Skip to content

L36 Cointegration & Further

Spurious Regression

Two independent \(I(1)\) processes:

\[ x_{t} = x_{t-1} +v_{t},\quad v_{t} \sim WN(0,1) \]
\[ y_{t} = y_{t-1} +u_{t},\quad u_{t} \sim WN(0,1) \]

Even though they are generated from independent families, there is a correlation \(\implies\) Spurious regression

Non-spurious regression

Two dependent \(I(1)\) processes

\[ x_{t} = 0.6I_{t} + v_{t},\quad v_{t} \sim WN(0,1) \]
\[ y_{t} = 0.6I_{t} + u_{t},\quad u_{t} \sim WN(0,1) \]

where \(I_{t} =I_{t-1} + w_{t}\) and \(w_{t} \sim WN(0,1)\) which is an \(I(1)\) process.

Thus, \(I_{t}\) is a common stochastic trend in both \(\{ x_{t} \}\) and \(\{ y_{t} \}\).

Since, \(x_{t}\) and \(y_{t}\) are \(I(1)\)1, to remove the stochastic trend, we take the first difference of both and then we note than the relationship is not significant (\(v_{t}\) and \(u_{t}\) are independent).

Cointegrated

\[ y_{t} - \dfrac{x_{t}}{0.6} = u_{t}^*, \quad u_{t}^* \sim WN(0, 1+0.6^{-2}) \]

There exists a \(\beta = (1,-(0.6)^{-1})\) such that,

$$
\beta'\begin{pmatrix}
y_{t} \
x_{t}
\end{pmatrix} \sim I(0)
$$
Then \(x_{t}\) and \(y_{t}\) are said to be cointegrated.

  • The series should be transformed so that they can be considered as realizations of weakly stationary processes (\(I(0)\))

When the linear combination (\(\beta'(y_{t}\ x_{t})'\)) of two \(I(1)\) processes is weakly stationary \(I(0)\) \(\implies\) cointegration.

  • Existence of long-run equilibrium
  • Common stochastic trend exists
  • Separate the short- and long- run relationships
  • help improve long-run forecast accuracy (how?)
  • improve estimation efficiency by implying restrictions on the model (what?)

Multivariate Situations

  • Elements of \(k\)-dimensional vector \(Y\), are cointegrated of order \((d,c)\)
  • if all \(Y\) elements are \(I(d)\)
  • There exists a non-trivial linear combination \(z\)
  • which is \(I(d-c)\)
\[ \beta'y_{t} = z_{t} \sim I(d-c) \]
  • \(\beta\) is called the cointegration vector
  • There can be multiple non-trivial linear combinations (need not be unique).
  • The number of such linearly independent cointegration vectors is called cointegration rank.

Applications

  • Pairs Trading in finance: individually assets are not stationary. Linear combination is! There will be some long-run equilibrium between two assets. So one can capture the deviations from the long-run equilibrium in the short-term, and take decisions accordingly (By taking long- and short- positions appropriately)
  • Energy markets: prices of energy commodities are non-stationary

  1. If a process contains an \(I(1)\) process, it, itself will become \(I(1)\)