|
Size: 1860
Comment: Rewrite 2
|
Size: 2164
Comment: Rewrite of coefficients section
|
| Deletions are marked like this. | Additions are marked like this. |
| Line 23: | Line 23: |
| The proof can be seen [[Econometrics/OrdinaryLeastSquares/UnivariateProof|here]]. | The derivation can be seen [[Econometrics/OrdinaryLeastSquares/Univariate|here]]. |
| Line 39: | Line 39: |
| More conventionally, this is estimated with [[LinearAlgebra|linear algebra]] as: {{attachment:matrix.svg}} The derivation can be seen [[Econometrics/OrdinaryLeastSquares/Multivariate|here]]. |
|
| Line 45: | Line 51: |
| If these assumptions can be made: | The '''Gauss-Markov theorem''' demonstrates that (with some assumptions) the OLS estimations are the '''best linear unbiased estimators''' ('''BLUE''') for the regression coefficients. The assumptions are: |
| Line 50: | Line 56: |
| 4. No perfect multicolinearity | 4. No perfect [[LinearAlgebra/Basis|multicolinearity]] |
| Line 52: | Line 58: |
Then OLS is the best linear unbiased estimator ('''BLUE''') for regression coefficients. |
Ordinary Least Squares
Ordinary Least Squares (OLS) is a linear regression method. It minimizes root mean square errors.
Univariate
Given one independent variable and one dependent (outcome) variable, the OLS model is specified as:
It is estimated as:
This model describes (1) the mean observation and (2) the marginal changes to the outcome per unit changes in the independent variable.
The derivation can be seen here.
Multivariate
Given k independent variables, the OLS model is specified as:
It is estimated as:
More conventionally, this is estimated with linear algebra as:
The derivation can be seen here.
Estimated Coefficients
The Gauss-Markov theorem demonstrates that (with some assumptions) the OLS estimations are the best linear unbiased estimators (BLUE) for the regression coefficients. The assumptions are:
- Linearity
- Random sampling
No perfect multicolinearity
The variances for each coefficient are:
![[ATTACH]](/Statistics/OrdinaryLeastSquares?action=AttachFile&do=upload_form&target=homo1.svg&ticket=0069eb405d.a53a4920348741bedbfe5a4542564e7b3f2e28e5 "[ATTACH]"){kind=small}
Note that the standard deviation of the population's parameter is unknown, so it's estimated like:
![[ATTACH]](/Statistics/OrdinaryLeastSquares?action=AttachFile&do=upload_form&target=homo2.svg&ticket=0069eb405d.a53a4920348741bedbfe5a4542564e7b3f2e28e5 "[ATTACH]"){kind=small}
If the homoskedasticity assumption does not hold, then the estimators for each coefficient are actually:
![[ATTACH]](/Statistics/OrdinaryLeastSquares?action=AttachFile&do=upload_form&target=hetero1.svg&ticket=0069eb405d.a53a4920348741bedbfe5a4542564e7b3f2e28e5 "[ATTACH]"){kind=small}
Wherein, for example, r1j is the residual from regressing x1 onto x2, ... xk.
The variances for each coefficient can be estimated with the Eicker-White formula:
![[ATTACH]](/Statistics/OrdinaryLeastSquares?action=AttachFile&do=upload_form&target=hetero2.svg&ticket=0069eb405d.a53a4920348741bedbfe5a4542564e7b3f2e28e5 "[ATTACH]"){kind=small}
See Nicolai Kuminoff's video lectures for the derivation of the robust estimators.