Difference between revisions of "CNF Example Meshes"

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(2D Example Meshes)
(2D Example Meshes)
Line 58: Line 58:
 
'''Note: ''' By using ''min-edge'' less than 1 we are essentially generating triangles with an edge smaller than the input pixels. Using values much smaller than 1 is not expected to help the discretization since we are essentially packing more element into a pixel which has a constant value.
 
'''Note: ''' By using ''min-edge'' less than 1 we are essentially generating triangles with an edge smaller than the input pixels. Using values much smaller than 1 is not expected to help the discretization since we are essentially packing more element into a pixel which has a constant value.
  
== OBS_ALU_Y50 ==
+
== NT_140519 ==
 
* Input distribution size : 10,000 cells
 
* Input distribution size : 10,000 cells
 
* Uniform case: 7,587 triangles
 
* Uniform case: 7,587 triangles
* Adapted  case:  1,018   triangles
+
* Adapted  case:  1,038   triangles
  
The 2D case created by extracting a 2D slice at Y=50 out of the 3D distribution (see 3D case below) OBS_ALU
+
The 2D case created by extracting a 2D slice at X=50 out of the 3D distribution (see 3D case below) NT_140519
  
  
 
<gallery mode="packed" heights=300px>
 
<gallery mode="packed" heights=300px>
File:OBS ALU Y50 me 2 uniform.vtk.png
+
File:NT 140519 X50 me2 uniform.png
File:OBS ALU Y50 me 2 wl 1e-1.png  
+
File:NT 140519 X50 me2 me2 wl 1e-1.png
 
</gallery>
 
</gallery>
  
 
Commands to generate meshes :
 
Commands to generate meshes :
  
'''Uniform :''' [https://odu.box.com/s/irrcuttg0ceogzgnn4x86mgf9eskk1wg Output Mesh]
+
'''Uniform :''' [https://odu.box.com/s/87wruxwbks5k9q5wst9d7rx6z4eycwyz Output Mesh]
 
<pre>
 
<pre>
docker run -v $(pwd):/data/ crtc_i2m tessellate2d  --input ./CNF_Data/2D/OBS_ALU_Y50.vtk --output OBS_ALU_Y50_me_2_uniform.vtk --min-edge=2 --uniform
+
docker run -v $(pwd):/data/ crtc_i2m tessellate2d  --input ./CNF_Data/2D/NT_140519_50_X.vtk --output NT_140519_X50_me_2_uniform.vtk --min-edge=2 --uniform
 
</pre>
 
</pre>
  
'''Adaptive :''' [https://odu.box.com/s/8369kd2q52weqp76811h6p54sax3nj37 Output Mesh]
+
'''Adaptive :''' [https://odu.box.com/s/oytjqxeque11wvbxu62fhwc3830fbpcy Output Mesh]
 
<pre>
 
<pre>
docker run -v $(pwd):/data/ crtc_i2m tessellate2d  --input ./CNF_Data/2D/OBS_ALU_Y50.vtk --output OBS_ALU_Y50_me_2_wl_1e-1.vtk --min-edge=2 --weight-limit=0.1
+
docker run -v $(pwd):/data/ crtc_i2m tessellate2d  --input ./CNF_Data/2D/NT_140519_50_X.vtk --output NT_140519_X50_me_2_wl_1e-1.vtk --min-edge=2 --weight-limit=0.1
 
</pre>
 
</pre>
  
== NT_140519 ==
+
== OBS_ALU_Y50 ==
 
* Input distribution size : 10,000 cells
 
* Input distribution size : 10,000 cells
 
* Uniform case: 7,587 triangles
 
* Uniform case: 7,587 triangles
* Adapted  case:  1,038   triangles
+
* Adapted  case:  1,018   triangles
 
 
The 2D case created by extracting a 2D slice at X=50 out of the 3D distribution (see 3D case below) NT_140519
 
  
 +
The 2D case created by extracting a 2D slice at Y=50 out of the 3D distribution (see 3D case below) OBS_ALU
  
 
<gallery mode="packed" heights=300px>
 
<gallery mode="packed" heights=300px>
File:NT 140519 X50 me2 uniform.png
+
File:OBS ALU Y50 me 2 uniform.vtk.png
File:NT 140519 X50 me2 me2 wl 1e-1.png
+
File:OBS ALU Y50 me 2 wl 1e-1.png  
 
</gallery>
 
</gallery>
  
 
Commands to generate meshes :
 
