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Time Series Econometrics

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Title: Time Series Econometrics


1
Time Series Econometrics
  • Ch7 Some Basic Concepts

2
Ch7 Basics
  • 1. Stochastic Processes
  • 2. Stationarity Processes
  • 3. Purely Random processes
  • 4. Nonstationary Processes
  • 5. Random Walk Models
  • 6. Unit Root Tests
  • 7. Cointegration and Cointegration Tests
  • 8. Error Correction Mechanism
  • 9. Granger Causality Test

3
Background
  1. Regression analysis based on time series data
    implicitly assumes that the underlying time
    series are stationary. The classical t test, F
    tests, etc. are based on this assumption.
  2. In practice most economic time series are
    nonstationary. (spurious/ nonsensical regression)

4
Spurious Regression
  • Regression of one time series variable on one or
    more time series variables often can give
    nonsensical or spurious results.
  • Spurious regression often shows a significant
    relationship between variables, but in fact, this
    kind of relationship does not exist.
  • This phenomenon is known as spurious
    regression.
  • An is a good rule of thumb to
    suspect that the estimated regression is
    spurious.

5
1. Stochastic Processes
  • A random or stochastic process is a collection of
    random variables ordered in time.
  • The term stochastic comes from the Greek word
    stochos, which means a target or bulls eye.

6
2. Stationary Stochastic Processes
  • A stochastic process is said to be stationary if
    its mean and variance are constant over time and
    the value of the covariance between the two time
    periods depends only on the distance or gap or
    lag between the two time periods and not the
    actual time at which the covariance is computed.
    That is, they are time invariant.
  • In the time series literature, such a stochastic
    process is known as a weakly stationary. A
    stationary time series will tend to return to its
    mean ( called mean reversion) and fluctuate
    around this mean.

7
Stationary Stochastic Processes, continued
  • Properties of stationarity
  • Let Yt be a stochastic time series
  • Mean
  • Variance
  • Covariance

8
Stationary Stochastic Processes, continued
  • A time series is strictly stationary if all the
    moments of its probability distribution and not
    just the first two (i.e., mean and variance) are
    invariant over time. If, however, the stationary
    process is normal, the weakly stationary
    stochastic process is also strictly stationary,
    for the normal stochastic process is fully
    specified by its two moments, the mean and
    variance.
  • Nonstationary time series if a time series is
    not stationary in the sense just defined, it is
    called a nonstationary time series. In other
    words, a nonstationary time series will have a
    time-varying mean or a time-varying variance or
    both.

9
Stationary Stochastic Processes, continued
  • White Noise a special case of stationary
    stochastic process.
  • We call a stochastic process purely random or
    white noise if it has zero mean, constant
    variance and is serially uncorrelated.
  • IID identically and independently
    distributed

10
3. Nonstationary stochastic process
  • Random walk model (RWM) a classical example of
    nonstationary time series
  • The term random walk is often compared with a
    drunkards walk. Leaving a bar, the drunkard
    moves a random distance ut at time t, and
    continuing to walk indefinitely, will eventually
    drift farther and farther away from the bar. The
    same is said about stock prices. Todays stock
    price is equal to yesterdays stock price plus a
    random shock.

11
4. Unit Root Process
  • If, , it becomes a RWM (without drift).
    If is in fact 1, we face what is known as the
    unit root problem, that is, a situation of
    nonstationary we already know that in this case
    the variance of Yt is not stationary. The name
    unit root is due to the fact that .
  • Thus the terms nonstationarity, random walk, and
    unit root can be treated as synonymous.

12
5. Spurious Regression Again
  • If Y and X have unit roots then all the usual
    regression results might be misleading and
    incorrect.
  • One way to guard against it is to find out if the
    time series are cointegrated.
  • An is a good rule of thumb to
    suspect that the estimated regression is
    spurious.

13
6.Tests of Nonstationarity
  • How do we find out whether a given time series is
    stationary?
  • At the informal level, weak stationarity can be
    tested by the correlogram of a given time series.
  • At the formal level, stationarity can be checked
    by finding out if the time series contains a unit
    root.

14
Tests of Nonstationarity the correlogram test
  • Autocorrelation function (ACF)
  • The correlogram is a graph of autocorrelation at
    various lags for a given time series
  • For stationary time series, the corelogram tapers
    off quickly, whereas for nonstationary time
    series it dies off gradually.
  • Q statistic
  • testing the joint hypothesis that all the
    up to certain lags are simultaneously equal
    to zero.

15
Tests of Nonstationarity the Unit Root Test
  • The Unit Root Test
  • If , then , that is we have a
    unit root, meaning the time series under
    consideration is nonstationary.

16
Tests of Nonstationarity Dickey-Fuller (DF) Test
  • The DF test is estimated in three different
    forms. It was assumed that the error term was
    uncorrelated.

