Add ray tracing
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@ -64,7 +64,7 @@ In order to increase the accuracy of the metrology system, two problems are to b
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<<sec:metrology_concept>>
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<<sec:metrology_concept>>
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** Introduction :ignore:
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** Introduction :ignore:
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The goal of the metrology system is to measure the distance and default of parallelism orientation between the first and second crystals
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The goal of the metrology system is to measure the distance and default of parallelism between the first and second crystals.
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Only 3 degrees of freedom are of interest:
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Only 3 degrees of freedom are of interest:
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- $d_z$
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- $d_z$
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@ -86,12 +86,16 @@ In order to measure the relative pose of the two crystals, instead of performing
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Three interferometers are used to measured the 3dof of interest for each crystals.
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Three interferometers are used to measured the 3dof of interest for each crystals.
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Three additional interferometers are used to measured the relative motion of the metrology frame.
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Three additional interferometers are used to measured the relative motion of the metrology frame.
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In total, there are 15 interferometers represented in Figure [[fig:metrology_schematic]].
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The measurements are summarized in Table [[tab:interferometer_list]].
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#+name: tab:metrology_notations
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#+name: tab:metrology_notations
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#+caption: Notations for the metrology frame
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#+caption: Notations for the metrology frame
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#+attr_latex: :environment tabularx :width 0.4\linewidth :align cX
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#+attr_latex: :environment tabularx :width 0.4\linewidth :align cX
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#+attr_latex: :center t :booktabs t
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#+attr_latex: :center t :booktabs t
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| Notation | Meaning |
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| *Notation* | *Meaning* |
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|----------+--------------------------|
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|------------+--------------------------|
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| =d= | "Downstream": Positive X |
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| =d= | "Downstream": Positive X |
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| =u= | "Upstream": Negative X |
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| =u= | "Upstream": Negative X |
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| =h= | "Hall": Positive Y |
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| =h= | "Hall": Positive Y |
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@ -100,182 +104,91 @@ Three additional interferometers are used to measured the relative motion of the
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| =1= | "First Crystals" |
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| =1= | "First Crystals" |
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| =2= | "Second Crystals" |
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| =2= | "Second Crystals" |
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#+name: tab:interferometer_list
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#+caption: List of Interferometer measurements
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#+attr_latex: :environment tabularx :width 0.7\linewidth :align ccl
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#+attr_latex: :center t :booktabs t
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| *Number* | *Measurement* | *Description* |
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|----------+---------------+-------------------------------------|
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| 1 | $z_{1r,u}$ | First "Ring" Crystal, "upstream" |
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| 2 | $z_{1r,c}$ | First "Ring" Crystal, "center" |
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| 3 | $z_{1r,d}$ | First "Ring" Crystal, "downstream" |
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| 4 | $z_{1h,u}$ | First "Hall" Crystal, "upstream" |
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| 5 | $z_{1h,c}$ | First "Hall" Crystal, "center" |
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| 6 | $z_{1h,d}$ | First "Hall" Crystal, "downstream" |
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| 7 | $z_{2h,u}$ | Second "Hall" Crystal, "upstream" |
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| 8 | $z_{2h,c}$ | Second "Hall" Crystal, "center" |
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| 9 | $z_{2h,d}$ | Second "Hall" Crystal, "downstream" |
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| 10 | $z_{2r,u}$ | Second "Ring" Crystal, "upstream" |
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| 11 | $z_{2r,c}$ | Second "Ring" Crystal, "center" |
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| 12 | $z_{2r,d}$ | Second "Ring" Crystal, "downstream" |
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| 13 | $z_{mf,u}$ | Metrology Frame, "upstream" |
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| 14 | $z_{mf,dr}$ | Metrology Frame, "downstream-ring" |
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| 15 | $z_{mf,dh}$ | Metrology Frame, "downstream-hall" |
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#+name: fig:metrology_schematic
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#+name: fig:metrology_schematic
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#+caption: Schematic of the Metrology System
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#+caption: Schematic of the Metrology System
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[[file:figs/metrology_schematic.png]]
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[[file:figs/metrology_schematic.png]]
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** Crystal's motion computation
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** Computation of the relative pose between first and second crystals
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From the raw interferometric measurements, the pose between the first and second crystals can be computed.
