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DW Displacement Inputs

We define general DW inputs as follows:

$\displaystyle y^{+}_{n,m}$ $\displaystyle =$ $\displaystyle y^{+}_{n-1,m-1} + (\underline{\gamma}^{+}_m)^T \underline{\upsilon}(n)$ (E.33)
$\displaystyle y^{-}_{n,m}$ $\displaystyle =$ $\displaystyle y^{-}_{n-1,m+1} + (\underline{\gamma}^{-}_m)^T \underline{\upsilon}(n)$ (E.34)

The $ m$ th $ 2q\times2$ block of the input matrix $ {\mathbf{B}_W}$ driving state components $ [y^{+}_{n+2,m},y^{-}_{n+2,m}]^T$ and multiplying $ [\underline{\upsilon}(n+2)^T,\underline{\upsilon}(n+1)^T]^T$ is then given by

$\displaystyle \left({\mathbf{B}_W}\right)_m = \left[\! \begin{array}{cc} (\underline{\gamma}^{+}_m)^T & (\underline{\gamma}^{+}_{m-1})^T \\ [5pt] (\underline{\gamma}^{-}_m)^T & (\underline{\gamma}^{-}_{m+1})^T \end{array} \!\right]. \protect$ (E.35)

Typically, input signals are injected equally to the left and right along the string, in which case

$\displaystyle \underline{\gamma}^{+}_m = \underline{\gamma}^{-}_m \isdef \underline{\gamma}_m.
$

Physically, this corresponds to applied forces at a single, non-moving, string position over time. The state update with this simplification appears as

\begin{displaymath}
\underbrace{\left[\!
\begin{array}{c}
\vdots\\
y^{+}_{n+2,m}\\ [5pt]
y^{-}_{n+2,m}\\
\vdots
\end{array}\!\right]}_{\underline{x}_W(n+2)}
=\mathbf{A}_W\underline{x}_W(n) +
\underbrace{\left[\!
\begin{array}{cc}
\vdots & \vdots\\
\underline{\gamma}_m^T & \underline{\gamma}_{m-1}^T \\ [5pt]
\underline{\gamma}_m^T & \underline{\gamma}_{m+1}^T \\ [5pt]
\vdots & \vdots
\end{array}\!\right]}_{{\mathbf{B}_W}}
\underbrace{\left[\!
\begin{array}{c}
\underline{\upsilon}(n+2)\\
\underline{\upsilon}(n+1)
\end{array}\!\right]}_{\underline{u}(n+2)}.
\end{displaymath}

Note that if there are no inputs driving the adjacent subgrid ( $ \underline{\gamma}_{m-1}=\underline{\gamma}_{m+1}=0$ ), such as in a half-rate staggered grid scheme, the input reduces to

\begin{displaymath}
\underline{x}_W(n+2) = \mathbf{A}_W\underline{x}_W(n) +
\underbrace{\left[\!
\begin{array}{c}
\vdots\\
\underline{\gamma}_{m-2}^T \\ [5pt]
\underline{\gamma}_{m-2}^T \\ [5pt]
\underline{\gamma}_m^T \\ [5pt]
\underline{\gamma}_m^T \\ [5pt]
\underline{\gamma}_{m+2}^T \\ [5pt]
\underline{\gamma}_{m+2}^T \\ [5pt]
\vdots
\end{array}\!\right]}_{{\mathbf{B}_W}}
\underline{\upsilon}(n+2).
\end{displaymath}

To show that the directly obtained FDTD and DW state-space models correspond to the same dynamic system, it remains to verify that $ \mathbf{A}_W=\mathbf{T}^{-1}\mathbf{A}_K\,\mathbf{T}$ . It is somewhat easier to show that

\begin{eqnarray*}
\mathbf{T}\,\mathbf{A}_W&=& \mathbf{A}_K\,\mathbf{T}\\
&=&
\left[\!
\begin{array}{cccccccccccc}
& \vdots & \vdots & \vdots & \vdots & \vdots & \vdots & \vdots & \vdots & \vdots & \vdots\\
\cdots & 1 & 0 & 0 & 0 & 0 & 1 & 0 & 0 & 0 & 0 & \cdots\\
\cdots & 0 & 0 & 1 & 0 & 0 & 1 & 0 & 0 & 0 & 0 & \cdots\\
\cdots & 0 & 0 & 1 & 0 & 0 & 0 & 0 & 1 & 0 & 0 & \cdots\\
\cdots & 0 & 0 & 0 & 0 & 1 & 0 & 0 & 1 & 0 & 0 & \cdots\\
& \vdots & \vdots & \vdots & \vdots & \vdots & \vdots & \vdots & \vdots & \vdots & \vdots
\end{array}\!\right].
\end{eqnarray*}

