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• • •
The True Model
OLS in Matrix Form
Let X be an n × k matrix where we have observations on k independent variables for n observations. Since our model will usually contain a constant term, one of the columns in the X matrix will contain only ones. This column should be treated exactly the same as any other column in the X matrix.
Let y be an n × 1 vector of observations on the dependent variable.
Let ε be an n × 1 vector of disturbances or errors.
Let β be an k × 1 vector of unknown population parameters that we want to estimate.
Our statistical model will essentially look something like the following: Y1XX…Xβε
11121 k111
Y2  1 X12 X22 … Xk2  β2  ε2 
 .  = . . . … .   .  + . 
 .   . . . .   .   .  .……...
Yn n×1 1 X1n X2n … Xkn n×k βn k×1 This can be rewritten more simply as:
y = Xβ + ε
εn n×1
This is assumed to be an accurate reflection of the real world. The model has a systematic com- ponent (Xβ) and a stochastic component (ε). Our goal is to obtain estimates of the population parameters in the β vector.
2 Criteria for Estimates
Our estimates of the population parameters are referred to as βˆ. Recall that the criteria we use for obtaining our estimates is to find the estimator βˆ that minimizes the sum of squared residuals (􏰢 e2i in scalar notation).1 Why this criteria? Where does this criteria come from?
The vector of residuals e is given by:
1Make sure that you are always careful about distinguishing between disturbances (ε) that refer to things that
e = y − Xβˆ (2) cannot be observed and residuals (e) that can be observed. It is important to remember that ε ̸= e.
(1)
1

The sum of squared residuals (RSS) is e′e.2 e
.
en
It should be obvious that we can write the sum of squared residuals as:
(y′Xβˆ)′ = βˆ′X′y.
To find the βˆ that minimizes the sum of squared residuals, we need to take the derivative of Eq. 4
with respect to βˆ. This gives us the following equation:
∂e′e = −2X′y + 2X′Xβˆ = 0 (5)
To check this is a minimum, we would take the derivative of this with respect to βˆ again – this gives us 2X′X. It is easy to see that, so long as X has full rank, this is a positive definite matrix (analogous to a positive real number) and hence a minimum.3
2It is important to note that this is very different from ee′ – the variance-covariance matrix of residuals. 3Here is a brief overview of matrix differentiaton.
􏰣e e … … e 􏰤  .  12 n1×n.
=􏰣e ×e +e ×e +…+e ×e 􏰤 (3)
1  e2 
n×1
(y − Xβˆ)′(y − Xβˆ)
e′e =
= y′y − βˆ′X′y − y′Xβˆ + βˆ′X′Xβˆ
= y′y − 2βˆ′X′y + βˆ′X′Xβˆ
(4) where this development uses the fact that the transpose of a scalar is the scalar i.e. y′Xβˆ =
1 1 2 2
n n 1×1
∂βˆ
when a and b are K×1 vectors.
∂a′b = ∂b′a = a (6) ∂b ∂b
∂b′Ab = 2Ab = 2b′A (7) ∂b
when A is any symmetric matrix. Note that you can write the derivative as either 2Ab or 2b′A.
∂2β′X′y = ∂2β′(X′y) = 2X′y (8)
and
∂b ∂b
∂β′X′Xβ = ∂β′Aβ = 2Aβ = 2X′Xβ (9) ∂b ∂b
when X′X is a K×K matrix. For more information, see Greene (2003, 837-841) and Gujarati (2003, 925).
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From Eq. 5 we get what are called the ‘normal equations’.
(X′X)βˆ = X′y (10)
Two things to note about the (X′X) matrix. First, it is always square since it is k × k. Second, it is always symmetric.
Recall that (X′X) and X′y are known from our data but βˆ is unknown. If the inverse of (X′X) exists (i.e. (X′X)−1), then pre-multiplying both sides by this inverse gives us the following equation:4
(X′X)−1(X′X)βˆ = (X′X)−1X′y (11) We know that by definition, (X′X)−1(X′X) = I, where I in this case is a k × k identity matrix.
This gives us:
Iβˆ = (X′X)−1X′y
βˆ = (X ′ X )−1 X ′ y (12)
Note that we have not had to make any assumptions to get this far! Since the OLS estimators in the βˆ vector are a linear combination of existing random variables (X and y), they themselves are random variables with certain straightforward properties.