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To understand how the relative pose between the crystals is computed from the interferometer signals, have a look at [[https://gitlab.esrf.fr/dehaeze/dcm-kinematics][this repository]] (=https://gitlab.esrf.fr/dehaeze/dcm-kinematics=).
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First, Jacobian matrices can be used to convert raw interferometer measurements to axial displacement and orientation of the crystals and metrology frame.
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Basically, Jacobian matrices are derived from the geometry and are used to convert the 15 interferometer signals to the *relative pose* of the primary and secondary crystals $[d_{h,z},\ r_{h,y},\ r_{h,x}]$ or $[d_{r,z},\ r_{r,y},\ r_{r,x}]$.
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For the 311 crystals:
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#+begin_note
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The sign conventions for the relative crystal pose are:
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- An increase of $d_{h,z}$ means the two crystals are further apart
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- An increase of $r_{h,}$ means that the second crystals experiences a rotation around $y$ with respect to the primary crystal
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- An increase of $r_{h,x}$ means that the second crystals experiences a rotation around $x$ with respect to the primary crystal
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#+end_note
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#+name: tab:311_crystals_notations_raw_interf
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The relative pose can be expressed as a function of the interferometers using the Jacobian matrices for the "hall" crystals:
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#+caption: Table caption
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\begin{equation}
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#+attr_latex: :environment tabularx :width 0.5\linewidth :align lX
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\boxed{
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#+attr_latex: :center t :booktabs t
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\begin{bmatrix} d_{h,z} \\ r_{h,y} \\ r_{h,x} \end{bmatrix}
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| Notation | Description |
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=
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|----------+-----------------------------------|
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\bm{J}_{2h,s}^{-1}
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| =um= | Metrology Frame - Upstream |
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\begin{bmatrix} z_{2h,u} \\ z_{2h,c} \\ z_{2h,d} \end{bmatrix}
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| =dhm= | Metrology Frame - Downstream Hall |
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-
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| =drm= | Metrology Frame - Downstream Ring |
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\bm{J}_{1h,s}^{-1}
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|----------+-----------------------------------|
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\begin{bmatrix} z_{1h,u} \\ z_{1h,c} \\ z_{1h,d} \end{bmatrix}
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| =ur1= | First Crystal - Upstream Ring |
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-
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| =h1= | First Crystal - Hall |
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\bm{J}_{mf,s}^{-1}
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| =dr1= | First Crystal - Downstream Ring |
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\begin{bmatrix} z_{mf,u} \\ z_{mf,dh} \\ z_{mf,dr} \end{bmatrix}
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|----------+-----------------------------------|
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}
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| =ur2= | First Crystal - Upstream Ring |
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\end{equation}
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| =h2= | First Crystal - Hall |
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| =dr2= | First Crystal - Downstream Ring |
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#+name: tab:311_crystals_notations_converted_interf
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As well as for the "ring" crystals:
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#+caption: Table caption
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\begin{equation}
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#+attr_latex: :environment tabularx :width 0.5\linewidth :align lX
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\boxed{
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#+attr_latex: :center t :booktabs t
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\begin{bmatrix} d_{r,z} \\ r_{r,y} \\ r_{r,x} \end{bmatrix}
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| Notation | Description |
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=
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|----------+--------------------------------|
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\bm{J}_{2r,s}^{-1}
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| =dzm= | Positive: increase of distance |
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\begin{bmatrix} z_{2r,u} \\ z_{2r,c} \\ z_{2r,d} \end{bmatrix}
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| =rym= | |
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-
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| =rxm= | |
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\bm{J}_{1r,s}^{-1}
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|----------+--------------------------------|
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\begin{bmatrix} z_{1r,u} \\ z_{1r,c} \\ z_{1r,d} \end{bmatrix}
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| =dz1= | Positive: decrease of distance |
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-
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| =ry1= | |
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\bm{J}_{mf,s}^{-1}
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| =rx1= | |
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\begin{bmatrix} z_{mf,u} \\ z_{mf,dr} \\ z_{mf,dr} \end{bmatrix}
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|----------+--------------------------------|
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}
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| =dz2= | Positive: increase of distance |
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\end{equation}
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| =ry2= | |
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| =rx2= | |
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#+begin_src latex :file schematic_sensor_jacobian_forward_kinematics_m.pdf
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Values of the matrices can be found in the document describing the kinematics of the DCM (see =https://gitlab.esrf.fr/dehaeze/dcm-kinematics=).