A straightforward calculation verifies that the above identity holds, as expected. One can similarly verify $ \mathbf{C}_W=\mathbf{C}_K\,\mathbf{T}$ , as expected. The relation $ {\mathbf{B}_W}=\mathbf{T}^{-1}\,\mathbf{B}_K$ provides a recipe for translating any choice of input signals for the FDTD model to equivalent inputs for the DW model, or vice versa. For example, in the scalar input case ($ q=1$ ), the DW input-weights $ {\mathbf{B}_W}$ become FDTD input-weights $ \mathbf{B}_K$ according to

\begin{displaymath}
\left[\!
\begin{array}{l}
\qquad\vdots\\
y_{n+1,m-1}\\
y_{n+2,m}\\
y_{n+1,m+1}\\
y_{n+2,m+2}\\
\qquad\vdots
\end{array}\!\right]
\!
\leftarrow
\!
\underbrace{\left[\!
\begin{array}{cc}
\vdots & \vdots\\
\gamma^{+}_m +\gamma^{-}_{m-1} \,&\, \gamma^{+}_{m-1}+\gamma^{-}_{m-1} \\ [5pt]
\gamma^{+}_m +\gamma^{-}_m \,&\, \gamma^{+}_{m-1}+\gamma^{-}_{m+1} \\ [5pt]
\gamma^{-}_m +\gamma^{+}_{m+1} \,&\, \gamma^{+}_{m+1}\gamma^{-}_{m+1} \\ [5pt]
\gamma^{+}_{m+2}+\gamma^{-}_{m+2} \,&\, \gamma^{+}_{m+1}+\gamma^{-}_{m+3} \\ [5pt]
\vdots & \vdots
\end{array}\!\right]}_{\mathbf{B}_K}
\!
\left[\!
\begin{array}{c}
\underline{\upsilon}(n+2)\\
\underline{\upsilon}(n+1)
\end{array}\!\right]
\end{displaymath}

The left- and right-going input-weight superscripts indicate the origin of each coefficient. Setting $ \gamma^{+}_m=\gamma^{-}_m$ results in

$\displaystyle \mathbf{B}_K= \left[\! \begin{array}{cc} \vdots & \vdots\\ \gamma _m +\gamma _{m-1} \,&\, 2\gamma _{m-1} \\ [5pt] 2\gamma _m \,&\, \gamma _{m-1}+\gamma _{m+1} \\ [5pt] \gamma _m +\gamma _{m+1} \,&\, 2\gamma _{m+1} \\ [5pt] 2\gamma _{m+2} \,&\, \gamma _{m+1}+\gamma _{m+3} \\ [5pt] \vdots & \vdots \end{array} \!\right] \protect$ (E.36)

Finally, when $ \gamma _m=1$ and $ \gamma _{\mu}=0$ for all $ \mu\neq m$ , we obtain the result familiar from Eq.(E.23):

\begin{displaymath}
\mathbf{B}_K=
\left[\!
\begin{array}{cc}
\vdots & \vdots\\
1 & 0 \\
2 & 0 \\
1 & 0 \\
\vdots & \vdots
\end{array}\!\right]
\end{displaymath}

Similarly, setting $ \gamma^{\pm}_{\mu}=0$ for all $ \mu\neq m+1$ , the weighting pattern $ (1,2,1)$ appears in the second column, shifted down one row. Thus, $ \mathbf{B}_K$ in general (for physically stationary displacement inputs) can be seen as the superposition of weight patterns $ (1,2,1)$ in the left column for even $ m$ , and the right column for odd $ m$ (the other subgrid), where the $ 2$ is aligned with the driven sample. This is the general collection of displacement inputs.


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``Physical Audio Signal Processing'', by Julius O. Smith III, W3K Publishing, 2010, ISBN 978-0-9745607-2-4
Copyright © 2024-06-28 by Julius O. Smith III
Center for Computer Research in Music and Acoustics (CCRMA),   Stanford University
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