Normal operators for momentum ray transforms, II: Saint Venant operator
The momentum ray transform $I_m^k$ integrates a rank $m$ symmetric tensor field $f$ on ${\mathbb R}^n$ over lines with the weight $t^k$, $I_m^kf(x,\xi)=\int_{-\infty}^\infty t^k\langle f(x+t\xi),\xi^m\rangle\,\mathrm{d}t$. Let $N^k_m=(I^k_m)^*I^k_m$ be the normal operator of $I_m^k$. To what extent...
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| Zusammenfassung: | The momentum ray transform $I_m^k$ integrates a rank $m$ symmetric tensor
field $f$ on ${\mathbb R}^n$ over lines with the weight $t^k$,
$I_m^kf(x,\xi)=\int_{-\infty}^\infty t^k\langle
f(x+t\xi),\xi^m\rangle\,\mathrm{d}t$. Let $N^k_m=(I^k_m)^*I^k_m$ be the normal
operator of $I_m^k$. To what extent is a symmetric $m$-tensor field $f$
determined by the data $(N_m^0f,\dots,N_m^rf)$ given for some $0\le r\le m$?
The Saint Venant operator $W^r_m$ is a linear differential operator of order
$m-r$ with constant coefficients on the space of symmetric $m$-tensor fields.
We derive an explicit formula expressing $W^r_mf$ in terms of
$(N_m^0f,\dots,N_m^rf)$. The tensor field $W^r_mf$ represents the full local
information on $f$ that can be extracted from the data $(N_m^0f,\dots,N_m^rf)$. |
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| DOI: | 10.48550/arxiv.2408.08085 |