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\begin{tikzpicture}
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% Blocs
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\node[block] (Js_inv) {$\bm{J}_{s,m}^{-1}$};
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% Connections and labels
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\draw[->] ($(Js_inv.west)+(-1.5,0)$) node[above right]{$\begin{bmatrix} u_{m} \\ dh_{m} \\ dr_{m} \end{bmatrix}$} -- (Js_inv.west);
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\draw[->] (Js_inv.east) -- ++(1.5, 0) node[above left]{$\begin{bmatrix} d_{zm} \\ r_{ym} \\ r_{xm} \end{bmatrix}$};
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\end{tikzpicture}
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#+end_src
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#+name: fig:schematic_sensor_jacobian_forward_kinematics_m
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#+caption: Forward Kinematics for the Metrology frame
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#+RESULTS:
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[[file:figs/schematic_sensor_jacobian_forward_kinematics_m.png]]
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#+begin_src latex :file schematic_sensor_jacobian_forward_kinematics_1.pdf
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\begin{tikzpicture}
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% Blocs
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\node[block] (Js_inv) {$\bm{J}_{s,1}^{-1}$};
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% Connections and labels
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\draw[->] ($(Js_inv.west)+(-1.5,0)$) node[above right]{$\begin{bmatrix} u_{r1} \\ h_1 \\ d_{r1} \end{bmatrix}$} -- (Js_inv.west);
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\draw[->] (Js_inv.east) -- ++(1.5, 0) node[above left]{$\begin{bmatrix} d_{z1} \\ r_{y1} \\ r_{x1} \end{bmatrix}$};
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\end{tikzpicture}
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#+end_src
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#+name: fig:schematic_sensor_jacobian_forward_kinematics_1
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#+caption: Forward Kinematics for the 1st crystal
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#+RESULTS:
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[[file:figs/schematic_sensor_jacobian_forward_kinematics_1.png]]
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#+begin_src latex :file schematic_sensor_jacobian_forward_kinematics_2.pdf
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\begin{tikzpicture}
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% Blocs
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\node[block] (Js_inv) {$\bm{J}_{s,2}^{-1}$};
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% Connections and labels
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\draw[->] ($(Js_inv.west)+(-1.5,0)$) node[above right]{$\begin{bmatrix} u_{r2} \\ h_2 \\ d_{r2} \end{bmatrix}$} -- (Js_inv.west);
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\draw[->] (Js_inv.east) -- ++(1.5, 0) node[above left]{$\begin{bmatrix} d_{z2} \\ r_{y2} \\ r_{x2} \end{bmatrix}$};
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\end{tikzpicture}
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#+end_src
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#+name: fig:schematic_sensor_jacobian_forward_kinematics_2
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#+caption: Forward Kinematics for the 2nd crystal
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#+RESULTS:
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[[file:figs/schematic_sensor_jacobian_forward_kinematics_2.png]]
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Then, the displacement and orientations can be combined as follows:
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\begin{align}
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d_{z} &= + d_{z1} - d_{z2} + d_{zm} \\
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d_{r_y} &= - r_{y1} + r_{y2} - r_{ym} \\
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d_{r_x} &= - r_{x1} + r_{x2} - r_{xm}
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\end{align}
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Therefore:
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- $d_z$ represents the distance between the two crystals
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- $d_{r_y}$ represents the rotation of the second crystal w.r.t. the first crystal around $y$ axis
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- $d_{r_x}$ represents the rotation of the second crystal w.r.t. the first crystal around $x$ axis
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If $d_{r_y}$ is positive, the second crystal has a positive rotation around $y$ w.r.t. the first crystal.