Commands to generate meshes :
  
'''Uniform :''' [https://odu.box.com/s/87wruxwbks5k9q5wst9d7rx6z4eycwyz Output Mesh]
+
'''Uniform :''' [https://odu.box.com/s/irrcuttg0ceogzgnn4x86mgf9eskk1wg Output Mesh]
 
<pre>
 
<pre>
docker run -v $(pwd):/data/ crtc_i2m tessellate2d  --input ./CNF_Data/2D/NT_140519_50_X.vtk --output NT_140519_X50_me_2_uniform.vtk --min-edge=2 --uniform
+
docker run -v $(pwd):/data/ crtc_i2m tessellate2d  --input ./CNF_Data/2D/OBS_ALU_Y50.vtk --output OBS_ALU_Y50_me_2_uniform.vtk --min-edge=2 --uniform
 
</pre>
 
</pre>
  
'''Adaptive :''' [https://odu.box.com/s/oytjqxeque11wvbxu62fhwc3830fbpcy Output Mesh]
+
'''Adaptive :''' [https://odu.box.com/s/8369kd2q52weqp76811h6p54sax3nj37 Output Mesh]
 
<pre>
 
<pre>
docker run -v $(pwd):/data/ crtc_i2m tessellate2d  --input ./CNF_Data/2D/NT_140519_50_X.vtk --output NT_140519_X50_me_2_wl_1e-1.vtk --min-edge=2 --weight-limit=0.1
+
docker run -v $(pwd):/data/ crtc_i2m tessellate2d  --input ./CNF_Data/2D/OBS_ALU_Y50.vtk --output OBS_ALU_Y50_me_2_wl_1e-1.vtk --min-edge=2 --weight-limit=0.1
 
</pre>
 
</pre>
  

Revision as of 14:46, 25 February 2020

2D Example Meshes

The directory containing the 2D input data is located in the 2D folder of CNF_Data.

Synthetic Gaussian Data

  • Input distribution size : 1,000,000 cells
  • Uniform case: 30,949 triangles
  • Adapted case: 3,788 triangles

Commands to generate meshes :

Uniform : Output Mesh

docker run -v $(pwd):/data/ crtc_i2m tessellate2d  --input ./CNF_Data/2D/Gaussian2.vtk  --output Gaussian_me_10_uniform.vtk --uniform --min-edge=10

Adaptive : Output Mesh

docker run -v $(pwd):/data/ crtc_i2m tessellate2d  --input ./CNF_Data/2D/Gaussian2.vtk  --output Gaussian_me_10_wl_1e-1.vtk --weight-limit=0.05 --min-edge=10

GPDGK16Numerical_140519

The 2D case created by extracting a 2D slice at X=50 out of the 3D distribution (see 3D case below) GPDGK16Numerical_140519

  • Input distribution size : 10,000 cells
  • Uniform case: 7,587 triangles
  • Adapted (min_edge = 2) case: 623 triangles
  • Adapted (min_edge = 0.5) case: 1,409 triangles


Commands to generate meshes :

Uniform : Output Mesh

docker run -v $(pwd):/data/ crtc_i2m tessellate2d  --input ./CNF_Data/2D/GPDGK16Numerical_140519_X50.vtk --output GPDGK16Numerical_140519_me_2_uniform.vtk --min-edge=2 --uniform

Adaptive :(min_edge = 2) Output Mesh

docker run -v $(pwd):/data/ crtc_i2m tessellate2d  --input ./CNF_Data/2D/GPDGK16Numerical_140519_X50.vtk --output GPDGK16Numerical_140519_me_2_wl_1e-1.vtk --min-edge=2 --weight-limit=0.1


Adaptive :(min_edge = 0.5) Output Mesh

docker run -v $(pwd):/data/ crtc_i2m tessellate2d  --input ./CNF_Data/2D/GPDGK16Numerical_140519_X50.vtk --output GPDGK16Numerical_140519_me_0.5_wl_1e-1.vtk --min-edge=0.5 --weight-limit=0.1

Note: By using min-edge less than 1 we are essentially generating triangles with an edge smaller than the input pixels. Using values much smaller than 1 is not expected to help the discretization since we are essentially packing more element into a pixel which has a constant value.

