1. Long-run growth
In this subsection, we will discuss long-run growth and use the tdata
package to calculate and plot it. First, let’s review some mathematical
concepts.
A variable can change continuously or discretely over time. \[\begin{align}
&y(t)=y(0)e^{g_1}e^{g_2}\ldots g^{g_t}\\
&y_t=y_0(1+g_1)(1+g_2)\ldots(1+g_t)
\end{align}\]
The starting condition is represented by \(y_0\) and \(y(0)\), while \(y_t\) and \(y(t)\) represents the value of the variable
\(t\) periods. The \(g_i \times 100\) for \(i=1\ldots t\) are the discrete or
continuous growth rates in different periods.
Recall that we have two formulas for calculating growth rate in one
period: \[\begin{align}
&G_c=(\ln{\frac{y(t+1)}{y(t)}})\times 100\\
&G_d=(\frac{y_{t+1}}{y_t}-1)\times 100
\end{align}\]
for \(y_i>0\) for all \(i\). Also, recall that we have this
approximation: \(ln(1+x) \approx x\)
when \(x\) is small. Therefore, it
might not be important which one we choose for variables such as GDP.
However, assume that the growth rates are large, e.g., in one period the
value increases from 1 to 2. It is clear that the growth rate is 100%.
Using the continuous formula gives us 69.3% and by using the discrete
one we get 100%. Does this mean the continuous formula is wrong?
Definitely not. When we say “the value increases from 1 to 2”, we are
assuming that the growth is discrete. Therefore, if you are wondering
which of these formulas to use, think about your assumptions and your
mathematical model. It is generally easier to work with the continuous
formula because the derivative of \(ln\) is easier to compute.
Interest rate is a similar concept to growth rate, and let’s study
these formulas from that perspective. Assume that you lend \(y_0\) amount of money at time \(t=0\). If the annual interest rate is \(r\), at the end of the first year you will
have \(y_0*(1+r)\). Let’s assume that
interest is paid monthly and you lend the interest too. At the end of
the first month, you will have \(y_0*(1+\frac{r}{12})\). Then, at the end of
the second month, you will have \(y_0*(1+\frac{r}{12})^2\). And so on. At the
end of the year, you will have \(y_0*(1+\frac{r}{12})^12\). At the end of
the second year, you will have \(y_0*(1+\frac{r}{12})^24\). At the end of
\(t\) years, you will have \(y_0*(1+\frac{r}{12})^12t\). We can
similarly split the year into smaller periods and calculate the limit
when we move from 12 toward infinity in the formula. If we use
L’Hopital’s rule and calculate such a limit, we will find the continuous
formula: \(y_t=y_0 e^{rt}\). Compared
to the previos discussion, we have one scalar value \(r\) here.
Let’s get back to the long-run formulas. We are looking for a scalar
value \(g\) in which we can summarize
all the other \(g_i\)s, such that:
\[\begin{align}
&y(t)=y(0)e^{g_c t}\\
&y_t=y_0(1+g_d)^t
\end{align}\]
This single value does what all other growth rates achieve together:
it take us from the starting point (\(y_0\) or \(y(0)\)) to the end point (\(y_t\) or \(y(t)\)). We call \(\bar{G}_c = g_c\times 100\) and \(\bar{G}_d=g_d \times 100\) the continuous
and discrete long-run growth rates. It is important to note that \(\bar{G}_c\) and \(\bar{G}_d\) are not exactly equal (The
discussion is similar to the discussion about \(G_c\) and \(G_d\) above).
Given the data \(\{y_i\}_{i=0}^t\)
where \(y_i>0\) for all \(i\), the following formula calculates the
long-run continuous growth rates: \[\begin{align}
&\bar{G}_c = \frac{\ln{\frac{y(t)}{y(0)}}}{t}\times 100\\
&\bar{G}_c = \frac{G_{c1}+G_{c2}+\ldots+G_{ct}}{t}
\end{align}\]
in which \(G_{ci}\) is the
continuous growth rate at period \(i\).
Recall that \(\ln{x}+ln{y}=\ln{xy}\)
for \(x,y\in\mathbb{R}\).
The two similar formulas for the discrete case are:
\[\begin{align}
&\bar{G}_d = (\frac{y_t}{y_0}-1)^{\frac{1}{t}}\times 100\\
&\bar{G}_d =(\sqrt[t]{\Pi_{i=1}^{t}(1+\frac{G_{di}}{100})}-1)\times
100
\end{align}\]
These are more complicated compared to the continuous case. As I said
before, it is much easier to deal with continuous assumption.
It is important to note that the formulas for calculating growth
rates may not be applicable when the data can be negative or \(\{y_i\}_{i=0}^t\) contains negative values.
