KALDFF Call

CALL KALDFF (pred, vpred, initial, s2, data, lead, int, coef, var, intd, coefd <*>, n0 <*>, at <*>, mt <*>, qt ) ;

The KALDFF subroutine computes the one-step forecast of state vectors in an SSM by using the diffuse Kalman filter. The call estimates the conditional expectation of $z_ t$, and also estimates the initial random vector, $\delta $, and its covariance matrix.

The input arguments to the KALDFF subroutine are as follows:

data

is a $T \times N_ y$ matrix that contains data $(y_1, \ldots , y_ T)^{\prime }$.

lead

is the number of steps to forecast after the end of the data set.

int

is an $(N_ z + N_ y) \times N_\beta $ matrix for a time-invariant fixed matrix, or a $(T+\mbox{lead})(N_ z + N_ y) \times N_\beta $ matrix that contains fixed matrices for the time-variant model in the transition equation and the measurement equation—that is, $(W^{\prime }_ t, X^{\prime }_ t)^{\prime }$.

coef

is an $(N_ z + N_ y) \times N_ z$ matrix for a time-invariant coefficient, or a $(T+\mbox{lead})(N_ z + N_ y) \times N_ z$ matrix that contains coefficients at each time in the transition equation and the measurement equation—that is, $(F^{\prime }_ t, H^{\prime }_ t)^{\prime }$.

var

is an $(N_ z + N_ y) \times (N_ z + N_ y)$ matrix for a time-invariant variance matrix for the error in the transition equation and the error in the measurement equation, or a $(T+\mbox{lead})(N_ z + N_ y) \times (N_ z + N_ y)$ matrix that contains covariance matrices for the error in the transition equation and the error in the measurement equation—that is, $(\eta ^{\prime }_ t, \epsilon ^{\prime }_ t)^{\prime }$.

intd

is an $(N_ z + N_\beta ) \times 1$ vector that contains the intercept term in the equation for the initial state vector $z_0$ and the mean effect $\beta $—that is, $(a^{\prime }, b^{\prime })^{\prime }$.

coefd

is an $(N_ z + N_\beta ) \times N_\delta $ matrix that contains coefficients for the initial state $\delta $ in the equation for the initial state vector $z_0$ and the mean effect $\beta $—that is, $(A^{\prime }, B^{\prime })^{\prime }$.

n0

is an optional scalar including an initial denominator. If n0$>0$, the denominator for $\hat{\sigma }^2_ t$ is n0 plus the number $n_ t$ of elements of $(y_1, \ldots , y_ t)^{\prime }$. If n0$ \leq 0$ or n0 is not specified, the denominator for $\hat{\sigma }^2_ t$ is $n_ t$. With n0$ \geq 0$, the initial values, $A_1, M_1$, and $Q_1$, are assumed to be known and, hence, at, mt, and qt are used for input that contains the initial values. If the value of n0 is negative or n0 is not specified, the initial values for at, mt, and qt are computed. The value of n0 is updated as $\max (\mbox{\Argument{n0}},0) + n_ t$ after the KALDFF call.

at

is an optional $kN_ z \times (N_\delta + 1)$ matrix. If n0$ \geq 0$, at contains $(A^{\prime }_1, \ldots , A^{\prime }_ k)^{\prime }$. However, only the first matrix $\mathbf{A}_1$ is used as input. When you specify the KALDFF call, at returns $(A^{\prime }_{T-k+\mbox{lead}+1}, \ldots , A^{\prime }_{T+\mbox{lead}})^{\prime }$. If n0 is negative or the matrix $\mathbf{A}_1$ contains missing values, $\mathbf{A}_1$ is automatically computed.

mt

is an optional $kN_ z \times N_ z$ matrix. If n0$ \geq 0$, mt contains $(M_1, \ldots , M_ k)^{\prime }$. However, only the first matrix $M_1$ is used as input. If n0 is negative or the matrix $M_1$ contains missing values, mt is used for output, and it contains $(M_{T-k+\mbox{lead}+1}, \ldots , M_{T+\mbox{lead}})^{\prime }$. Note that the matrix $M_1$ can be used as an input matrix if either of the off-diagonal elements is not missing. The missing element $M_1(i,j)$ is replaced by the nonmissing element $M_1(j,i)$.

