In this example we show how someone can simulate the signal and the ODF of a single voxel using a MultiTensor.

```
import numpy as np
from dipy.sims.voxel import multi_tensor, multi_tensor_odf
from dipy.data import get_sphere
```

For the simulation we will need a GradientTable with the b-values and b-vectors Here we use the one we created in Gradients and Spheres.

```
from gradients_spheres import gtab
```

In `mevals`

we save the eigenvalues of each tensor.

```
mevals = np.array([[0.0015, 0.0003, 0.0003],
[0.0015, 0.0003, 0.0003]])
```

In `angles`

we save in polar coordinates (\(\theta, \phi\)) the principal
axis of each tensor.

```
angles = [(0, 0), (60, 0)]
```

In `fractions`

we save the percentage of the contribution of each tensor.

```
fractions = [50, 50]
```

The function `multi_tensor`

will return the simulated signal and an array
with the principal axes of the tensors in cartesian coordinates.

```
signal, sticks = multi_tensor(gtab, mevals, S0=100, angles=angles,
fractions=fractions, snr=None)
```

We can also add Rician noise with a specific SNR.

```
signal_noisy, sticks = multi_tensor(gtab, mevals, S0=100, angles=angles,
fractions=fractions, snr=20)
import matplotlib.pyplot as plt
plt.plot(signal, label='noiseless')
plt.plot(signal_noisy, label='with noise')
plt.legend()
#plt.show()
plt.savefig('simulated_signal.png')
```

For the ODF simulation we will need a sphere. Because we are interested in a simulation of only a single voxel, we can use a sphere with very high resolution. We generate that by subdividing the triangles of one of DIPY’s cached spheres, which we can read in the following way.

```
sphere = get_sphere('repulsion724')
sphere = sphere.subdivide(2)
odf = multi_tensor_odf(sphere.vertices, mevals, angles, fractions)
from dipy.viz import window, actor
# Enables/disables interactive visualization
interactive = False
scene = window.Scene()
odf_actor = actor.odf_slicer(odf[None, None, None, :], sphere=sphere, colormap='plasma')
odf_actor.RotateX(90)
scene.add(odf_actor)
print('Saving illustration as multi_tensor_simulation')
window.record(scene, out_path='multi_tensor_simulation.png', size=(300, 300))
if interactive:
window.show(scene)
```

Example source code

You can download `the full source code of this example`

. This same script is also included in the dipy source distribution under the `doc/examples/`

directory.