经济代写|ECON2300 Econometrics

Exercise 2.19 Show (2.46)-(2.47), namely that for
$$
d(\boldsymbol{\beta})=\mathbb{E}\left[\left(m(\boldsymbol{x})-\boldsymbol{x}^{\prime} \boldsymbol{\beta}\right)^2\right]
$$
then
$$
\begin{aligned}
\boldsymbol{\beta} & =\underset{\boldsymbol{b} \in \mathbb{R}^k}{\operatorname{argmin}} d(\boldsymbol{b}) \
& =\left(\mathbb{E}\left[\boldsymbol{x} \boldsymbol{x}^{\prime}\right]\right)^{-1} \mathbb{E}[\boldsymbol{x} m(\boldsymbol{x})] \
& =\left(\mathbb{E}\left[\boldsymbol{x} \boldsymbol{x}^{\prime}\right]\right)^{-1} \mathbb{E}[\boldsymbol{x} y] .
\end{aligned}
$$
Hint: To show $\mathbb{E}[\boldsymbol{x} m(\boldsymbol{x})]=\mathbb{E}[\boldsymbol{x} y]$ use the law of iterated expectations.

Exercise 2.20 Verify that (2.54) holds with $m(\boldsymbol{x})$ defined in $(2.5)$ when $(y, \boldsymbol{x})$ have a joint density $f(y, \boldsymbol{x})$.
Exercise 2.21 Consider the short and long projections
$$
\begin{gathered}
y=x \gamma_1+e \
y=x \beta_1+x^2 \beta_2+u
\end{gathered}
$$

(a) Under what condition does $\gamma_1=\beta_1$ ?
(b) Now suppose the long projection is
$$
y=x \theta_1+x^3 \theta_2+v
$$
Is there a similar condition under which $\gamma_1=\theta_1$ ?

Exercise 2.22 Take the homoskedastic model
$$
\begin{aligned}
y & =\boldsymbol{x}_1^{\prime} \boldsymbol{\beta}_1+\boldsymbol{x}_2^{\prime} \boldsymbol{\beta}_2+e \
\mathbb{E}\left[e \mid \boldsymbol{x}_1, \boldsymbol{x}_2\right] & =0 \
\mathbb{E}\left[e^2 \mid \boldsymbol{x}_1, \boldsymbol{x}_2\right] & =\sigma^2 \
\mathbb{E}\left[\boldsymbol{x}_2 \mid \boldsymbol{x}_1\right] & =\boldsymbol{\Gamma} \boldsymbol{x}_1 \
\boldsymbol{\Gamma} & \neq 0 .
\end{aligned}
$$
Suppose the parameter $\boldsymbol{\beta}_1$ is of interest. We know that the exclusion of $\boldsymbol{x}_2$ creates omited variable bias in the projection coefficient on $\boldsymbol{x}_2$. It also changes the equation error. Our question is: what is the effect on the homoskedasticity property of the induced equation error? Does the exclusion of $\boldsymbol{x}_2$ induce heteroskedasticity or not? Be specific.

Exercise 3.1 Let $y$ be a random variable with $\mu=\mathbb{E}[y]$ and $\sigma^2=\operatorname{var}[y]$. Define
$$
g\left(y, \mu, \sigma^2\right)=\left(\begin{array}{c}
y-\mu \
(y-\mu)^2-\sigma^2
\end{array}\right) .
$$
Let $\left(\widehat{\mu}, \widehat{\sigma}^2\right)$ be the values such that $\bar{g}n\left(\widehat{\mu}, \widehat{\sigma}^2\right)=\mathbf{0}$ where $\bar{g}_n(m, s)=n^{-1} \sum{i=1}^n g\left(y_i, m, s\right)$. Show that $\widehat{\mu}$ and $\widehat{\sigma}^2$ are the sample mean and variance.

Exercise 3.2 Consider the OLS regression of the $n \times 1$ vector $\boldsymbol{y}$ on the $n \times k$ matrix $\boldsymbol{X}$. Consider an alternative set of regressors $\boldsymbol{Z}=\boldsymbol{X} \boldsymbol{C}$, where $\boldsymbol{C}$ is a $k \times k$ non-singular matrix. Thus, each column of $\boldsymbol{Z}$ is a mixture of some of the columns of $\boldsymbol{X}$. Compare the OLS estimates and residuals from the regression of $\boldsymbol{y}$ on $\boldsymbol{X}$ to the OLS estimates from the regression of $\boldsymbol{y}$ on $\boldsymbol{Z}$.