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Therefore, the second crystal should be actuated such that it is making a negative rotation around $y$ w.r.t. metrology frame.
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The Jacobian matrices are defined as follow:
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#+begin_src matlab
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%% Sensor Jacobian matrix for the metrology frame
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J_m = [1, 0.102, 0
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1, -0.088, 0.1275
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1, -0.088, -0.1275];
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%% Sensor Jacobian matrix for 1st "111" crystal
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J_s_111_1 = [-1, -0.036, -0.015
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-1, 0, 0.015
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-1, 0.036, -0.015];
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%% Sensor Jacobian matrix for 2nd "111" crystal
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J_s_111_2 = [1, 0.07, 0.015
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1, 0, -0.015
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1, -0.07, 0.015];
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#+end_src
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Therefore, the matrix that gives the relative pose of the crystal from the 9 interferometers is:
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#+begin_src matlab
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%% Compute the transformation matrix
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G_111_t = [-inv(J_s_111_1), inv(J_s_111_2), -inv(J_m)];
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% Sign convention for the axial motion
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G_111_t(1,:) = -G_111_t(1,:);
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#+end_src
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#+begin_src matlab :exports results :results value table replace :tangle no :post addhdr(*this*)
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data2orgtable(G_111_t, ...
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{'=dz= [nm]', '=rx= [nrad]', '=ry= [nrad]'}, ...
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{'=ur1= [nm]', '=h1= [nm]', '=dr1= [nm]', '=ur2= [nm]', '=h2= [nm]', '=dr1= [nm]', '=um= [nm]', '=dhm= [nm]', '=drm= [nm]'}, ...
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' %.3f ');
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#+end_src
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#+name: tab:transformation_matrix
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#+caption: Transformation Matrix
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#+attr_latex: :environment tabularx :width \linewidth :align cccccccccc
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#+attr_latex: :center t :booktabs t :font \scriptsize
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#+RESULTS:
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| | =ur1= [nm] | =h1= [nm] | =dr1= [nm] | =ur2= [nm] | =h2= [nm] | =dr1= [nm] | =um= [nm] | =dhm= [nm] | =drm= [nm] |
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|-------------+------------+-----------+------------+------------+-----------+------------+-----------+------------+------------|
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| =dz= [nm] | -0.25 | -0.5 | -0.25 | -0.25 | -0.5 | -0.25 | 0.463 | 0.268 | 0.268 |
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| =rx= [nrad] | 13.889 | 0.0 | -13.889 | 7.143 | 0.0 | -7.143 | -5.263 | 2.632 | 2.632 |
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| =ry= [nrad] | 16.667 | -33.333 | 16.667 | 16.667 | -33.333 | 16.667 | 0.0 | -3.922 | 3.922 |
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From table [[fig:schematic_sensor_jacobian_forward_kinematics_2]], we can determine the effect of each interferometer on the estimated relative pose between the crystals.
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For instance, an error on =dr1= will have much greater impact on =ry= than an error on =drm=.
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* Relation Between Crystal position and X-ray measured displacement
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* Relation Between Crystal position and X-ray measured displacement
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** Setup
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<<sec:relation_crystal_xray>>
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** Introduction :ignore:
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#+name: fig:calibration_setup
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In this section, the impact of an error in the relative pose between the first and second crystals on the output X-ray beam is studied.
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#+caption: Schematic of the setup
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[[file:figs/calibration_setup.png]]
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Detector:
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This is very important in order to:
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- link a measurement of the x-ray beam position to a default in the crystal position
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- understand which pose default will have large impact on the output beam position/orientation
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- calibrate the deformations of the metrology frame using and external metrology measuring the x-ray beam position/orientation
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https://www.baslerweb.com/en/products/cameras/area-scan-cameras/ace/aca1920-40gc/
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In order to simplify the problem, the first crystal is supposed to be fixed (i.e. ideally positioned), and only the motion of the second crystal is studied.
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Pixel size depends on the magnification used (1x, 6x, 12x).
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Pixel size of camera is 5.86 um x 5.86 um.
