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In applied mathematics, the transfer matrix is a formulation in terms of a block-Toeplitz matrix of the two-scale equation, which characterizes refinable functions. Refinable functions play an important role in wavelet theory and finite element theory.

For the mask ${\displaystyle h}$, which is a vector with component indexes from ${\displaystyle a}$ to ${\displaystyle b}$, the transfer matrix of ${\displaystyle h}$, we call it ${\displaystyle T_{h}}$ here, is defined as

${\displaystyle (T_{h})_{j,k}=h_{2\cdot j-k}.}$

More verbosely

${\displaystyle T_{h}={\begin{pmatrix}h_{a}&&&&&\\h_{a+2}&h_{a+1}&h_{a}&&&\\h_{a+4}&h_{a+3}&h_{a+2}&h_{a+1}&h_{a}&\\\ddots &\ddots &\ddots &\ddots &\ddots &\ddots \\&h_{b}&h_{b-1}&h_{b-2}&h_{b-3}&h_{b-4}\\&&&h_{b}&h_{b-1}&h_{b-2}\\&&&&&h_{b}\end{pmatrix}}.}$

The effect of ${\displaystyle T_{h}}$ can be expressed in terms of the downsampling operator "${\displaystyle \downarrow }$":

${\displaystyle T_{h}\cdot x=(h*x)\downarrow 2.}$

Properties

• ${\displaystyle T_{h}\cdot x=T_{x}\cdot h}$.
• If you drop the first and the last column and move the odd-indexed columns to the left and the even-indexed columns to the right, then you obtain a transposed Sylvester matrix.
• The determinant of a transfer matrix is essentially a resultant.

More precisely:

Let ${\displaystyle h_{\mathrm {e} }}$ be the even-indexed coefficients of ${\displaystyle h}$ (${\displaystyle (h_{\mathrm {e} })_{k}=h_{2k}}$) and let ${\displaystyle h_{\mathrm {o} }}$ be the odd-indexed coefficients of ${\displaystyle h}$ (${\displaystyle (h_{\mathrm {o} })_{k}=h_{2k+1}}$).

Then ${\displaystyle \det T_{h}=(-1)^{\lfloor {\frac {b-a+1}{4}}\rfloor }\cdot h_{a}\cdot h_{b}\cdot \mathrm {res} (h_{\mathrm {e} },h_{\mathrm {o} })}$, where ${\displaystyle \mathrm {res} }$ is the resultant.

This connection allows for fast computation using the Euclidean algorithm.

• For the trace of the transfer matrix of convolved masks holds

${\displaystyle \mathrm {tr} ~T_{g*h}=\mathrm {tr} ~T_{g}\cdot \mathrm {tr} ~T_{h}}$

• For the determinant of the transfer matrix of convolved mask holds

${\displaystyle \det T_{g*h}=\det T_{g}\cdot \det T_{h}\cdot \mathrm {res} (g_{-},h)}$

where ${\displaystyle g_{-}}$ denotes the mask with alternating signs, i.e. ${\displaystyle (g_{-})_{k}=(-1)^{k}\cdot g_{k}}$.

• If ${\displaystyle T_{h}\cdot x=0}$, then ${\displaystyle T_{g*h}\cdot (g_{-}*x)=0}$.

This is a concretion of the determinant property above. From the determinant property one knows that ${\displaystyle T_{g*h}}$ is singular whenever ${\displaystyle T_{h}}$ is singular. This property also tells, how vectors from the null space of ${\displaystyle T_{h}}$ can be converted to null space vectors of ${\displaystyle T_{g*h}}$.

• If ${\displaystyle x}$ is an eigenvector of ${\displaystyle T_{h}}$ with respect to the eigenvalue ${\displaystyle \lambda }$, i.e.

${\displaystyle T_{h}\cdot x=\lambda \cdot x}$,

then ${\displaystyle x*(1,-1)}$ is an eigenvector of ${\displaystyle T_{h*(1,1)}}$ with respect to the same eigenvalue, i.e.

${\displaystyle T_{h*(1,1)}\cdot (x*(1,-1))=\lambda \cdot (x*(1,-1))}$.

• Let ${\displaystyle \lambda _{a},\dots ,\lambda _{b}}$ be the eigenvalues of ${\displaystyle T_{h}}$, which implies ${\displaystyle \lambda _{a}+\dots +\lambda _{b}=\mathrm {tr} ~T_{h}}$ and more generally ${\displaystyle \lambda _{a}^{n}+\dots +\lambda _{b}^{n}=\mathrm {tr} (T_{h}^{n})}$. This sum is useful for estimating the spectral radius of ${\displaystyle T_{h}}$. There is an alternative possibility for computing the sum of eigenvalue powers, which is faster for small ${\displaystyle n}$.

Let ${\displaystyle C_{k}h}$ be the periodization of ${\displaystyle h}$ with respect to period ${\displaystyle 2^{k}-1}$. That is ${\displaystyle C_{k}h}$ is a circular filter, which means that the component indexes are residue classes with respect to the modulus ${\displaystyle 2^{k}-1}$. Then with the upsampling operator ${\displaystyle \uparrow }$ it holds

${\displaystyle \mathrm {tr} (T_{h}^{n})=\left(C_{k}h*(C_{k}h\uparrow 2)*(C_{k}h\uparrow 2^{2})*\cdots *(C_{k}h\uparrow 2^{n-1})\right)_{[0]_{2^{n}-1}}}$

Actually not ${\displaystyle n-2}$ convolutions are necessary, but only ${\displaystyle 2\cdot \log _{2}n}$ ones, when applying the strategy of efficient computation of powers. Even more the approach can be further sped up using the Fast Fourier transform.

• From the previous statement we can derive an estimate of the spectral radius of ${\displaystyle \varrho (T_{h})}$. It holds

${\displaystyle \varrho (T_{h})\geq {\frac {a}{\sqrt {\#h}}}\geq {\frac {1}{\sqrt {3\cdot \#h}}}}$

where ${\displaystyle \#h}$ is the size of the filter and if all eigenvalues are real, it is also true that

${\displaystyle \varrho (T_{h})\leq a}$,

where ${\displaystyle a=\Vert C_{2}h\Vert _{2}}$.

See also

• Transfer matrix method
• Hurwitz determinant

References

• Template:Cite article
• Template:Cite thesis (contains proofs of the above properties)