, P. A. (2000). An Introduction to Classical Econometric Theory. New York: Oxford University Press. pp. 54–60. ISBN 0-19-511164-8.
• Stachurski, John (2016). A Primer in Econometric Theory. MIT Press. pp. 311–314. ISBN 9780262337465.