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Transcript of PRUS11_SI_2008
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Common Dynamics Between The US and Puerto Rico
Economies
Csar R. Sobrino
School of Business & EntrepreneurshipUniversity of Turabo
PO BOX 3030
Gurabo, PR 00778Email: [email protected]
ABSTRACT
In this paper, I examine the comovements between US real GDP and Puerto Rico real GDP. To
accomplish it, I employ a cointegration test and the Vahid&Engle (1993)s common feature test.From 1947 to 2009, the findings indicate there are common movements between Puerto Rico and
the US in the long and short run. Likewise, the evidence also shows that Puerto Rico has been
more sensible to US permanent shocks than US transitory shocks.
Keywords: Time Series Models,Macroeconomics, Business Cycles,JEL Classification: C32, E20, E32
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1. Introduction
Puerto Rico is a self-governing non-incorporated territory of the United States and its
economy works under the legal US frame. In other words, there is a common free trade
area, a common custom union, a common currency union. free labor and capital
mobility. According to the economic theory, this circumstance implies common
movements between both economies. In this, Alameda (2000) finds that Puerto Rico
economy is less responsive to US transitory shock in the second period.
In this paper, I employ a different approach to analyze the comovements between the US
and Puerto Rico. First, find a long term relationship between US real GDP and Puerto
Rico real GDP by a cointegration test. Second, conditional to cointegration, find a short
run relationship between both real GDPs using the Vahid and Engle (1993)s test.
Using annual data (1947-2009), the evidence indicates that, consistent with , from 1950-
2007, the real GDP per capita of Puerto Rico has grown almost 8 times while the US real
GDP per capita has grown 3.3 times, PR RGDP has positively responded for almost 4%
to a 1% increase in US permanent shocks. In contrast, in the short run, PR RGDP
positively responds for almost 1.6% to a 1% increase in US transitory shocks.
This paper is organized as follows: Section 2 presents the cointegration and common
cycles tests, and data; Section 3 reports the outcomes of the tests; and, Section 4
concludes.
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2. Cointegration and Cofeature Tests and Data
Consider n variables of integration order I(1) which can be represented in the next VAR
in reduced form of orderp+1:
..(1)
Where x is an (n*1) column vector of time processes; is (n*1) column vector of
deterministic variables; is an (n*n) matrix of coefficients of;Ai is an (n*n) matrix of
coefficients with elements Ajk(i); is the (n*1) matrix of disturbance terms (
where is the (n*n) variance-covariance matrix). Suffix tstands for time.
After some operations of adding and subtraction about (1), it is obtained the following
VECM of orderp:
(2)
Where (
) ,
(
) , and is the first difference
operator.
The Johansen (1991)s cointegration test focuses on the rank(r)of. If 0 < r< n, there are
r linear combinations of the series which are I(0). In other words, r is the number of
cointegrating vectors. When 0 < r< n, the series respond to deviations returning to their
steady state. Likewise, it is used a VAR in first differences when r= 0. Moreover, ifr=
n, it means thatxtisI(0).
To find r, Johansen (1991) suggests two tests statistics: (
) and () . T is the number of usable
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observations and the lambdas are the eigenvalues of . In the first one, the null
hypothesis is number of cointegrating vectors r, and in the second one, the null
hypothesis is number of cointegrating vectors = r.
In addition, to test the restrictions in the cointegrating vector, Johansen (1991)
decomposes into two matrices, and (). is the (n*r) matrix of
cointegrating parameters and is the (n*r) matrix of speed of adjustment parameters.
Once found a long term relationship among the series, the cointegrating vector is used to
find the Vahid and Engle (1993)s statistics for common cycles test. In this approach, the
canonical correlations between {xt} and {xt-1, xt-1,,xt-p} have to be estimated. The
null hypothesis that the dimension of the cofeature space is at least s (the quantity of the
smallest squared canonical correlations) is tested with this statistics. The statistics
is , where
s (i=1,2,3,..,s) are the smallest
squared canonical correlations. This statistics has a Chi-square distribution with s(np+r)-
s(n-s) degrees of freedom.