3 Properties of the OLS Estimators
The primary property of OLS estimators is that they satisfy the criteria of minimizing the sum of squared residuals. However, there are other properties. These properties do not depend on any assumptions – they will always be true so long as we compute them in the manner just shown.
Recall the normal form equations from earlier in Eq. 10.
(X′X)βˆ = X′y (13)
Now substitute in y = Xβˆ + e to get
(X′X)βˆ = X′(Xβˆ + e) (X′X)βˆ = (X′X)βˆ + X′e
X′e = 0 (14)
4The inverse of (X′X) may not exist. If this is the case, then this matrix is called non-invertible or singular and is said to be of less than full rank. There are two possible reasons why this matrix might be non-invertible. One, based on a trivial theorem about rank, is that n < k i.e. we have more independent variables than observations. This is unlikely to be a problem for us in practice. The other is that one or more of the independent variables are a linear combination of the other variables i.e. perfect multicollinearity. 3 What does X′e look like? X X ...XeX×e+X×e+...+X×e0 11 12 1n111 1 12 2 1n n  X21 X22 ... X2n  e2   X21 ×e1 +X22 ×e2 +...+X2n ×en   0   . . . .  . = . =. (15)  . . . .  .   .   .  ..... . . Xk1 Xk2 ... Xkn en Xk1 ×e1 +Xk2 ×e2 +...+Xkn ×en 0 From X′e = 0, we can derive a number of properties. 1. The observed values of X are uncorrelated with the residuals. X′e = 0 implies that for every column xk of X, x′ke = 0. In other words, each regressor has zero sample correlation with the residuals. Note that this does not mean that X is un- correlated with the disturbances; we’ll have to assume this. If our regression includes a constant, then the following properties also hold. 2. The sum of the residuals is zero. If there is a constant, then the first column in X (i.e. X1) will be a column of ones. This means that for the first element in the X′e vector (i.e. X11 ×e1 +X12 ×e2 +...+X1n ×en) to be zero, it must be the case that 􏰢ei = 0. 3. The sample mean of the residuals is zero. This follows straightforwardly from the previous property i.e. e = n i = 0. 􏰢e 4. The regression hyperplane passes through the means of the observed values (X and y). This follows from the fact that e = 0. Recall that e = y − Xβˆ. Dividing by the number of observations, we get e = y − xβˆ = 0. This implies that y = xβˆ. This shows that the regression hyperplane goes through the point of means of the data. 5. The predicted values of y are uncorrelated with the residuals. The predicted values of y are equal to Xβˆ i.e. yˆ = Xβˆ. From this we have yˆ′e = (Xβˆ)′e = b′X′e = 0 (16) This last development takes account of the fact that X′e = 0. 6. The mean of the predicted Y’s for the sample will equal the mean of the observed Y’s i.e. yˆ = y. 4 These properties always hold true. You should be careful not to infer anything from the residuals about the disturbances. For example, you cannot infer that the sum of the disturbances is zero or that the mean of the disturbances is zero just because this is true of the residuals - this is true of the residuals just because we decided to minimize the sum of squared residuals. Note that we know nothing about βˆ except that it satisfies all of the properties discussed above. We need to make some assumptions about the true model in order to make any inferences regarding β (the true population parameters) from βˆ (our estimator of the true parameters). Recall that βˆ comes from our sample, but we want to learn about the true parameters. 4 The Gauss-Markov Assumptions 1. y=Xβ+ε This assumption states that there is a linear relationship between y and X. 2. X is an n×k matrix of full rank. This assumption states that there is no perfect multicollinearity. In other words, the columns of X are linearly independent. This assumption is known as the identification condition. 