NT_140519

  • Input distribution size : 10,000 cells
  • Uniform case: 7,587 triangles
  • Adapted case: 1,038 triangles

The 2D case created by extracting a 2D slice at X=50 out of the 3D distribution (see 3D case below) NT_140519


Commands to generate meshes :

Uniform : Output Mesh

docker run -v $(pwd):/data/ crtc_i2m tessellate2d  --input ./CNF_Data/2D/NT_140519_50_X.vtk  --output NT_140519_X50_me_2_uniform.vtk --min-edge=2 --uniform

Adaptive : Output Mesh

docker run -v $(pwd):/data/ crtc_i2m tessellate2d  --input ./CNF_Data/2D/NT_140519_50_X.vtk  --output NT_140519_X50_me_2_wl_1e-1.vtk --min-edge=2 --weight-limit=0.1

OBS_ALU_Y50

  • Input distribution size : 10,000 cells
  • Uniform case: 7,587 triangles
  • Adapted case: 1,018 triangles

The 2D case created by extracting a 2D slice at Y=50 out of the 3D distribution (see 3D case below) OBS_ALU

Commands to generate meshes :

Uniform : Output Mesh

docker run -v $(pwd):/data/ crtc_i2m tessellate2d  --input ./CNF_Data/2D/OBS_ALU_Y50.vtk --output OBS_ALU_Y50_me_2_uniform.vtk --min-edge=2 --uniform

Adaptive : Output Mesh

docker run -v $(pwd):/data/ crtc_i2m tessellate2d  --input ./CNF_Data/2D/OBS_ALU_Y50.vtk --output OBS_ALU_Y50_me_2_wl_1e-1.vtk --min-edge=2 --weight-limit=0.1

3D Example Meshes

The directory containing the 3D input data is located in the 3D folder of CNF_Data.

CFF_14052019

GPDGK16Numerical_140519

Input Image

  • Input distribution size : 1,000,000 cells
  • Uniform case: tetrahedra
  • Adapted case: tetrahedra

Commands to generate meshes :

Uniform : [ Output Mesh]


Adaptive : Output Mesh

docker run -v $(pwd):/data/ crtc_i2m podm3d --input ./CNF_Data/3D/CFF_14052019/GPDGK16Numerical_140519.nrrd --delta 5 --cnf --weight-limit 0.1 --min-edge 1 --output ./GPDGK16Numerical_140519,d=5,wl=0.1,me=1.vtk

GPDMMS13_140519

Input Image

  • Input distribution size : 1,000,000 cells
  • Uniform case: tetrahedra
  • Adapted case: tetrahedra

Commands to generate meshes :

Uniform : [ Output Mesh]


Adaptive : Output Mesh

docker run -v $(pwd):/data/ crtc_i2m podm3d --input ./CNF_Data/3D/CFF_14052019/GPDMMS13_140519.nrrd --delta 5 --cnf --weight-limit 0.05 --min-edge 1 --output ./GPDMMS13_140519,d=5,wl=0.05,me=1.vtk

GPDVGG99_140519

Input Image

  • Input distribution size : 1,000,000 cells
  • Uniform case: tetrahedra
  • Adapted case: tetrahedra

Commands to generate meshes :

Uniform : [ Output Mesh]


Adaptive : Output Mesh

docker run -v $(pwd):/data/ crtc_i2m podm3d --input ./CNF_Data/3D/CFF_14052019/GPDVGG99_140519.nrrd --delta 5 --cnf --weight-limit 0.05 --min-edge 1 --output ./GPDVGG99_140519,d=5,wl=0.05,me=1.vtk

NT_140519

Input Image

  • Input distribution size : 1,000,000 cells
  • Uniform case: tetrahedra
  • Adapted case: tetrahedra

Commands to generate meshes :

Uniform : [ Output Mesh]


Adaptive : Output Mesh

docker run -v $(pwd):/data/ crtc_i2m podm3d --input ./CNF_Data/3D/CFF_14052019/NT_140519.nrrd --delta 5 --cnf --weight-limit 0.07 --min-edge 1 --output ./NT_140519,d=5,wl=0.07,me=1.vtk

OBS_ALU_140519

Input Image

  • Input distribution size : 1,000,000 cells
  • Uniform case: tetrahedra
  • Adapted case: tetrahedra

Commands to generate meshes :

Uniform : [ Output Mesh]


Adaptive : Output Mesh

docker run -v $(pwd):/data/ crtc_i2m podm3d --input ./CNF_Data/3D/CFF_14052019/OBS_ALU_140519.nrrd --delta 5 --cnf --weight-limit 0.13 --min-edge 1 --output ./OBS_ALU_140519,d=5,wl=0.13,me=1.vtk

