|
Size: 3533
Comment:
|
Size: 3637
Comment:
|
| Deletions are marked like this. | Additions are marked like this. |
| Line 23: | Line 23: |
| Now, we have all the componenet of the model, we can start the process to compute the head model. For the EEG, brainstorm offers three methods. We perform these three computations on this model. | Now, we have all the components of the model, we can start the process to compute the head model. For the EEG, brainstorm offers three methods. We perform these three computations on this model. |
| Line 27: | Line 27: |
| 1. 3-shell sphere : best fitting sphere based pn scalp, then OK, less 1. OpenMeeg BEM : use the conductivity 0.33, 0.004 and 0.33, and keep the default options. 1. DUNEuro FEM : use the default option with the same conductivity value as the previous method. |
1. 3-shell sphere: best-fitting sphere based on the scalp, then OK. 1. OpenMeeg BEM: use the conductivity 0.33, 0.004 and 0.33, and keep the default options. 1. DUNEuro FEM: use the default option with the same conductivity value as the previous method. |
| Line 31: | Line 31: |
| === Quantitave comparaison of the methods === In this tutorial we use the display of the leadfield vector to compare visually the performances of the the three methods. |
=== Quantitative comparison of the methods === In this tutorial, we use the display of the lead field vector to compare visually the performances of the three methods. |
| Line 34: | Line 34: |
| Right-click on the head model, and then select 'View lead field vector'. You can select more than the head model in order to overlay the vectors. | |
| Line 35: | Line 36: |
| In this figure, we show the 3-Shell vs OpenMeeg and 3-Shell vs Duneuro and all of these methods. | |
| Line 36: | Line 38: |
| Right click on the headmodel, and then select 'View leadfield vector'. You can select more than headmodel in order to overlay the vectors. In this figure we show the 3-Shell vs OpenMeeg and 3-Shell vs Duneuro and all of these method. |
{{attachment:ViewLeadFieldEEGAllMethod.JPG||height="300",width="350"}} {{attachment:leadVectorZoom.JPG||height="300",width="350"}} |
| Line 72: | Line 53: |
| difference appears on v10 | the difference appears on v10 |
| Line 76: | Line 57: |
| in spherical head model | in the spherical head model |
| Line 80: | Line 61: |
| difference appears on the v1 and worse for v10 | the difference appears on the v1 and worse for v10 |
| Line 82: | Line 63: |
| == EEG forward within 3 layers head model : == In this example we compute the head model for the ICBM head model using the openmeeg method and then we generate the fem mesh for the same subject, then we compute the the leadfield using the Duneuro method v = 0.1 default value. MNorm {{attachment:sourcelocalisation.JPG||height="400",width="700"}} |
== EEG forward within 3 layers head model: == In this example, we compute the head model for the ICBM head model using the openmeeg method and then we generate the fem mesh for the same subject, then we compute the lead field using the Duneuro method v = 0.1 default value. MNorm {{attachment:sourcelocalisation.JPG||height="400",width="700"}} |
Introduction
In this tutorial, we compare the head models computation using the methods available in brainstorm.
At this time, the FEM implementation is available for the EEG and the MEG computation. We will integrate and test soon the FEM for sEEG and ECOG.
EEG within a spherical model
The volume conductor or the head model:
In this part we used the spherical head model distributed by the duneuro team (sphere). The following figure shows on the left the surface model and on right the tetrahedral mesh. 
The model has three layers, the brain (inner skull), the outer skull and the scalp.
The source space :
For the source space or dipole position, we will use a realistic cortex distributed with the ICBM default subject of brainstorm.
The sensor model
Regarding the electrode's positions, we use the same position defined in this file. The total number of electrodes is 200 regularly distributed on the outer layer.
The forward model
Now, we have all the components of the model, we can start the process to compute the head model. For the EEG, brainstorm offers three methods. We perform these three computations on this model.
Cond: 0.330 0.004 0.330
- 3-shell sphere: best-fitting sphere based on the scalp, then OK.
OpenMeeg BEM: use the conductivity 0.33, 0.004 and 0.33, and keep the default options.
- DUNEuro FEM: use the default option with the same conductivity value as the previous method.
Quantitative comparison of the methods
In this tutorial, we use the display of the lead field vector to compare visually the performances of the three methods.
Right-click on the head model, and then select 'View lead field vector'. You can select more than the head model in order to overlay the vectors.
In this figure, we show the 3-Shell vs OpenMeeg and 3-Shell vs Duneuro and all of these methods.
the BEM, FEM forward computation in basic model (realistic head model 3 layer) and also within in a spherical head model with an analytical solution.
Describe femVSbem here.
Compare the performance of the mesh resolution vs the lead field approximation
v10, v1, v0.1 and v0.01 
v0.1 and V0.01 are almost the same ....
the difference appears on v10
in the spherical head model
same observation on the lf view 
the difference appears on the v1 and worse for v10
EEG forward within 3 layers head model:
In this example, we compute the head model for the ICBM head model using the openmeeg method and then we generate the fem mesh for the same subject, then we compute the lead field using the Duneuro method v = 0.1 default value. MNorm 
sloreta 