3. E[ε|X] = 0 ε1|X E(ε1) 0 ε2|X E(ε2) 0 E . = . = .  (17) εn|X E(εn) 0 This assumption - the zero conditional mean assumption - states that the disturbances average out to 0 for any value of X. Put differently, no observations of the independent variables convey any information about the expected value of the disturbance. The assumption implies that E(y) = Xβ. This is important since it essentially says that we get the mean function right. 4. E(εε′|X) = σ2I This captures the familiar assumption of homoskedasticity and no autocorrelation. To see why, start with the following:  ε1|X  ′  ε2|X 􏰣 􏰤 E(εε|X)=E .  ε1|X ε2|X ... εn|X] εn |X (18) 5 which is the same as: E(εε |X) = E  . which is the same as: ′  E[ε2ε1|X] εnε2|X E[ε1ε2|X] E[ε2|X] . E[εnε2|X] ′  ε2ε1|X εnε1|X ε2|X . . . . . . . . . . . . . . . . . . ε2εn|X  .  (19) ε2n|X E[ε1εn|X]  E[ε2εn|X]  .  (20) E[ε2n|X]  E[ε21|X] E(εε |X) =  .  ε21|X ε1ε2|X ... ε1εn|X  E[εnε1|X] The assumption of homoskedasticity states that the variance of εi is the same (σ2) for all i i.e. var[εi|X] = σ2 ∀ i. The assumption of no autocorrelation (uncorrelated errors) means that cov(εi,εj|X) = 0 ∀ i ̸= j i.e. knowing something about the disturbance term for one observation tells us nothing about the disturbance term for any other observation. With these assumptions, we have: σ2 0...0 ′ 0 σ2 ... 0 E(εε |X) =  . . . .  (21) 0 0 ... σ2 Finally, this can be rewritten as: 10...0 E(εε′|X)=σ2 0 1 ... 0 =σ2I (22) . . . . 00...1 Disturbances that meet the two assumptions of homoskedasticity and no autocorrelation are referred to as spherical disturbances. We can compactly write the Gauss-Markov assumptions about the disturbances as: Ω = σ2I (23) where Ω is the variance-covariance matrix of the disturbances i.e. Ω = E[εε′]. 5. X may be fixed or random, but must be generated by a mechanism that is unrelated to ε. 6. ε|X∼N[0,σ2I] This assumption is not actually required for the Gauss-Markov Theorem. However, we often assume it to make hypothesis testing easier. The Central Limit Theorem is typically evoked to justify this assumption. 6 5 The Gauss-Markov Theorem The Gauss-Markov Theorem states that, conditional on assumptions 1-5, there will be no other linear and unbiased estimator of the β coefficients that has a smaller sampling variance. In other words, the OLS estimator is the Best Linear, Unbiased and Efficient estimator (BLUE). How do we know this? Proof that βˆ is an unbiased estimator of β. We know from earlier that βˆ = (X′X)−1X′y and that y = Xβ + ε. This means that βˆ = (X′X)−1X′(Xβ + ε) βˆ = β + (X′X)−1X′ε since (X′X)−1X′X = I. This shows immediately that OLS is unbiased so long as either (i) fixed (non-stochastic) so that we have: E[βˆ] = E[β] + E[(X′X)−1X′ε] = β + (X′X)−1X′E[ε] where E[ε] = 0 by assumption or (ii) X is stochastic but independent of ε so that we have: E[βˆ] = E[β] + E[(X′X)−1X′ε] (24) X is (25) (26) = β + (X′X)−1E[X′ε] Proof that βˆ is a linear estimator of β. From Eq. 24, we have: where E(X′ε) = 0. βˆ = β + (X′X)−1X′ε disturbances. By the definition that we use, this makes it a linear estimator (See Greene (2003, 45). Proof that βˆ has minimal variance among all linear and unbiased estimators See Greene (2003, 46-47). 7 Since we can write βˆ = β + Aε where A = (X′X)−1X′, we can see that βˆ is a linear function of the (27) 6 The Variance-Covariance Matrix of the OLS Estimates We can derive the variance-covariance matrix of the OLS estimator, βˆ. E[(βˆ − β)(βˆ − β)′] = E[((X′X)−1X′ε)((X′X)−1X′ε)′] = E[(X′X)−1X′εε′X(X′X)−1] (28) where we take advantage of the fact that (AB)′ = B′A′ i.e. we can rewrite (X′X)−1X′ε as ε′X(X′X)−1. If we assume that X is non-stochastic, we get: E[(βˆ − β)(βˆ − β)′] = From Eq. 22, we have E[εε′] = σ2I. Thus, we E[(βˆ − β)(βˆ − β)′] = = = We estimate σ2 with σˆ2, where: (X′X)−1X′E[εε′]X(X′X)−1 (29) have: (X′X)−1X′(σ2I)X(X′X)−1 σ2I(X′X)−1X′X(X′X)−1 σ2(X′X)−1 (30)  var(βˆ1) ˆ ˆ ′  cov(βˆ2, βˆ1) cov(βˆ1, βˆk)  cov(βˆ2, βˆk)  σˆ2= e′e (31) n−k To see the derivation of this, see Greene (2003, 49). What does the variance-covariance matrix of the OLS estimator look like? cov(βˆ1, βˆ2) var(βˆ2) . main diagonal of this matrix. 