2.1. Data and Modeling
For the period 1947- 2008 (yearly data), the US real GDP, hereafter QUS, is provided by
the Fed of St. Louis web page (http://research.stlouisfed.org/fred2/) and the Puerto Rico
Planning Board provides the real GDP of Puerto Rico1, hereafter QPR. So, n=2. In Figure
1, both series in logs are shown. At first glance, it looks like they share common
movements: Over 60 years, there is a common tendency and, specifically in the 70s,
1 I thank Dr. Ervin Martinez, Director of the Puerto Rico Planning Board, for making available Puerto
Rican data. Regrettably, quarterly data is not accounted. Quarterly data describes more accurate short runfluctuations than annual data, moreover, in the analysis, degrees of freedom are lost.
http://research.stlouisfed.org/fred2/http://research.stlouisfed.org/fred2/http://research.stlouisfed.org/fred2/http://research.stlouisfed.org/fred2/ -
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there are similar period recessions and expansions (marked with NBER recessions dates),
although, it is also observed that, after 2001 US recession, Puerto Rico got a small growth
up to 2005 and, later on, negative growth rates. It seems that both processes meander
from each other.
In order to know the integration order of the series, Augmented Dickey-Fuller
tests outcomes are shown in Table 1. They indicate that both processes are no stationary
because the null hypothesis cannot be rejected. In first differences, the null hypothesis
that the process has a unit root is rejected at 5% of significance for both series. This
indicates that both real GDPs areI(1).
For testing the optimal lag order of the VAR, I employ the Akaike Information Criterion
(AIC) which is reported in Table 2:. It indicates the optimal lag order at levels is 3 which
mean in first differences the optimal lag order is 2. So, whenp=2, (2) has the next form:
Including into the former, the model employed in this paper is:
(3)
Where L is a matrix of lag operators and and the number of
usable observations is 62 (=T)
In this form, the matrix of deterministic variables allows changes regarding to include
unrestricted and restricted constants, and, unrestricted and restricted linear trends. If there
are a restricted constant or a restricted linear trend, is part of their coefficients. In other
words, they are included in the cointegrating vector.
http://economics.about.com/cs/economicsglossary/g/augmented.htmhttp://economics.about.com/cs/economicsglossary/g/augmented.htm -
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Once established a cointegrating relationship, given p=2, it has to be computed the
canonical correlations between {xt} and {xt-1, xt-1}. The statistics is
, where i=1,2, and thereare s(2+r)-s(2-s) degrees of freedom for
all s>0.
3. Outcomes
Including a drift and a restricted linear trend, the outcomes of trace test are shown in
Table 3. The null hypothesis that r1 cannot be rejected at 5% of significance which
indicates that there is at most one cointegrating relationship between QUS and QPR over
the long run. The null hypothesis that r=0, is rejected at 5% of significance2. This means
that both processes share a common trend.
When it is not included a restricted trend, in both lambda tests, the null hypothesis that
r=0 cannot be rejected. The restricted linear trend is consistent with after 2001 US
recession data shows that both RGDPs veer apart. Likewise, QPR does not show breaks,
for that reason, I have included no dummy. However, to be accurate, I run (1) including a
time dummy (1991-2009=1, otherwise, zero). This dummy is not significant at 5%3.
is (1, -0.22, -0.02), normalized with respect to coefficient ofQUS. The second one is the
cointegrating coefficient ofQPR and the last one is the coefficient of the linear trend. The
restricted is (-0.56,-0.36) which means that when both (or one of them) series deviate
2 In max test, the null hypothesis that r=0 is rejected at 10% and the null hypothesis that r=1 cannot be
rejected at 5% of significance.
3For Puerto Rico, Alameda (2000) divides his analysis into two periods: 1967:01-1991:03 and 1991:03-
1998:06. Using a Chow test and the Economic Activity Index as a proxy variable of real GDP, He findsthat there is a break in 1991:03.
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from their long run equilibrium, the adjustment ofQUS is faster than the adjustment of
QPR.
On the other hand, in order to get the canonical correlations, I use the cointegrating
restriction () to test common cycles. Reported in Table 4, this test indicates that there is
a common feature between QUS and QPR. The null hypothesis that s>0 cannot be rejected
at 5% of significance and the null hypothesis that s>1 is rejected at 5% of significance.