OBS_CS_140519

Input Image

  • Input distribution size : 1,000,000 cells
  • Uniform case: tetrahedra
  • Adapted case: tetrahedra

Commands to generate meshes :

Uniform : [ Output Mesh]


Adaptive : Output Mesh

docker run -v $(pwd):/data/ crtc_i2m podm3d --input ./CNF_Data/3D/CFF_14052019/OBS_CS_140519.nrrd --delta 5 --cnf --weight-limit 0.01 --min-edge 1 --output ./OBS_CS_140519,d=5,wl=0.01,me=1.vtk

CFF_DATA

cff_E.data_IM

Input Image

  • Input distribution size : 8,000,000 cells
  • Uniform case: tetrahedra
  • Adapted case: tetrahedra

Commands to generate meshes :

Uniform : [ Output Mesh]


Adaptive : Output Mesh

docker run -v $(pwd):/data/ crtc_i2m podm3d --input ./CNF_Data/3D/CFF_DATA/cff_E.data_IM.nrrd --delta 5 --cnf --weight-limit 0.01 --min-edge 1 --output ./cff_E.data_IM,d=10,wl=0.01,me=1.vtk

cff_E.data_REAL

Input Image

  • Input distribution size : 8,000,000 cells
  • Uniform case: tetrahedra
  • Adapted case: tetrahedra

Commands to generate meshes :

Uniform : [ Output Mesh]


Adaptive : Output Mesh

docker run -v $(pwd):/data/ crtc_i2m podm3d --input ./CNF_Data/3D/CFF_DATA/cff_E.data_REAL.nrrd --delta 10 --cnf --weight-limit 0.1 --min-edge 1 --output ./cff_E.data_REAL,d=10,wl=0.1,me=1.vtk

cff_H.data_IM

Input Image

  • Input distribution size : 8,000,000 cells
  • Uniform case: tetrahedra
  • Adapted case: tetrahedra

Commands to generate meshes :

Uniform : [ Output Mesh]


Adaptive : Output Mesh

docker run -v $(pwd):/data/ crtc_i2m podm3d --input ./CNF_Data/3D/CFF_DATA/cff_H.data_IM.nrrd --delta 10 --cnf --weight-limit 0.05 --min-edge 1 --output ./cff_H.data_IM,d=10,wl=0.05,me=1.vtk

cff_H.data_REAL

Input Image

  • Input distribution size : 8,000,000 cells
  • Uniform case: tetrahedra
  • Adapted case: tetrahedra

Commands to generate meshes :

Uniform : [ Output Mesh]


Adaptive : Output Mesh

docker run -v $(pwd):/data/ crtc_i2m podm3d --input ./CNF_Data/3D/CFF_DATA/cff_H.data_REAL.nrrd --delta 10 --cnf --weight-limit 0.1 --min-edge 1 --output ./cff_H.data_REAL,d=10,wl=0.1,me=1.vtk

cff_Ht.data_IM

Input Image

  • Input distribution size : 8,000,000 cells
  • Uniform case: tetrahedra
  • Adapted case: tetrahedra

Commands to generate meshes :

Uniform : [ Output Mesh]


Adaptive : Output Mesh

docker run -v $(pwd):/data/ crtc_i2m podm3d --input ./CNF_Data/3D/CFF_DATA/cff_Ht.data_IM.nrrd --delta 10 --cnf --weight-limit 0.1 --min-edge 1 --output ./cff_Ht.data_IM,d=10,wl=0.1,me=1.vtk

cff_Ht.data_REAL

Input Image

  • Input distribution size : 8,000,000 cells
  • Uniform case: tetrahedra
  • Adapted case: tetrahedra

Commands to generate meshes :

Uniform : [ Output Mesh]


Adaptive : Output Mesh

docker run -v $(pwd):/data/ crtc_i2m podm3d --input ./CNF_Data/3D/CFF_DATA/cff_Ht.data_REAL.nrrd --delta 10 --cnf --weight-limit 0.1 --min-edge 1 --output ./cff_Ht.data_REAL,d=10,wl=0.1,me=1.vtk

DATA_04252019

CFF_E_im

Input Image

  • Input distribution size : 1,000,000 cells
  • Uniform case: tetrahedra
  • Adapted case: tetrahedra

Commands to generate meshes :

Uniform : [ Output Mesh]