6.1 Hypothesis Testing Recall Assumption 6 from earlier, which stated that ε|X ∼ N[0,σ2I]. I had stated that this assumption was not necessary for the Gauss-Markov Theorem but was crucial for testing inferences about βˆ. Why? Without this assumption, we know nothing about the distribution of βˆ. How does this assumption about the distribution of the disturbances tell us anything about the distribution of βˆ? Well, we just saw in Eq. 27 that the OLS estimator is just a linear function of the disturbances. By assuming that the disturbances have a multivariate normal distribution i.e. ε ∼ N[0,σ2I] (33) 8 E[(β − β)(β − β) ] =  . cov(βˆk, βˆ1) . . . . . . . .  (32) var(βˆk) cov(βˆk, βˆ2) As you can see, the standard errors of the βˆ are given by the square root of the elements along the . . . we are also saying that the OLS estimator is also distributed multivariate normal i.e. βˆ ∼ N[β,σ2(X′X)−1] (34) but where the mean is β and the variance is σ2(X′X)−1. It is this that allows us to conduct the normal hypothesis tests that we are familiar with. 7 Robust (Huber of White) Standard Errors Recall from Eq. 29 that we have: var − cov(βˆ) = (X′X)−1X′E[εε′]X(X′X)−1 = (X′X)−1(X′ΩX)(X′X)−1 (35) This helps us to make sense of White’s heteroskedasticity consistent standard errors.5 Recall that heteroskedasticity does not cause problems for estimating the coefficients; it only causes problems for getting the ‘correct’ standard errors. We can compute βˆ without making any as- sumptions about the disturbances i.e. βˆOLS = (X′X)−1X′y. However, to get the results of the Gauss Markov Theorem (things like E[βˆ] = β etc.) and to be able to conduct hypothesis tests (βˆ ∼ N[β,σ2(X′X)−1]), we need to make assumptions about the disturbances. One of the as- sumptions is that E[ee′] = σ2I. This assumption includes the assumption of homoskedasticity – var[εi|X] = σ2 ∀ i. However, it is not always the case that the variance will be the same for all observations i.e. we have σi2 instead of σ2. Basically, there may be many reasons why we are better at predicting some observations than others. Recall the variance-covariance matrix of the disturbance terms from earlier:  E[ε21|X] ′  E[ε2ε1|X] E(εε |X) = Ω =  . E[εnε1|X] E[ε1ε2|X] E[ε2|X] . . . . . . . . E[ε1εn|X]  E[ε2εn|X]  .  (36) E[ε2n|X] E[εnε2|X] If we retain the assumption of no autocorrelation, this can be rewritten as:  σ 12 0 . . . 0  ′ 0 σ2 ... 0 E(εε|X)=Ω= . . . .  0 0 ... σn2 (37) Basically, the main diagonal contains n variances of εi. The assumption of homoskedasticity states that each of these n variances are the same i.e. σi2 = σ2. But this is not always an appropriate 5As we’ll see later in the semester, it also helps us make sense of Beck and Katz’s panel-corrected standard errors. 9 . . . assumption to make. Our OLS standard errors will be incorrect insofar as: X′E[εε′]X ̸= σ2(X′X) (38) Note that our OLS standard errors may be too big or too small. So, what can we do if we suspect that there is heteroskedasticity? Essentially, there are two options. 