Both, the cointegrating and cofeature vectors are shown in Table 5. Puerto Rico is more
sensible to US permanent shocks than US temporary shocks. Specifically, QPR positively
responds for almost 4% to a 1% change in US permanent shocks in the long run. In the
short run, QPR positively responds for almost 1.6% to a 1% change in US transitory
shocks. The long run outcome is consistent with that, from 1950 to 2007 the real GDP
per capita of Puerto Rico has grown almost 8 times while the US real GDP per capita has
grown 3.3 times4.
In contrast, after 1993 (NAFTA adoption), as reported by Herrera (2004), Mexico real
GDP is less sensible to US permanent shocks than US transitory shocks. In the first case,
the real output increases by less than 1% to 1% rise in US permanent shock. In the second
case, the real output increases by almost 4% to 1% change in transitory shock.
3.1. Robustness
4. Conclusions
4The Puerto Rico real GDP per capita was in 1950, $3,327.01 and in 2007, $26,212.98; and, The US real
GDP per capita was in 1950, 12,989.94 and in 2007, 42,886.92. (Penn Tables 6.3)
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References
Alameda, J. (2000) Globalizacin, Ciclos Econmicos y Respuesta Cclica de la
Economa de Puerto Rico: Evidencia Emprica entre 1967 a 1998, Unidad de
Investigaciones Econmicas, Departamento de Economa, Universidad de Puerto Rico,
Ro Piedras, Feb, #3.
Bram, J., F. Martinez and C. Steindel (2008) Trends and Developments in The Economy
of Puerto Rico New York Federal Reserve, Current Issues 14(2).
Herrera, J. (2004). Business Cycles in Mexico and The United States: Do they share
common movements?Journal of Applied Economics, 7(2), pp. 303-323.
Johansen, S. (1991) Estimation and Hypothesis Testing of Cointegration Vectors in
Gaussian Vector Autoregressive ModelsEconometrica 59:,pp 1551-1580.
Vahid, F. and R. Engle (1993), Common Trends and Common Cycles Journal ofApplied Econometrics, 8, pp. 341-360.
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Figure 1: US RGDP vs. Puerto Rico RGDP
20
21
22
23
24
28.0
28.5
29.0
29.5
30.0
30.5
50 55 60 65 70 75 80 85 90 95 00 05
US RGDP in logs (right-hand side)PR RGDP in logs (left-hand side)
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Table 1: Unit Root Test (ADF)
Null Hypothesis P-value
Log ofQUS has a unit root 0.5211
Log ofQPR has a unit root 0.9836
QUS growth rate has a unit root 0.0413
QPR growth rate has a unit root 0.0376
At levels: 10 lags, including intercept and trend.In first differences, 5 lags without intercept and trend.
Table 2: Optimal Lag Order-VAR
lags AIC
1 -9.50551
2 -9.6399
3 -9.64575*
4 -9.55505
5 -9.46928
* indicates the minimal value.
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Table 3: Johansen's Trace Test (restricted trend)
Null Hypothesis: # of
cointegrating vectorsEigenvalue
Trace
Statistic
Critical Value at
5%P-value
r=0 0.31006 26.84242 25.87211 0.0378
r1 0.08039 4.944535 12.51798 0.6044
Table 4: Johansen's Max Test (restricted trend)
Null Hypothesis: # of
cointegrating vectorsEigenvalue
Max-Eigen
Statistic
Critical Value
at 5%P-value
r=0 0.31006 21.89788 19.38704 0.0212
r=1 0.08039 4.944535 12.51798 0.6044
Table 5: Test of Common Cycles
Null Hypothesis: #
of common
features
Canonical
Correlations
Vahid and Engle's
(1993) Statistics (DF)
Critical Value
at 5% (P-value)
s >1 0.6025 16.38 (8) 15.51 (0.0181)
s >0 0.4468 5.42 (2) 5.99 (0.0665)
Table 6: US Real GDP and Puerto Rico Real GDP Common Dynamics
Long Run
Normalized cointegrating vector()
log(QUS) log(QPR) TREND
1 -0.22 -0.02
(-0.03027) (-0.00149)
Short Run
Normalized common feature vector( )log(QUS) log(QPR)
1 -0.53
(-0.1985)
Standard deviations in parentheses