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With typical magnification of 6x, pixel size is ~1.44um x 1.44um
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Frame rate is: 42 fps
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** Matlab Init :noexport:ignore:
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** Matlab Init :noexport:ignore:
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#+begin_src matlab :tangle no :exports none :results silent :noweb yes :var current_dir=(file-name-directory buffer-file-name)
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#+begin_src matlab :tangle no :exports none :results silent :noweb yes :var current_dir=(file-name-directory buffer-file-name)
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@ -290,8 +203,7 @@ Frame rate is: 42 fps
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bragg = pi/180*linspace(5,75,100);
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bragg = pi/180*linspace(5,75,100);
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#+end_src
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#+end_src
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** Relation between second crystal motion and beam motion
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** Axial motion of second crystal
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*** Axial motion of second crystal
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Let's consider the relation between the $[y, z]$ motion of the beam and the motion of the second crystal $[z^\prime, R_{y^\prime}, R_{x^\prime}]$.
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Let's consider the relation between the $[y, z]$ motion of the beam and the motion of the second crystal $[z^\prime, R_{y^\prime}, R_{x^\prime}]$.
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#+name: fig:relation_dz_output_beam
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#+name: fig:relation_dz_output_beam
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@ -319,7 +231,7 @@ exportFig('figs/relation_vert_motion_crystal_beam.pdf', 'width', 'wide', 'height
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#+RESULTS:
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#+RESULTS:
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[[file:figs/relation_vert_motion_crystal_beam.png]]
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[[file:figs/relation_vert_motion_crystal_beam.png]]
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*** Ry motion of second crystal
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** Ry motion of second crystal
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\begin{equation}
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\begin{equation}
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d_z = D_{\text{vlm}} d_{R_y^\prime}
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d_z = D_{\text{vlm}} d_{R_y^\prime}
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@ -327,7 +239,7 @@ d_z = D_{\text{vlm}} d_{R_y^\prime}
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with $D_{\text{vlm}} \approx 10\,m$.
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with $D_{\text{vlm}} \approx 10\,m$.
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*** Rx motion of second crystal
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** Rx motion of second crystal
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\begin{equation}
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\begin{equation}
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||||||
d_y = 2 D_{\text{vlm}} \sin \theta \cdot d_{R_x^\prime}
|
d_y = 2 D_{\text{vlm}} \sin \theta \cdot d_{R_x^\prime}
|
||||||
@ -335,6 +247,173 @@ d_y = 2 D_{\text{vlm}} \sin \theta \cdot d_{R_x^\prime}
|
|||||||
|
|
||||||
|
|
||||||
|
|
||||||
|
* Ray Tracing
|
||||||
|
** Matlab Init :noexport:ignore:
|
||||||
|
#+begin_src matlab :tangle no :exports none :results silent :noweb yes :var current_dir=(file-name-directory buffer-file-name)
|
||||||
|
<<matlab-dir>>
|
||||||
|
#+end_src
|
||||||
|
|
||||||
|
#+begin_src matlab :exports none :results silent :noweb yes
|
||||||
|
<<matlab-init>>
|
||||||
|
#+end_src
|
||||||
|
|
||||||
|
#+begin_src matlab :tangle no :noweb yes
|
||||||
|
<<m-init-path>>
|
||||||
|
#+end_src
|
||||||
|
|
||||||
|
#+begin_src matlab :eval no :noweb yes
|
||||||
|
<<m-init-path-tangle>>
|
||||||
|
#+end_src
|
||||||
|
|
||||||
|
#+begin_src matlab :noweb yes
|
||||||
|
<<m-init-other>>
|
||||||
|
#+end_src
|
||||||
|
|
||||||
|
** Definition of frame
|
||||||
|
|
||||||
|
| | Position | Orientation |
|
||||||
|
|------------------+------------+-------------|
|
||||||
|
| input beam | =x1,y1,z1= | =s1= |
|
||||||
|
| primary mirror | =xp,yp,zp= | =np= |
|
||||||
|
| reflected beam | =x2,y2,z2= | =s2= |
|
||||||
|
| secondary mirror | =xs,ys,zz= | =ns= |
|
||||||
|
| output beam | =x3,y3,z3= | =s3= |
|
||||||
|
|
||||||
|
#+begin_src matlab
|
||||||
|
theta = 5*pi/180; % [rad]
|
||||||
|
#+end_src
|
||||||
|
|
||||||
|
#+begin_src matlab
|
||||||
|
%% Secondary crystal defaults
|
||||||
|
drx = 5*pi/180; % [rad]
|
||||||
|
dry = 0*pi/180; % [rad]
|
||||||
|
dz = 0; % [m]
|
||||||
|
|
||||||
|
% Rotation matrix for drx
|
||||||
|
udrx = [cos(theta), 0, -sin(theta)];
|
||||||
|
Rdrx = cos(drx)*eye(3)+sin(drx)*[0, -udrx(3), udrx(2); udrx(3), 0, -udrx(1); -udrx(2), udrx(1), 0] + (1-cos(drx))*(udrx'*udrx);
|
||||||
|
|
||||||
|
% Rotation matrix for dry
|
||||||
|
Rdry = [ cos(dry), 0, sin(dry); ...