1. Weighted Least Squares: To solve the problem, we just need to find something that is proportional to the variance. We might not know the variance for each observation, but if we know something about where it comes from, then we might know something that is proportional to it. In effect, we try to model the variance. Note that this only solves the problem of heteroskedasticity if we assume that we have modelled the variance correctly - we never know if this is true or not. 2. Robust standard errors (White 1980): This method treats heteroskedasticity as a nuisance rather than something to be modelled. How do robust standard errors work? We never observe disturbances (ε) but we do observe residuals (e). While each individual residual (ei) is not going to be a very good estimator of the corresponding disturbance (εi), White (1980) showed that X′ee′X is a consistent (but not unbiased) estimator of X′E[εε′]X.6 Thus, the variance-covariance matrix of the coefficient vector from the White estimator is: var − cov(βˆ) = (X′X)−1X′ee′X(X′X)−1 (39) rather than: var − cov(βˆ) = X′X)−1X′εε′X(X′X)−1 = (X′X)−1X′(σ2I)X(X′X)−1 (40) from the normal OLS estimator. White (1980) suggested that we could test for the presence of heteroskedasticity by examining the extent to which the OLS estimator diverges from his own estimator. White’s test is to regress the squared residuals (e2i ) on the terms in X′X i.e. on the squares and the cross-products of the independent variables. If the R2 exceeds a critical value (nR2 ∼ χ2k), then heteroskedasticity causes problems. At that point use the White estimator (assuming your sample is sufficiently large). Neal Beck suggests that, by and large, using the White estimator can do little harm and some good. 6It is worth remembering that X′ee′X is a consistent (but not unbiased) estimator of X′E[εε′]X since this means that robust standard errors are only appropriate when the sample is relatively large (say, greater than 100 degrees of freedom). 10 8 Partitioned Regression and the Frisch-Waugh-Lovell Theorem Imagine that our true model is: y = X1β1 + X2β2 + ε (41) In other words, there are two sets of independent variables. For example, X1 might contain some independent variables (perhaps also the constant) whereas X2 contains some other independent variables. The point is that X1 and X2 need not be two variables only. We will estimate: y = X1βˆ1 + X2βˆ2 + e (42) Say, we wanted to isolate the coefficients associated with X2 i.e. βˆ2. The normal form equations will be:7 8.1 Omitted Variable Bias (1)􏰥X′X X′X􏰦􏰥βˆ􏰦 􏰥X′y􏰦 1 1 1 2 ˆ1 = 1 (43) (2) X2′ X1 X2′ X2 β2 X2′ y 1 First, let’s solve for βˆ . (X′X )βˆ +(X′X )βˆ = X′y 111 122 1 (X′X )βˆ = X′y−(X′X )βˆ 111 1 122 βˆ = (X′X )−1X′y−(X′X )−1X′X βˆ 111111122 βˆ = (X′X )−1X′(y−X βˆ) (44) 111122 The solution shown in Eq. 44 is the set of OLS coefficients in the regression of y on X1, i.e, (X′ X )−1X′ y, minus a correction vector (X′ X )−1X′ X βˆ . This correction vector is the equation 11 1 11 122 ˆ ′ −1′ for omitted variable bias. The first part of the correction vector up to β2, i.e. (X1X1) X1X2, is just the regression of the variables in X2 done separately and then put together into a matrix on all the variables in X1. This will only be zero if the variables in X1 are linearly unrelated (uncorrelated or orthogonal) to the variables in X . The correction vector will also be zero if βˆ = 0 i.e. if X 222 variables have no impact on y. Thus, you can ignore all potential omitted variables that are either (i) unrelated to the included variables or (ii) unrelated to the dependent variable. Any omitted variables that do not meet these conditions will change your estimates of βˆ if they were to be 1 included. Greene (2003, 148) writes the omitted variable formula slightly differently. He has E[b1] = β1 + P1.2β2 (45) where P1.2 = (X1′X1)−1X1′X2, where b1 is the coefficient vector of a regression omitting the X2 7To see this, compare with Eq. 10. 11 matrix, and β1 and β2 are the true coefficient vectors from a full regression including both X1 and X2. 