In such cases, alternative methods may be needed to measure growth or
change over time. One possible approach is to add a constant to all
values to make them positive before calculating the growth rates.
However, this approach may not always be suitable and it is crucial to
carefully evaluate the context of the data before applying any
transformation.
The following code creates two tdata variables which
contain the real GDP per capita (PPP) of Korea and Iran from 1990 to
2021. Data source is “World Development Indicators” and data code is
“NY.GDP.PCAP.PP.KD”.
y_kor <- variable(data = c(12656, 13882, 14591, 15436, 16698, 18120, 19365, 20368, 19184, 21233, 22964, 23894, 25591, 26260, 27516, 28641, 29991, 31570, 32275, 32364, 34394, 35389, 36049, 37021, 37967, 38829, 39815, 40957, 41966, 42759, 42397, 44232),
startFrequency = f.yearly(1990),
name = "Korea, GDP per capita, PPP (constant 2017 international $), World Bank")
y_iri <- variable(data = c(9442, 10240, 10331, 10114, 9904, 10007, 10504, 10495, 10548, 10590, 11026, 11098, 11879, 12786, 13127, 13329, 13781, 14690, 14526, 14474, 15099, 15302, 14542, 14113, 14539, 14011, 14969, 15163, 14629, 14084, 14432, 15005),
startFrequency = f.yearly(1990),
name = "Iran, Rep., GDP per capita, PPP (constant 2017 international $), World Bank")
We can use the get.longrun.growth function to calculate
the long-run growth rates and plot the trends.
GDP per capita of IRI and KOR: Data and longrun
trend over time
2. NA starategies
Data cleaning is a crucial early step in the data analytics process,
which may involve handling missing or NA observations. There are several
methods to deal with missing values, including replacing them with
substitutes from other records or datasets, estimating values based on
other available information through imputation, or using a mathematical
function to fit a curve to the available data points through
interpolation. However, sometimes it may be necessary to remove
NA observations from the data before analysis. In this
section, we will discuss a common scenario when working with
cross-sectional data where NA values exist in some variables.
Let’s begin with a simple example. Consider the following data table,
where the variables are in columns and the observations are in rows:
\[\begin{equation}
\begin{array}{c|ccc}
& V_1 & V_2 & V_3 \\
\hline
O_1 & 1 & 2 & 3 \\
O_2 & 4 & NA & 5 \\
O_3 & 7 & NA & 9 \\
O_4 & 10 & 11 & 12
\end{array}
\end{equation}\]
If we remove \(V_2\), the resulting
data table will have 8 observations. However, if we remove \(O_2\) and \(O_3\) observations, the final data table
will have only 6 observations. Assuming that all observations are
equally important, removing \(V_2\)
would be the best strategy. Now, consider the following structure:
\[\begin{equation}
\begin{array}{c|ccc}
& V_1 & V_2 & V_3 \\
\hline
O_1 & NA & 2 & NA \\
O_2 & 4 & 5 & 5 \\
O_3 & NA & 6 & 9 \\
O_4 & NA & 11 & 12
\end{array}
\end{equation}\]
In this case, the best strategy would be to remove \(V_1\) and \(O_1\). Now, consider the following data
table:
\[\begin{equation}
\begin{array}{c|ccc}
& V_1 & V_2 & V_3 & V_4\\
\hline
O_1 & NA & 2 & NA & NA \\
O_2 & 5 & 6 & 7 & 8 \\
O_3 & 9 & NA & 11 & 12 \\
O_4 & 13 & 14 & NA & NA \\
O_5 & 17 & 18 & 19 & 20 \\
\end{array}
\end{equation}\]
Can you see what the best strategy would be in this case? What if it
is more important to keep variables instead of observations.
The remove.na.strategies function in the
tdata package can help you decide on a proper order for
removing columns and rows. Here is an example using the data from the
previous example:
st <- remove.na.strategies(data = matrix(c(NA,2,NA,NA,5,6,7,8,9,NA,
11,12,13,14,NA,NA,17,18,19,20),
ncol = 4,
byrow = TRUE))
The first element of the output shows the best strategy where the
final data table has 9 observations by removing columns with indices
reported in colRemove (which is 2) and rows with indices
reported in rowRemove (which is 1, 4). The second-best
strategy results in a final matrix with 8 observations and suggests
removing rows with indices reported in rowRemove (which is
1, 3, 4) and no columns.
We can use the countFun argument to increase the weight
of columns. For example, if we use
countFun = function(nRows, nCols) nRows * nCols^2, the best
strategy would be to remove rows with indices reported in
rowRemove (which is 1, 3, 4).