|
||||||
|
0, 1, 0; ...
|
||||||
|
-sin(dry), 0, cos(dry)];
|
||||||
|
#+end_src
|
||||||
|
|
||||||
|
#+begin_src matlab
|
||||||
|
%% Input Beam
|
||||||
|
p1 = [-0.1, 0, 0]; % [m]
|
||||||
|
s1 = [ 1, 0, 0];
|
||||||
|
|
||||||
|
%% Primary Mirror
|
||||||
|
pp = [0, 0, 0]; % [m]
|
||||||
|
np = [cos(pi/2-theta), 0, sin(pi/2-theta)];
|
||||||
|
|
||||||
|
%% Reflected beam
|
||||||
|
[p2, s2] = get_plane_reflection(p1, s1, pp, np);
|
||||||
|
|
||||||
|
%% Secondary Mirror
|
||||||
|
ps = pp ...
|
||||||
|
+ 0.07*[cos(theta), 0, -sin(theta)] ... % x offset (does not matter a lot)
|
||||||
|
- np*10e-3./(2*cos(theta)) ... % Theoretical offset
|
||||||
|
+ np*dz; % Add error in distance
|
||||||
|
|
||||||
|
ns = [Rdry*Rdrx*[cos(pi/2-theta), 0, sin(pi/2-theta)]']'; % Normal
|
||||||
|
|
||||||
|
%% Output Beam
|
||||||
|
[p3, s3] = get_plane_reflection(p2, s2, ps, ns);
|
||||||
|
#+end_src
|
||||||
|
|
||||||
|
#+begin_src matlab
|
||||||
|
%% Primary crystal plane
|
||||||
|
z = np;
|
||||||
|
y = [0,1,0];
|
||||||
|
x = cross(y,z);
|
||||||
|
xtal1_rectangle = [pp + 0.02*y + 0.07*x;
|
||||||
|
pp - 0.02*y + 0.07*x;
|
||||||
|
pp - 0.02*y - 0.07*x;
|
||||||
|
pp + 0.02*y - 0.07*x];
|
||||||
|
|
||||||
|
%% Secondary crystal plane
|
||||||
|
z = ns;
|
||||||
|
y = [0,cos(drx),sin(drx)];
|
||||||
|
x = cross(y,z);
|
||||||
|
xtal2_rectangle = [ps + 0.02*y + 0.07*x;
|
||||||
|
ps - 0.02*y + 0.07*x;
|
||||||
|
ps - 0.02*y - 0.07*x;
|
||||||
|
ps + 0.02*y - 0.07*x];
|
||||||
|
#+end_src
|
||||||
|
|
||||||
|
#+begin_src matlab
|
||||||
|
figure;
|
||||||
|
tiledlayout(2, 1, 'TileSpacing', 'Compact', 'Padding', 'None');
|
||||||
|
|
||||||
|
ax1 = nexttile();
|
||||||
|
hold on;
|
||||||
|
plot3([p1(1), p2(1)],[p1(2), p2(2)], [p1(3), p2(3)])
|
||||||
|
plot3([p2(1), p3(1)],[p2(2), p3(2)], [p2(3), p3(3)])
|
||||||
|
plot3([p3(1), p3(1)+0.3*s3(1)],[p3(2), p3(2)+0.3*s3(2)], [p3(3), p3(3)+0.3*s3(3)])
|
||||||
|
patch(xtal1_rectangle(:,1), xtal1_rectangle(:,2), xtal1_rectangle(:,3), 'k')
|
||||||
|
patch(xtal2_rectangle(:,1), xtal2_rectangle(:,2), xtal2_rectangle(:,3), 'k')
|
||||||
|
hold off;
|
||||||
|
view(0,0)
|
||||||
|
axis equal
|
||||||
|
xlim([-0.1, 0.15])
|
||||||
|
zlim([-0.02, 0.01])
|
||||||
|
grid off;
|
||||||
|
xlabel('X')
|
||||||
|
ylabel('Y')
|
||||||
|
zlabel('Z')
|
