Description

Returns the estimated coefficient matrices of the moving average representation of a stable VAR(p), of an SVAR as an array or a converted VECM to VAR.

Usage

Arguments

Details

If the process \bold{y}_t is stationary (i.e. I(0), it has a Wold moving average representation in the form of:

\bold{y}_t = Φ_0 \bold{u}_t + Φ_1 \bold{u}_{t-1} + Φ \bold{u}_{t-2} + … ,

whith Φ_0 = I_k and the matrices Φ_s can be computed recursively according to:

Φ_s = ∑_{j=1}^s Φ_{s-j} A_j \quad s = 1, 2, … ,

whereby A_j are set to zero for j > p. The matrix elements represent the impulse responses of the components of \bold{y}_t with respect to the shocks \bold{u}_t. More precisely, the (i, j)th element of the matrix Φ_s mirrors the expected response of y_{i, t+s} to a unit change of the variable y_{jt}.
In case of a SVAR, the impulse response matrices are given by:

Θ_i = Φ_i A^{-1} B \quad .

Albeit the fact, that the Wold decomposition does not exist for nonstationary processes, it is however still possible to compute the Φ_i matrices likewise with integrated variables or for the level version of a VECM. However, a convergence to zero of Φ_i as i tends to infinity is not ensured; hence some shocks may have a permanent effect.

Value

An array with dimension (K \times K \times nstep + 1) holding the estimated coefficients of the moving average representation.

Note

The first returned array element is the starting value, i.e., Φ_0.

Author(s)

Bernhard Pfaff

References

Hamilton, J. (1994), Time Series Analysis, Princeton University Press, Princeton.

Lütkepohl, H. (2006), New Introduction to Multiple Time Series Analysis, Springer, New York.

See Also

Psi, VAR, SVAR, vec2var, SVEC

Examples