17
Dickey-Fuller Test, continued
  • Suppose Yt can be described by the following
    equation
  • Using OLS to run the unrestricted regression
  • Using OLS to run the restricted regression

  • or
  • Using the sums of squared residuals in the
    restricted and unrestricted regressions to
    calculate F statistic, then compare F value with
    the critical value.

18
Tests of Nonstationarity the Augmented Dickey-
Fuller (ADF) Test
  • ADF test is developed if the are correlated.
  • Under the circumstance, the unit root test
    is run the same way as before.

19
7. Cointegration
  • Regressing one random walk against another can
    lead to spurious results.
  • Differencing variables before using them in a
    regression may result in a loss of long-run
    information.
  • Cointegration means that despite two or more time
    series follow random walks, a linear combination
    of them can be stationary. If this is the case,
    we say that these time series are co-integrated.
  • The AEG,augmented Engle-Granger test,and other
    tests can be used to find out whether two or more
    time series are cointegrated.
  • Cointegration of two or more time series suggests
    that there is a long-run, or equilibrium,
    relationship between them.

20
Testing for Cointegration ( ADF CRDW Tests)
  • Testing whether there is a co-integrated
    relationship between two time series.
  • Step 1 using the ADF test to confirm that
    variables in the regression are random walks.
  • Step 2 using OLS to estimate the regression
    equation
  • , then tests
    whether the residuals from the above
    co-integrating regression are stationary.
  • 1. Perform Augmented Dickey-Fuller unit
    root test on the residual series to see if the
    residual is stationary.
  • 2. Look at the Durbin-Watson statistic
    from the above regression
  • , compare DW value
    with the corresponding critical vale at proper
    confidence level to decide whether reject or
    accept the null hypothesis.

21
8. Error Correction Mechanism
  • Granger representation theorem if two variables
    Y and X are cointergated, then the relationship
    between the two can be expressed as ECM, the
    error correction mechanism.
  • where is the error obtained from the
    regression model with Y and X (i.e.
    ) and is the error in the ECM
    model.
  • The ECM says that depends on - an
    intuitively sensible point (i.e. changes in X
    cause Y to change).
  • In addition, depends on . This
    latter aspects is unique to the ECM and gives it
    its name.

22
Error Correction Mechanism, continued
  • Remember that can be thought of an an
    equilibrium error. If it is non-zero, then the
    model is out of equilibrium. Consider the case
    where and is positive. The
    latter implies that is too high to be in
    equilibrium (i.e. is above its equilibrium
    level of ). Since the
    term will be negative and so will
    be negative. In other words, if is above
    its equilibrium level, then it will start falling
    in the next period and the equilibrium error will
    be corrected in the model hence the term
    error correct model. In the case where
    the opposite will hold (i.e. is below its
    equilibrium level, hence which causes to be
    positive, triggering Y to rise in period t).

23
Error Correction Mechanism, continued
  • A distinctive feature of the model is that the
    ECM has both long run and short run properties
    built into it.
  • We use this error term, to tie the
    short-run behaviour of Y to its long-run
    value.The ECM developed by Engle and Granger is a
    means of reconciling the short-run behaviour of
    an economic variable with its long-run behaviour.

24
9. Causality in Economics the Granger Causality
Test
  • The test involves estimating the following pair
    of regressions

25
Granger Causality Test, continued
  • 1. Unidirectional causality from X to Y is
    indicated if the estimated coefficients on the
    lagged X in (1) are statistically different from
    zero as a group and the set of estimated
    coefficients on the lagged Y in (2) is not
    statistically different from zero
  • 2. Conversely, unidirectional causality from Y to
    X exists if the set of lagged X coefficients in
    (1) is not statistically different from zero and
    the set of the lagged Y coefficients in (2) is
    statistically different from zero

26
Granger Causality Test, continued
  • 3. Feedback, or bilateral causality, is suggested
    when the sets of X and Y coefficients are
    statistically different from zero in both
    regression
  • 4. Finally, independence is suggested when the
    sets of X and Y coefficients are not
    statistically significant in both the regression.

27
Granger Causality Test, continued
  • 1. Regress current Y on all lagged Y terms, but
    not include the lagged X variables, obtain the
    restricted residual sum of squares, RSSR.
  • 2. Run the regression including the lagged X
    terms, obtain the unrestricted residual sum of
    squares, RSSu
  • 3. The null hypothesis is , that
    is, lagged X terms do not belong in the
    regression.

28
Granger Causality Test, continued
  • 4. To test this hypothesis, we apply the F test
  • Which follows the F distribution with m and
    (n-k) df. m is equal to the number of lagged X
    terms and k is the number of parameters estimated
    in the unrestricted regression.
  • 5. If the computed F value exceeds the critical F
    value at the chose level of significance, we
    reject the null hypothesis, in which case the
    lagged X terms belong in the regression. This is
    another way of saying that X Granger-causes Y.
  • 6. Steps 1 to 5 can be repeated to test model 2,
    that is, if Y Granger-causes X.
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