INTRODUCTION TO ECONOMETRICS II ECO 306 NOUN 61 This condition states that there should be no systematic association between the values of the disturbance term in any two observations. For example, just because the disturbance term is large and
positive in one observation, there should be no tendency for it to be large and positive in the next (or large and negative, for that matter,
or small and positive, or small and negative. The values of the disturbance term should be independent of one another. The condition implies that
μiμj, the population covariance between
μiandμj, is 0, because
μiμj =E[(
μi–
μu)(
μj–
μu)] =
E(
μiμj) =
E(
μi)
E(
μj) = 0
…[2.29] where,
u is a value in
μ as shown in (
1
u) of Figure 2.0 Note
that the population means of μiandμjare 0, by the first Gauss–Markov condition, and that
E(
μiμj)
can be decomposed as E(
μi)
E(
μj) if
μiandμjare generated independently. If this condition is not satisfied, OLS will again give inefficient estimates.
2.2.3.2.4 Gauss–Markov Condition 4: u Distributed Independently of the Explanatory Variables The final condition comes in two versions, weak and strong. The strong version is that the explanatory variables should be non-stochastic, that is, not have random components. This is very unrealistic
for economic variables, and we will eventually switch to the weak version of the condition, where the explanatory variables are allowed to have random components provided that they are distributed independently of the disturbance term. However, the strong version is usually used because it simplifies the analysis of the properties of the estimators.
iXiu,*
iX(
iX)+*
iu+- (
iXiX) (
iu)
…[2.30]
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