Adaptive : Output Mesh

docker run -v $(pwd):/data/ crtc_i2m podm3d --input ./CNF_Data/3D/DATA_04252019/CFF_E_im.nrrd --delta 5 --cnf --weight-limit 0.04 --min-edge 1 --output ./CFF_E_im,d=5,wl=0.04,me=1.vtk

CFF_E_re

Input Image

  • Input distribution size : 1,000,000 cells
  • Uniform case: tetrahedra
  • Adapted case: tetrahedra

Commands to generate meshes :

Uniform : [ Output Mesh]


Adaptive : Output Mesh

docker run -v $(pwd):/data/ crtc_i2m podm3d --input ./CNF_Data/3D/DATA_04252019/CFF_E_re.nrrd --delta 5 --cnf --weight-limit 0.08 --min-edge 1 --output ./CFF_E_re,d=5,wl=0.08,me=1.vtk

CFF_H_im

Input Image

  • Input distribution size : 1,000,000 cells
  • Uniform case: tetrahedra
  • Adapted case: tetrahedra

Commands to generate meshes :

Uniform : [ Output Mesh]


Adaptive : Output Mesh

docker run -v $(pwd):/data/ crtc_i2m podm3d --input ./CNF_Data/3D/DATA_04252019/CFF_H_im.nrrd --delta 5 --cnf --weight-limit 0.06 --min-edge 1 --output ./CFF_H_im,d=5,wl=0.06,me=1.vtk

CFF_H_re

Input Image

  • Input distribution size : 1,000,000 cells
  • Uniform case: tetrahedra
  • Adapted case: tetrahedra

Commands to generate meshes :

Uniform : [ Output Mesh]


Adaptive : Output Mesh

docker run -v $(pwd):/data/ crtc_i2m podm3d --input ./CNF_Data/3D/DATA_04252019/CFF_H_re.nrrd --delta 5 --cnf --weight-limit 0.13 --min-edge 1 --output ./CFF_H_re,d=5,wl=0.13,me=1.vtk

GPD_H_down

Input Image

  • Input distribution size : 1,000,000 cells
  • Uniform case: tetrahedra
  • Adapted case: tetrahedra

Commands to generate meshes :

Uniform : [ Output Mesh]


Adaptive : Output Mesh

docker run -v $(pwd):/data/ crtc_i2m podm3d --input ./CNF_Data/3D/DATA_04252019/GPD_H_down.nrrd --delta 5 --cnf --weight-limit 0.1 --min-edge 1 --output ./GPD_H_down,d=5,wl=0.1,me=1.vtk

GPD_H_up

Input Image

  • Input distribution size : 1,000,000 cells
  • Uniform case: tetrahedra
  • Adapted case: tetrahedra

Commands to generate meshes :

Uniform : [ Output Mesh]


Adaptive :Output Mesh

docker run -v $(pwd):/data/ crtc_i2m podm3d --input ./CNF_Data/3D/DATA_04252019/GPD_H_up.nrrd --delta 5 --cnf --weight-limit 0.1 --min-edge 1 --output ./GPD_H_up,d=5,wl=0.1,me=1.vtk

OBS_ALU

Input Image

  • Input distribution size : 1,000,000 cells
  • Uniform case: tetrahedra
  • Adapted case: tetrahedra

Commands to generate meshes :

Uniform : Output Mesh

docker run -v $(pwd):/data/ crtc_i2m podm3d --input ./CNF_Data/3D/DATA_04252019/OBS_ALU.nrrd --delta 2 --image-segmentation --background-value 0 --linear-interpolation --output ./OBS_ALU,d=5,bg=0,uniform.vtk

Adaptive : Output Mesh

docker run -v $(pwd):/data/ crtc_i2m podm3d --input ./CNF_Data/3D/DATA_04252019/OBS_ALU.nrrd --delta 5 --cnf --background-value 0 --weight-limit 0.07 --min-edge 1 --output ./OBS_ALU,d=5,bg=0,wl=0.07,me=1.vtk

phase_space_000

phase_space_000

Input Image

  • Input distribution size : 1,000,000 cells
  • Uniform case: tetrahedra
  • Adapted case: tetrahedra

Commands to generate meshes :

Uniform : [ Output Mesh]


Adaptive : Output Mesh

docker run -v $(pwd):/data/ crtc_i2m podm3d --input ./CNF_Data/3D/phase_space_000/phase_space_000.nrrd --delta 1.5 --cnf --weight-limit 0.005 --min-edge 1 --output ./phase_space_000,d=1.5,wl=0.005,me=1.vtk