Alignment: Difference between revisions

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<li>create straws within the panel
<li> Straws are placed within the panel
* straw direction is +y
* this uses the local panel coordinate system, defined as UVW, a right-handed coordinate system.  These correspond to the XYZ coordinates of the Duke panel X-ray mapper, defined in Mu2e document 5703.
* straws are placed around the +x axis with the longer (innermost) straw near x=0
* The straw direction points along the +U axis, which points from the High Voltage (HV) side of the DRAC electronics board to the Calibration (cal) side.
* the origin is the average position of the two innermost straws
* straw 0 is the longest, innermost straw, straw 95 is the shortest, outermost straw.
* straw z is plus or minus half the layer spacing
* V points radially outwards, from the center of straw 0 to the center of straw 94.
* W is perpendicular to the panel, and to U and V, pointing from the back of the base plate to the cover. This is roughly from the center of straw 1 to the center of straw 0
* panel U=0 is defined by the nominal symmetry axis of the panel
* pane V=0 is defined to be midway between innermost and outermost straw centers, between straws 47 and 48.
* panel W=0 is defined to be midway between the straw layers, which is also midway between the innermost and outermost straw centers
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</li>
<li>Apply the panel alignment of rotations and displacements.  The coordinates are these current local coordinates. For example, to move a panel to a larger radius in the final detector, apply a +x alignment.</li>
<li>Apply the straw alignment.  These are defined in terms of displacements in V and W at either end (HV and Calibration) of the straw, where the straw intersects the manifold (radius=700 mm).  The mylar envelope and wire have separate corrections.
<li>Place the panel in the plane.  This involves rotating the panel to its nominal phi position around the z axis, and adding its nominal displacement of about <code>x += 380*cos(phi)</code> and <code>y += 380*sin(phi)</code> </li>
<li>Apply the panel alignment of rotations and displacements.  These are rigid body rotation and translations WRT the local panel UVW coordinate system.
<li>Apply the plane alignment of rotations and displacements.  The coordinates are the center of the plane. For example, to move a plane vertically up in the final detector, apply a +y alignment.</li>
<li>Place the panel in the nominal plane.  This involves rotating the nominal panel center to its nominal phi position around the z axis, and adding its nominal displacement in Z and radially outwards.  By convention, the nominal plane is defined as plane 0, described in Mu2e document 888.  The nominal plane coordinate system (XYZ) is centered on the plane, with directions as defined by the Mu2e detector coordinate system.
<li>Place the plane within the tracker.  This only involves moving it along the z axis.</li>
<li>Apply the plane alignment of rotations and displacements, with respect to the nominal plane coordinate system.
<li>Place the tracker by applying the tracker alignment.  The coordinates are all the same as the final detector.  To move it closer to the calorimeter, apply a +z alignment. To spin it about its axes apply a z roation.</li>
<li>Place the plane within the nominal tracker.  This involves moving it along the z axis, and rotating half the planes around the Y axis by 180 degrees.  The pattern of plane rotations is defined in Mu2e document 888.  It amounts to building a station by rotating one plane around Y by 180 degrees, then rotating every-other station around Y by 180 degrees.
<li>Place the tracker within the Mu2e detector coordinate system by applying the tracker alignment.  The detector coordinate system is defined as the nominal (perfect) tracker coordinate system.
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Revision as of 17:52, 27 December 2020


Technical Definition

This section explains how the tracker alignment is defined.

  • There are three places that alignment transforms are inserted
    • between the whole tracker and the nominal geometry
    • between each plane and the aligned tracker
    • between each panel and the aligned plane
  • transforms
    • apply rotation before displacement
    • a rotation is defined as right-handed about the local x, then y, then z axes (rad)
    • add an offset in position (mm)
  • tracker geometry object are in coordinate centered at the nominal tracker center

Here is how the geometry is conceptually built up, including the alignment

  1. Straws are placed within the panel
    • this uses the local panel coordinate system, defined as UVW, a right-handed coordinate system. These correspond to the XYZ coordinates of the Duke panel X-ray mapper, defined in Mu2e document 5703.
    • The straw direction points along the +U axis, which points from the High Voltage (HV) side of the DRAC electronics board to the Calibration (cal) side.
    • straw 0 is the longest, innermost straw, straw 95 is the shortest, outermost straw.
    • V points radially outwards, from the center of straw 0 to the center of straw 94.
    • W is perpendicular to the panel, and to U and V, pointing from the back of the base plate to the cover. This is roughly from the center of straw 1 to the center of straw 0
    • panel U=0 is defined by the nominal symmetry axis of the panel
    • pane V=0 is defined to be midway between innermost and outermost straw centers, between straws 47 and 48.
    • panel W=0 is defined to be midway between the straw layers, which is also midway between the innermost and outermost straw centers
  2. Apply the straw alignment. These are defined in terms of displacements in V and W at either end (HV and Calibration) of the straw, where the straw intersects the manifold (radius=700 mm). The mylar envelope and wire have separate corrections.
  3. Apply the panel alignment of rotations and displacements. These are rigid body rotation and translations WRT the local panel UVW coordinate system.
  4. Place the panel in the nominal plane. This involves rotating the nominal panel center to its nominal phi position around the z axis, and adding its nominal displacement in Z and radially outwards. By convention, the nominal plane is defined as plane 0, described in Mu2e document 888. The nominal plane coordinate system (XYZ) is centered on the plane, with directions as defined by the Mu2e detector coordinate system.
  5. Apply the plane alignment of rotations and displacements, with respect to the nominal plane coordinate system.
  6. Place the plane within the nominal tracker. This involves moving it along the z axis, and rotating half the planes around the Y axis by 180 degrees. The pattern of plane rotations is defined in Mu2e document 888. It amounts to building a station by rotating one plane around Y by 180 degrees, then rotating every-other station around Y by 180 degrees.
  7. Place the tracker within the Mu2e detector coordinate system by applying the tracker alignment. The detector coordinate system is defined as the nominal (perfect) tracker coordinate system.