||||||
|
|
||||||
|
ax2 = nexttile();
|
||||||
|
hold on;
|
||||||
|
plot3([p1(1), p2(1)],[p1(2), p2(2)], [p1(3), p2(3)])
|
||||||
|
plot3([p2(1), p3(1)],[p2(2), p3(2)], [p2(3), p3(3)])
|
||||||
|
plot3([p3(1), p3(1)+0.3*s3(1)],[p3(2), p3(2)+0.3*s3(2)], [p3(3), p3(3)+0.3*s3(3)])
|
||||||
|
patch(xtal1_rectangle(:,1), xtal1_rectangle(:,2), xtal1_rectangle(:,3), 'k')
|
||||||
|
patch(xtal2_rectangle(:,1), xtal2_rectangle(:,2), xtal2_rectangle(:,3), 'k')
|
||||||
|
hold off;
|
||||||
|
view(0,90)
|
||||||
|
axis equal
|
||||||
|
xlim([-0.1, 0.15])
|
||||||
|
zlim([-0.02, 0.01])
|
||||||
|
grid off;
|
||||||
|
xlabel('X')
|
||||||
|
ylabel('Y')
|
||||||
|
zlabel('Z')
|
||||||
|
#+end_src
|
||||||
|
|
||||||
|
#+begin_src matlab
|
||||||
|
figure;
|
||||||
|
hold on;
|
||||||
|
plot3([p1(1), p2(1)],[p1(2), p2(2)], [p1(3), p2(3)])
|
||||||
|
plot3([p2(1), p3(1)],[p2(2), p3(2)], [p2(3), p3(3)])
|
||||||
|
plot3([p3(1), p3(1)+0.3*s3(1)],[p3(2), p3(2)+0.3*s3(2)], [p3(3), p3(3)+0.3*s3(3)])
|
||||||
|
surf(xtal1_x, xtal1_y, xtal1_z)
|
||||||
|
patch(xtal2_rectangle(:,1), xtal2_rectangle(:,2), xtal2_rectangle(:,3), 'k')
|
||||||
|
hold off;
|
||||||
|
view(0,0)
|
||||||
|
axis equal
|
||||||
|
xlim([-0.1, 0.15])
|
||||||
|
zlim([-0.02, 0.01])
|
||||||
|
grid off;
|
||||||
|
#+end_src
|
||||||
|
|
||||||
|
#+begin_src matlab
|
||||||
|
figure;
|
||||||
|
hold on;
|
||||||
|
plot3([p1(1), p2(1)],[p1(2), p2(2)], [p1(3), p2(3)])
|
||||||
|
plot3([p2(1), p3(1)],[p2(2), p3(2)], [p2(3), p3(3)])
|
||||||
|
plot3([p3(1), p3(1)+0.3*s3(1)],[p3(2), p3(2)+0.3*s3(2)], [p3(3), p3(3)+0.3*s3(3)])
|
||||||
|
surf(xtal1_x, xtal1_y, xtal1_z)
|
||||||
|
patch(xtal2_rectangle(:,1), xtal2_rectangle(:,2), xtal2_rectangle(:,3), 'k')
|
||||||
|
hold off;
|
||||||
|
view(90,90)
|
||||||
|
axis equal
|
||||||
|
xlim([-0.1, 0.15])
|
||||||
|
zlim([-0.02, 0.01])
|
||||||
|
grid off;
|
||||||
|
#+end_src
|
||||||
|
|
||||||
* Deformations of the Metrology Frame
|
* Deformations of the Metrology Frame
|
||||||
<<sec:frame_deformations>>
|
<<sec:frame_deformations>>
|
||||||
** Introduction :ignore:
|
** Introduction :ignore:
|
||||||
@ -356,6 +435,22 @@ For each Bragg angle, the Fast Jacks are actuated to that the beam is at the cen
|
|||||||
Then, then position of the crystals as measured by the interferometers is recorded.