qt

is an optional $k(N_\delta + 1) \times (N_\delta + 1)$ matrix. If n0$ \geq 0$, qt contains $(Q_1, \ldots , Q_ k)^{\prime }$. However, only the first matrix $Q_1$ is used as input. If n0 is negative or the matrix $Q_1$ contains missing values, qt is used for output and contains $(Q_{T-k+\mbox{lead}+1}, \ldots , Q_{T+\mbox{lead}})^{\prime }$. The matrix $Q_1$ can also be used as an input matrix if either of the off-diagonal elements is not missing since the missing element $Q_1(i,j)$ is replaced by the nonmissing element $Q_1(j,i)$.

The KALDFF call returns the following values:

pred

is a $(T+\mbox{lead}) \times N_ z$ matrix that contains estimated predicted state vectors $(\hat{z}_{1|0}, \ldots , \hat{z}_{T+1|T}, \hat{z}_{T+2|T}, \ldots , \hat{z}_{T+\mbox{lead}|T})^{\prime }$.

vpred

is a $(T+\mbox{lead})N_ z \times N_ z$ matrix that contains estimated mean square errors of predicted state vectors $(P_{1|0}, \ldots , P_{T+1|T}, P_{T+2|T}, \ldots , P_{T+\mbox{lead}|T})^{\prime }$.

initial

is an $N_ d \times (N_ d + 1)$ matrix that contains an estimate and its variance for initial state $\delta $, that is, $(\hat{\delta }_ T, \hat{\Sigma }_{\delta , T})$.

s2

is a scalar that contains the estimated variance $\hat{\sigma }^2_ T$.

The KALDFF call computes the one-step forecast of state vectors in an SSM by using the diffuse Kalman filter. The SSM for the diffuse Kalman filter is written

$\displaystyle  y_ t  $
$\displaystyle  =  $
$\displaystyle  X_ t \beta + H_ t z_ t + \epsilon _ t  $
$\displaystyle  z_{t+1}  $
$\displaystyle  =  $
$\displaystyle  W_ t \beta + F_ t z_ t + \eta _ t  $
$\displaystyle  z_0  $
$\displaystyle  =  $
$\displaystyle  a + A \delta  $
$\displaystyle  \beta  $
$\displaystyle  =  $
$\displaystyle  b + B \delta  $

where $z_ t$ is an $N_ z \times 1$ state vector, $y_ t$ is an $N_ y \times 1$ observed vector, and

$\displaystyle  \left[ \begin{array}{c} \eta _ t \\ \epsilon _ t \end{array} \right]  $
$\displaystyle  \sim  $
$\displaystyle  N \left(\mb {0}, \sigma ^2 \left[ \begin{array}{cc} V_ t &  G_ t \\ G^{\prime }_ t &  R_ t \end{array} \right] \right)  $
$\displaystyle \delta  $
$\displaystyle  \sim  $
$\displaystyle  N(\mu , \sigma ^2\Sigma )  $

It is assumed that the noise vector $(\eta ^{\prime }_ t, \epsilon ^{\prime }_ t)^{\prime }$ is independent and $\delta $ is independent of the vector $(\eta ^{\prime }_ t, \epsilon ^{\prime }_ t)^{\prime }$. The matrices, $W_ t$, $F_ t$, $X_ t$, $H_ t$, $a$, $A$, $b$, $B$, $V_ t$, $G_ t$, and $R_ t$, are assumed to be known. The KALDFF call estimates the conditional expectation of the state vector $z_ t$ given the observations. The KALDFF subroutine also produces the estimates of the initial random vector $\delta $ and its covariance matrix. For $k$-step forecasting where $k>0$, the estimated conditional expectation at time $t + k$ is computed with observations given up to time $t$. The estimated $k$-step forecast and its estimated MSE are denoted $z_{t+k|t}$ and $P_{t+k|t}$ (for $k>0$). $A_{t+k(\delta )}$ and $E_{t(\delta )}$ are last-column-deleted submatrices of $A_{t+k}$ and $E_ t$, respectively. The algorithm for one-step prediction is given as follows:

