[1208] | 1 | <html> |
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| 2 | <head> |
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| 3 | <title>ADG: Geometry</title> |
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| 4 | </head> |
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| 5 | |
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| 6 | <!-- Changed by: Gabriele Cosmo, 18-Apr-2005 --> |
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| 7 | <!-- $Id: geomLogical.html,v 1.3 2006/06/09 13:59:15 gcosmo Exp $ --> |
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| 8 | <!-- $Name: $ --> |
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| 9 | <body> |
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| 10 | <table WIDTH="100%"><TR> |
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| 11 | <td> |
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| 12 | <a href="../../../../Overview/html/index.html"> |
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| 13 | <IMG SRC="../../../../resources/html/IconsGIF/Overview.gif" ALT="Overview"></a> |
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| 14 | <a href="geometry.html"> |
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| 15 | <IMG SRC="../../../../resources/html/IconsGIF/Contents.gif" ALT="Contents"></a> |
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| 16 | <a href="geomSolids.html"> |
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| 17 | <IMG SRC="../../../../resources/html/IconsGIF/Previous.gif" ALT="Previous"></a> |
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| 18 | <a href="geomPhysical.html"> |
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| 20 | </td> |
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| 21 | <td ALIGN="Right"> |
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| 22 | <font SIZE="-1" COLOR="#238E23"> |
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| 23 | <b>Geant4 User's Guide</b> |
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| 24 | <br> |
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| 25 | <b>For Application Developers</b> |
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| 26 | <br> |
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| 27 | <b>Geometry</b> |
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| 28 | </font> |
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| 29 | </td> |
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| 30 | </tr></table> |
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| 31 | <br><br> |
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| 32 | |
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| 33 | <a name="4.1.3"> |
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| 34 | <h2>4.1.3 Logical Volumes</h2></a> |
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| 35 | |
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| 36 | <p> |
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| 37 | The Logical Volume manages the information associated with detector elements |
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| 38 | represented by a given Solid and Material, independently from its physical |
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| 39 | position in the detector. |
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| 40 | </p> |
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| 41 | <p> |
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| 42 | A Logical Volume knows which physical volumes are contained within it. It is |
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| 43 | uniquely defined to be their mother volume. A Logical Volume thus represents |
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| 44 | a hierarchy of unpositioned volumes whose positions relative to one another |
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| 45 | are well defined. By creating Physical Volumes, which are placed instances of |
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| 46 | a Logical Volume, this hierarchy or tree can be repeated. |
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| 47 | </p> |
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| 48 | <p> |
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| 49 | A Logical Volume also manages the information relative to the Visualization |
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| 50 | attributes (<a href="../Visualization/attributes.html">Section 8.6</a>) and |
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| 51 | user-defined parameters related to tracking, electro-magnetic field or cuts |
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| 52 | (through the <tt>G4UserLimits</tt> interface). |
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| 53 | </p> |
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| 54 | <p> |
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| 55 | By default, tracking optimization of the geometry (voxelization) is applied |
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| 56 | to the volume hierarchy identified by a logical volume. It is possible to |
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| 57 | change the default behavior by choosing not to apply geometry optimization |
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| 58 | for a given logical volume. This feature does not apply to the case where the |
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| 59 | associated physical volume is a parameterised volume; in this case, |
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| 60 | optimization is always applied. |
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| 61 | |
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| 62 | <pre> |
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| 63 | G4LogicalVolume( G4VSolid* pSolid, |
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| 64 | G4Material* pMaterial, |
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| 65 | const G4String& Name, |
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| 66 | G4FieldManager* pFieldMgr=0, |
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| 67 | G4VSensitiveDetector* pSDetector=0, |
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| 68 | G4UserLimits* pULimits=0, |
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| 69 | G4bool Optimise=true ) |
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| 70 | </pre> |
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| 71 | </p> |
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| 72 | <P> |
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| 73 | The logical volume provides a way to estimate the <I>mass</I> of a tree of |
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| 74 | volumes defining a detector or sub-detector. This can be achieved by calling |
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| 75 | the method: |
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| 76 | <PRE> |
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| 77 | G4double GetMass(G4bool forced=false) |
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| 78 | </PRE> |
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| 79 | The mass of the logical volume tree is computed from the estimated geometrical |
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| 80 | volume of each solid and material associated with the logical volume and its |