|
Then, then position of the crystals as measured by the interferometers is recorded.
|
||||||
This position is the wanted position for a given Bragg angle.
|
This position is the wanted position for a given Bragg angle.
|
||||||
|
|
||||||
|
#+name: fig:calibration_setup
|
||||||
|
#+caption: Schematic of the setup
|
||||||
|
[[file:figs/calibration_setup.png]]
|
||||||
|
|
||||||
|
Detector:
|
||||||
|
|
||||||
|
https://www.baslerweb.com/en/products/cameras/area-scan-cameras/ace/aca1920-40gc/
|
||||||
|
|
||||||
|
Pixel size depends on the magnification used (1x, 6x, 12x).
|
||||||
|
|
||||||
|
Pixel size of camera is 5.86 um x 5.86 um.
|
||||||
|
With typical magnification of 6x, pixel size is ~1.44um x 1.44um
|
||||||
|
|
||||||
|
Frame rate is: 42 fps
|
||||||
|
|
||||||
|
|
||||||
** Simulations
|
** Simulations
|
||||||
|
|
||||||
The deformations of the metrology frame and therefore the expected interferometric measurements can be computed as a function of the Bragg angle.
|
The deformations of the metrology frame and therefore the expected interferometric measurements can be computed as a function of the Bragg angle.
|
||||||
@ -1050,6 +1145,36 @@ colors = colororder;
|
|||||||
freqs = logspace(1, 3, 1000);
|
freqs = logspace(1, 3, 1000);
|
||||||
#+END_SRC
|
#+END_SRC
|
||||||
|
|
||||||
|
** Intersection between Ray and Plane
|
||||||
|
:PROPERTIES:
|
||||||
|
:header-args:matlab+: :tangle matlab/src/get_plane_reflection.m
|
||||||
|
:header-args:matlab+: :comments none :mkdirp yes :eval no
|
||||||
|
:END:
|
||||||
|
<<sec:get_plane_reflection>>
|
||||||
|
|
||||||
|
#+begin_src matlab
|
||||||
|
function [p_reflect, s_reflect] = get_plane_reflection(p_in, s_in, p_plane, n_plane)
|
||||||
|
% get_plane_reflection -
|
||||||
|
%
|
||||||
|
% Syntax: [p_reflect, s_reflect] = get_plane_reflection(p_in, s_in, p_plane, n_plane)
|
||||||
|
%
|
||||||
|
% Inputs:
|
||||||
|
% - p_in, s_in, p_plane, n_plane -
|
||||||
|
%
|
||||||
|
% Outputs:
|
||||||
|
% - p_reflect, s_reflect -
|
||||||
|
#+end_src
|
||||||
|
|
||||||
|
#+begin_src matlab
|
||||||
|
p_reflect = p_in + s_in*dot(p_plane - p_in, n_plane)/dot(s_in, n_plane);
|
||||||
|
s_reflect = s_in-2*n_plane*dot(s_in, n_plane);
|
||||||
|
s_reflect = s_reflect./norm(s_reflect);
|
||||||
|
#+end_src
|
||||||
|
|
||||||
|
#+begin_src matlab
|
||||||
|
end
|
||||||
|
#+end_src
|
||||||
|
|
||||||
* Bibliography
|
* Bibliography
|
||||||
:PROPERTIES:
|
:PROPERTIES:
|
||||||
:UNNUMBERED: t
|
:UNNUMBERED: t
|
||||||
|
Loading…
Reference in New Issue
Block a user