$\displaystyle  E_ t  $
$\displaystyle  =  $
$\displaystyle  (X_ t B, ~  y_ t - X_ t b) - H_ t A_ t  $
$\displaystyle  D_ t  $
$\displaystyle  =  $
$\displaystyle  H_ t M_ t H^{\prime }_ t + R_ t  $
$\displaystyle  Q_{t+1}  $
$\displaystyle  =  $
$\displaystyle  Q_ t + E^{\prime }_ t D_ t^- E_ t  $
$\displaystyle  $
$\displaystyle  =  $
$\displaystyle  \left[\begin{array}{cc} S_ t &  s_ t \\ s^{\prime }_ t &  q_ t \end{array} \right]  $
$\displaystyle  \hat{\sigma }^2_ t  $
$\displaystyle  =  $
$\displaystyle  (q_ t - s^{\prime }_ t S_ t^- s_ t)/n_ t  $
$\displaystyle  \hat{\delta }_ t  $
$\displaystyle  =  $
$\displaystyle  S^-_ t s_ t  $
$\displaystyle  \hat{\Sigma }_{\delta ,t}  $
$\displaystyle  =  $
$\displaystyle  \hat{\sigma }^2_ t S^-_ t  $
$\displaystyle  K_ t  $
$\displaystyle  =  $
$\displaystyle  (F_ t M_ t H^{\prime }_ t + G_ t)D^-_ t  $
$\displaystyle  A_{t+1}  $
$\displaystyle  =  $
$\displaystyle  W_ t(-B, b) + F_ t A_ t + K_ tE_ t  $
$\displaystyle  M_{t+1}  $
$\displaystyle  =  $
$\displaystyle  (F_ t - K_ t H_ t) M_ t F^{\prime }_ t + V_ t - K_ t G^{\prime }_ t  $
$\displaystyle  z_{t+1|t}  $
$\displaystyle  =  $
$\displaystyle  A_{t+1}(-\hat{\delta }^{\prime }_ t, 1)^{\prime }  $
$\displaystyle  P_{t+1|t}  $
$\displaystyle  =  $
$\displaystyle  \hat{\sigma }^2_ t \bM _{t+1} + A_{t+1(\delta )} \hat{\Sigma }_{\delta ,t} A^{\prime }_{t+1(\delta )}  $

where $n_ t$ is the number of elements of $(y_1,\ldots ,y_ t)^{\prime }$ plus $\max (\mbox{\Argument{n0}},0)$. Unless initial values are given and n0$ \geq 0$, initial values are set as follows:

$\displaystyle  A_1  $
$\displaystyle  =  $
$\displaystyle  W_1(-B,b) + F_1(-A,a)  $
$\displaystyle  M_1  $
$\displaystyle  =  $
$\displaystyle  V_1  $
$\displaystyle  Q_1  $
$\displaystyle  =  $
$\displaystyle  \mb {0}  $

For $k$-step forecasting where $k>1$,

$\displaystyle  A_{t+k}  $
$\displaystyle  =  $
$\displaystyle  W_{t+k-1}(-B,b) + F_{t+k-1} A_{t+k-1}  $
$\displaystyle  M_{t+k}  $
$\displaystyle  =  $
$\displaystyle  F_{t+k-1} M_{t+k-1} F^{\prime }_{t+k-1} + V_{t+k-1}  $
$\displaystyle  D_{t+k}  $
$\displaystyle  =  $
$\displaystyle  H_{t+k} M_{t+k} H^{\prime }_{t+k} + R_{t+k}  $
$\displaystyle  z_{t+k|t}  $
$\displaystyle  =  $
$\displaystyle  A_{t+k}(-\hat{\delta }^{\prime }_ t,1)^{\prime }  $
$\displaystyle  P_{t+k|t}  $
$\displaystyle  =  $
$\displaystyle  \hat{\sigma }^2_ t M_{t+k} + A_{t+k(\delta )} \hat{\Sigma }_{\delta ,t} A^{\prime }_{t+k(\delta )}  $

If there is a missing observation, the KALDFF call computes the one-step forecast for the observation that follows the missing observation as the two-step forecast from the previous observation.

An example that uses the KALDFF call is in the documentation for the KALDFS call.