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| 81 | daughters. Note that this computation may require a considerable amount of |
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| 82 | time, depending on the complexity of the geometry tree. |
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| 83 | The returned value is cached by default and can be used for successive calls, |
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| 84 | unless recomputation is forced by providing <TT>true</TT> for the boolean |
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| 85 | argument <TT>forced</TT> in input. Computation should be forced if the |
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| 86 | geometry setup has changed after the previous call.</P> |
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| 87 | <P> |
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| 88 | Finally, the Logical Volume manages the information relative to the Envelopes |
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| 89 | hierarchy required for fast Monte Carlo parameterisations |
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| 90 | (<a href="../TrackingAndPhysics/physicsProcess.html#5.2.6">Section 5.2.6</a>).</P> |
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| 91 | |
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| 92 | <P> </P> |
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| 93 | |
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| 94 | <a name="4.1.3.1"> |
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| 95 | <H4>4.1.3.1 Sub-detector Regions</H4></a> |
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| 96 | |
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| 97 | In complex geometry setups, such as those found in large detectors in |
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| 98 | particle physics experiments, it is useful to think of specific Logical |
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| 99 | Volumes as representing parts (sub-detectors) of the entire detector setup |
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| 100 | which perform specific functions. In such setups, the processing speed of |
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| 101 | a real simulation can be increased by assigning specific production |
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| 102 | <i>cuts</i> to each of these detector parts. This allows a more detailed |
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| 103 | simulation to occur only in those regions where it is required. |
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| 104 | <P> |
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| 105 | The concept of detector <i>Region</i> was introduced to address this need. |
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| 106 | Once the final geometry setup of the detector has been defined, a region |
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| 107 | can be specified by constructing it with: |
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| 108 | <PRE> |
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| 109 | G4Region( const G4String& rName ) |
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| 110 | </PRE></P> |
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| 111 | <P> |
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| 112 | where:</P> |
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| 113 | <P> |
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| 114 | <table border=1 cellpadding=8> |
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| 115 | <td><tt>rName</tt> <td>String identifier for the detector region |
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| 116 | </table></P> |
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| 117 | <P> |
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| 118 | A <tt>G4Region</tt> must then be assigned to a logical volume, in order to |
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| 119 | make it a <i>Root Logical Volume</i>: |
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| 120 | <PRE> |
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| 121 | G4Region* emCalorimeter = new G4Region("EM-Calorimeter"); |
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| 122 | emCalorimeter->AddRootLogicalVolume(emCalorimeter); |
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| 123 | </PRE> |
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| 124 | A root logical volume is the first volume at the top of the hierarchy to |
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| 125 | which a given region is assigned. Once the region is assigned to the root |
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| 126 | logical volume, the information is automatically propagated to the volume |
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| 127 | tree, so that each daughter volume shares the same region. Propagation on |
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| 128 | a tree branch will be interrupted if an already existing root logical |
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| 129 | volume is encountered.</P> |
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| 130 | <P> |
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| 131 | A specific <i>Production Cut</i> can be assigned to the region, by defining |
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| 132 | and assigning to it a <tt>G4ProductionCut</tt> object |
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| 133 | <PRE> |
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| 134 | emCalorimeter->SetProductionCuts(emCalCuts); |
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| 135 | </PRE> |
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| 136 | <a href="../TrackingAndPhysics/thresholdVScut.html#5.4.2">Section 5.4.2</a> |
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| 137 | describes how to define a production cut. The same region can be assigned |
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| 138 | to more than one root logical volume, and root logical volumes can be |
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| 139 | removed from an existing region. A logical volume can have only <i>one</i> |
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| 140 | region assigned to it. Regions will be automatically registered in a store |
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| 141 | which will take care of destroying them at the end of the job. A default |
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| 142 | region with a default production cut is automatically created and assigned |
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| 143 | to the world volume.</P> |
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| 144 | |
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| 145 | <hr><a href="../../../../Authors/html/subjectsToAuthors.html"> |
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| 146 | <i>About the authors</a></i> </P> |
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| 147 | |
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| 148 | </body> |
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| 149 | </html> |
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