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			 Track3P

ACE3P Codes Source Date:   Mon Mar 6 23:26:49 2023 -0800
ACE3P Codes Source Branch: master
ACE3P Codes Source Tag:    503652f41066a31de4a9b7088dd1fd7572ada43a
Support Lib Source Date:   Fri Dec 2 09:43:53 2022 -0800
Support Lib Source Branch: master
Support Lib Source Tag:    2f7bd8bf8ec6eb3646dc05e32622a4475531a105
Compilation Date:          Wed 15 Mar 2023 02:18:40 PM PDT

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         Copyright 2023, Stanford University 

Authors make no representations or warranties, expressed or 
implied. By way of example, but not limitation, authors make 
no representatinos or warranties of merchantibility or 
fitness for any particular purpose or that the use of the 
software componentns of documentation will not infringe any
patents, copyrights, trademarks or other rights.

The Authors shall not be held liable for any liability 
nor for any direct, indirect or consequential damages with 
respect to any claim by users or any third party on account 
of or arising from the use of this software.

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Advanced Computations Department
SLAC National Accelerator Laboratory
https://slacportal.slac.stanford.edu/sites/ard_public/acd/Pages/Default.aspx
Contact: ace3p@slac.stanford.edu

Thank you for citing ACE3P when publishing related results.

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Starting master process on nid004883
Number of MPI processes: 16
Number of compute nodes: 1
Number of processes per node: 16
Data precision: 64 bits
Compiler: 11.2.0 20210728 (Cray Inc.)
 no enhancement counter postprocess
Boundary conditions:
0 = INTERIOR
3 = EXTERIOR
4 = EXTERIOR
6 = EXTERIOR
7 = WAVEGUIDE
8 = WAVEGUIDE

Boundary 6 has surface conductivity of 5.800000000000e+07 S/m
Boundary 3 has surface conductivity of 2.500000000000e+07 S/m
Boundary 4 has surface conductivity of 2.500000000000e+07 S/m
Surface impedance model 
Metal properties: 
  Epsilon = 1.000000000000e+00
  MU = 1.000000000000e+00
  Sigma = 5.800000000000e+07
  Frequency = 1.000000000000e+09

Surface impedance model 
Metal properties: 
  Epsilon = 1.000000000000e+00
  MU = 1.000000000000e+00
  Sigma = 2.500000000000e+07
  Frequency = 1.000000000000e+09

Surface impedance model 
Metal properties: 
  Epsilon = 1.000000000000e+00
  MU = 1.000000000000e+00
  Sigma = 2.500000000000e+07
  Frequency = 1.000000000000e+09

Read Mesh: /pscratch/sd/l/lge/cw23/examples/track3p/Muon201MHz/Muon.ncdf
Time for reading the model: 3.080424290001e-01

Using curved quadratic tetrahedrons
Setting global vector finite element basis order to p=2
Partitioning Method: parmetis

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*	Total Number of Elements read: 	207642
*	Total Number of Elements used: 	207642
*	Total Number of DOFs: 	1247482
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Time for setting up finite element framework: 3.393938880000e+00
/********************************/
/* input parameters, KVC syntax */
/********************************/


        Mesh : { 
            ElementDistribution : { 
                average : 207642.0 
                min : 207642 
                total : 207642 
                stddev : 0.0 
                max : 207642 
            }
            File : /pscratch/sd/l/lge/cw23/examples/track3p/Muon201MHz/Muon.ncdf 
            ReplicatedElementDistribution : { 
                average : 0.0 
                min : 0 
                total : 0 
                stddev : 0.0 
                max : 0 
            }
            MeshCoords : 41889 
        }
/********************************/




number of all emitting faces = 990
scale 4.084307285507e+05 Field 1.000000000000e+06
Geometry Model: Using full (4/4) 3D symmetry
scale 8.168614571014e+05 Field 2.000000000000e+06
Geometry Model: Using full (4/4) 3D symmetry
scale 1.225292185652e+06 Field 3.000000000000e+06
Geometry Model: Using full (4/4) 3D symmetry
scale 1.633722914203e+06 Field 4.000000000000e+06
Geometry Model: Using full (4/4) 3D symmetry
scale 2.042153642753e+06 Field 5.000000000000e+06
Geometry Model: Using full (4/4) 3D symmetry
scale 2.450584371304e+06 Field 6.000000000000e+06
Geometry Model: Using full (4/4) 3D symmetry
scale 2.859015099855e+06 Field 7.000000000000e+06
Geometry Model: Using full (4/4) 3D symmetry
scale 3.267445828405e+06 Field 8.000000000000e+06
Geometry Model: Using full (4/4) 3D symmetry
scale 3.675876556956e+06 Field 9.000000000000e+06
Geometry Model: Using full (4/4) 3D symmetry
scale 4.084307285507e+06 Field 1.000000000000e+07
Geometry Model: Using full (4/4) 3D symmetry
scale 4.492738014057e+06 Field 1.100000000000e+07
Geometry Model: Using full (4/4) 3D symmetry
scale 4.901168742608e+06 Field 1.200000000000e+07
Geometry Model: Using full (4/4) 3D symmetry
scale 5.309599471159e+06 Field 1.300000000000e+07
Geometry Model: Using full (4/4) 3D symmetry
scale 5.718030199709e+06 Field 1.400000000000e+07
Geometry Model: Using full (4/4) 3D symmetry
scale 6.126460928260e+06 Field 1.500000000000e+07
Geometry Model: Using full (4/4) 3D symmetry
scale 6.534891656811e+06 Field 1.600000000000e+07
Geometry Model: Using full (4/4) 3D symmetry
Done!