8.2 The Residual Maker and the Hat Matrix Before going any further, I introduce some useful matrices. Note that: e = y−Xβˆ = y − X(X′X)−1X′y = (I − X(X′X)−1X′)y = My (46) where M is called the residual maker since it makes residuals out of y. M is a square matrix and is idempotent. A matrix A is idempotent if A2 = AA = A. This will prove useful. The M matrix also has the properties that MX = 0 and Me = e. A related matrix is the hat matrix (H) which makes yˆ our of y. Note that: yˆ = y − e = [ I − M ] y = H y (48) where: H = X(X′X)−1X′ (49) Greene refers to this matrix as P, but he is the only one that does this. 8.3 Frisch-Waugh-Lovell Theorem So far we have solved for βˆ . 1 (I − X(X′X)−1X′)(I − X(X′X)−1X′) MM = = I2 − 2X(X′X)−1X′ + X(X′X)−1X′X(X′X)−1X′ = I − 2X(X′X)−1X′ + X(X′X)−1X′ = I − X(X′X)−1X′ =M (47) βˆ = (X′X )−1X′(y−X βˆ) (50) 111122 12 Now we insert this into (2) of Eq. 43. This gives us X′y = X′X (X′X )−1X′y−X′X (X′X )−1X′X βˆ +X′X βˆ 2 2111 1 2111 122 222 X′y−X′X (X′X )−1X′y = X′X βˆ −X′X (X′X )−1X′X βˆ 2 2111 1 222 2111 122 X′y−X′X (X′X )−1X′y = [X′X −X′X (X′X )−1X′X ]βˆ 221111222111122 X′y−X′X (X′X )−1X′y = [(X′ −X′X (X′X )−1X′)X ]βˆ 22111122111122 X′y−X′X (X′X )−1X′y = [X′(I−X (X′X )−1X′)X ]βˆ 221111 2111122 (X′ −X′X (X′X )−1X′)y = [X′(I −X (X′X )−1X′)X ]βˆ 221111 2 111122 X′(I −X (X′X )−1X′)y = [X′(I −X (X′X )−1X′)X ]βˆ 2 1111 2 111122 βˆ = 2 = [X′(I −X (X′X )−1X′)X ]−1X′(I −X (X′X )−1X′)y 2 111122 1111 (X2′ M1X2)−1(X2′ M1y) (51) Recall that M is the residual maker. In this case, M1 makes residuals for regressions on the X1 variables: M1y is the vector of residuals from regressing y on the X1 variables and M1X2 is the matrix made up of the column by column residuals of regressing each variable (column) in X2 on all the variables in X1. Because M is both idempotent and symmetric, we can rewrite Eq. 51 as βˆ =(X∗′X )−1X∗′y∗ (52) 2222 where X2∗ = M1X2 and y∗ = M1y. From this it is easy to see that βˆ can be obtained from regressing y∗ on X∗ (you’ll get good at 22 spotting regressions i.e. equations of the (X′X)−1X′y form. The starred variables are just the residuals of the variables (y or X2) after regressing them on the X1 variables. This leads to the Frisch-Waugh-Lovell Theorem: In the OLS regression of vector y on two sets of variables, X and X , the subvector βˆ is the set of coefficients obtained when the residuals from 122 a regression of y on X1 alone are regressed on the set of residuals obtained when each column of X2 is regressed on X1. We’ll come back to the FWL Theorem when we look at fixed effects models. 8.4 Example Imagine we have the following model. Y =β0 +β1X1 +β2X2 +β3X3 +ε (53) If we regressed Y on X , X , and X , we would get βˆ, βˆ, βˆ. We could get these estimators 123123 differently. Say we partitioned the variables into (i) X1 and (ii) X2 and X3. Step 1: regress Y on X1 and obtain residuals (e1) i.e. M1y. 13 Step 2: regress X2 on X1 and obtain residuals (e2) i.e. first column of M1X2. Step 3: regress X3 on X1 and obtain residuals (e3) i.e. second column of M1X2. Step 4: regress e1 on e2 and e3 i.e. regress M1y on M1X2. Step 5: the coefficient on e2 will be βˆ and the coefficient on e3 will be βˆ . 23 Steps 2 and 3 are called partialing out or netting out the effect of X1. For this reason, the coefficients in multiple regression are often called partial regression coefficients. This is what it means to say we are holding the X1 variables constant in the regression. So the difference between regressing Y on both X1 and X2 instead of on just X2 is that in the first case we first regress both the dependent variables and all the X2 variables separately on X1 and then regress the residuals on each other, but in the second case we just regress y on the X2 variables. 14