代写 Monash ETF2100/5910 Introductory Econometrics

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    • 代写 Monash ETF2100/5910 Introductory Econometrics

    Department of Econometrics and Business Statistics
    ETF2100/5910 Introductory Econometrics
    Assignment 1, Semester 1, 2016
    Worth 10% of Final Mark
    Due 4pm Friday April 8
    (Hand in to Duangkamon’s mailbox – Building H Level 5)
    Note:
    • Notation used in the assignment needs to be written correctly and properly. It is
    recommended that students submit hand-written assignments instead of typed ones.
    • This assignment comprises three questions.
    • Question 3 parts h) to k) are extra questions for ETF5910 students.
    • Mark allocations are given for each question. Marks are also awarded for presentation
    of graphs.
    • Total marks for ETF2100 and ETF5910 students are 100 and 125, respectively.
    • Marks will be deducted for late submission on the following basis:
    10% for each day late, up to a maximum of 3 days.
    Assignments more than 3 days late will not be marked.
    Question 1  ((5+5)+(9+3+3+3)+2+5+2+5=42 marks)
    (a)  Show that
    (i)  ( )( )
    1 1 1 1
    1
    N N N N
    i i i i i i
    i i i i
    x x y y x y x y
    N
    = = = =
    − − = −
    ∑ ∑ ∑ ∑
    (ii)
    2
    2 2
    1 1 1
    1
    ( )
    N N N
    i i i
    i i i
    x x x x
    N
    = = =
     
    − = −
     
     
    ∑ ∑ ∑
    (b)  In 1990, data were collected for 200 CEO Salaries (measured on thousands of dollars)
    and their company’s return on equity,  RoE (measured in percent) over the previous
    three years. Consider the following linear regression model:
    1 2 i i i
    Salary RoE e =β +β +
    Let’s  y Salary = and  x RoE = and
    200 200 200 200
    2
    1 1 1 1
    3470.7; 261752; 75159.15; 4801270;
    i i i i i
    i i i i
    x y x x y
    = = = =
    = = = =
    ∑ ∑ ∑ ∑
    ( )
    2
    1
    388,006,092
    N
    i
    i
    y y
    =
    − =
    Fill in the blanks of the EViews output below using the information above and the
    relevant information provided in the EViews output. Be sure to show your working and
    any formulae used. In particular, find the following quantities.
    (i)  Calculate  x ,  y ,
    1
    b ,
    2
    b and
    2

    代写 Monash ETF2100/5910 Introductory Econometrics
     
    ( ) se b .
    (ii)  Calculate the  t statistic for testing the null hypotheses
    0 2
    : 0 H β = .
    (iii)  Calculate the sum squared error or  SSE .
    (iv)  Calculate
    2
    R .
    Dependent Variable: SALARY 
    Method: Least Squares 
    Sample: 1 200 
    Included observations: 200 
    Variable  Coefficient  Std. Error  t-Statistic  Prob.
    C  220.8001  4.5642  0.0000
    ROE  0.1294
    R-squared  Mean dependent var 
    Adjusted R-squared  0.006584 S.D. dependent var  1396.345
    S.E. of regression  1391.741 Akaike info criterion  17.32445
    Sum squared resid  Schwarz criterion  17.35743
    F-statistic  2.318811 Durbin-Watson stat  2.118519
    Prob(F-statistic)  0.129413 
    (c)  Interpret the value for
    2
    b .
    (d)  Economic theory stated that return on equity should have a positive impact on salary.
    Use a critical value approach to test this hypothesis at 10% level of significance. Be
    sure to show all steps used to conduct your hypothesis test.
    (e)  Predict the expected CEO salary when the company’s return on equity is 10% for the
    previous three years.
    (f)  Calculate salary elasticity with respect to return on equity when the return on equity is
    10% for the previous three years. Calculate also its standard error. (Use the property
    that  ( ) ( )
    2
    var var aX a X = where  X is a random variable and  a is a constant.)
    Question 2  (4 marks each =16 Marks)
    Are the following statements true? Provide a brief explanation (not more than 3-4 sentences)
    for your answer.
    1.  In the OLS model,
    1
    var( ) b increases as the sample size (N) increases.
    2.  A left-tailed significance test should be used for
    0 2
    : 0 H β = when economic theory
    suggests that the dependent variable and the independent variable have a correlation
    that is greater than 0.
    3.  When overall uncertainty in the model, as measured by σ 2 , is smaller, the forecast error
    will also be smaller.
    4.  The Jarque-Bera test is a test of the hypothesis that the residuals have a constant
    variance.
    Question 3 (6 marks each for parts (a) to (g) = 42 marks; for (h) to (k) 11+2+2+10 = 25
    marks)
    Life expectancy is an indicator of how long a person can expect to live on average given the
    environment s/he is in. It is a standard measure of population wellbeing in general. It is
    commonly used by the government for policy planning related to future population ageing in a
    country. It is also commonly used in calculating life insurance policy.
    There are a number of studies done on the relationship between life expectancy and income. It
    is believed that people with higher incomes tend to live longer than people with lower incomes
    and the relationship can be linear or nonlinear.
    Consider the data on life expectancy and income for the year 2011 from a number of countries
    obtained from http://www.gapminder.org/ and reported in LifeExpectancy.xls. The variable LE
    represents life expectancy at birth in years. The variable GDP represents the country’s Gross
    Domestic Product (GDP) per capita in international dollar after adjusting for purchasing power
    parity so that GDP from different countries are comparable.
    Consider three functional forms for the relationship between life expectancy and income.
    1 2 i i i
    LE GDP e =β +β + (3.1)
    ( )
    1 2 ln i i i
    LE GDP v = α +α + (3.2)
    2
    1 2 i i i
    LE GDP = γ + γ +ε (3.3)
    (a)  Explain what each of the above functional forms imply in terms of the relationship
    between life expectancy and GDP?
    (b)  Using the data for 179 countries, estimate the 3 equations and report the results the
    usual way.
    (c)  Plot the fitted equations onto a scatterplot of the data. Which equation seems to best
    match your observations? Explain why?
    (d)  Obtain and comment on residual plots against the explanatory variable for each
    equation. Which model seems best specified?
    (e)  Obtain histograms of your residuals for each model and discuss if they resemble a
    normal distribution. Perform a test of normality on each set of residuals.
    (f)  Interpret and compare the
    2
    R for each of your three equations, and explain why it is
    possible to make this comparison.
    (g)  Which is your preferred model? Use your answers in parts b) to f) above to justify your
    choice.
    Parts h) to k) below are for ETF5910 students only
    It may be of interest to compare life expectancy between two levels of incomes. Some previous
    studies have shown that a big proportion of population around the world receive income in
    2011 around 2,000 international dollars. At the same time, some people at the high end of the
    global income distribution receive income more than 30,000 international dollars in 2011.
    Using the preferred model in (g):
    (h)  Predict life expectancy values for the two levels of GDPs. Obtain a 99% prediction
    interval for both predicted life expectancy values. Compare and comment on the
    finding.
    (i)  Find the estimates of the slopes  ( ) ( ) d LE d GDP at the points where  2,000 GDP = and
    30,000 GDP = .
    (j)  Find estimates of the elasticities  ( ) ( )
    ( ) ( )
    d LE d GDP GDP LE at the point where
    2,000 GDP = and  30,000 GDP = .
    (k)  Based on the finding from parts (h) to (j), write a short report (not more than half a
    page) in terms of life expectancy between low and high income populations.

    代写 Monash ETF2100/5910 Introductory Econometrics