| | """ |
| | ======================== |
| | 3D plot projection types |
| | ======================== |
| | |
| | Demonstrates the different camera projections for 3D plots, and the effects of |
| | changing the focal length for a perspective projection. Note that Matplotlib |
| | corrects for the 'zoom' effect of changing the focal length. |
| | |
| | The default focal length of 1 corresponds to a Field of View (FOV) of 90 deg. |
| | An increased focal length between 1 and infinity "flattens" the image, while a |
| | decreased focal length between 1 and 0 exaggerates the perspective and gives |
| | the image more apparent depth. In the limiting case, a focal length of |
| | infinity corresponds to an orthographic projection after correction of the |
| | zoom effect. |
| | |
| | You can calculate focal length from a FOV via the equation: |
| | |
| | .. math:: |
| | |
| | 1 / \\tan (\\mathrm{FOV} / 2) |
| | |
| | Or vice versa: |
| | |
| | .. math:: |
| | |
| | \\mathrm{FOV} = 2 \\arctan (1 / \\mathrm{focal length}) |
| | |
| | """ |
| |
|
| | import matplotlib.pyplot as plt |
| |
|
| | from mpl_toolkits.mplot3d import axes3d |
| |
|
| | fig, axs = plt.subplots(1, 3, subplot_kw={'projection': '3d'}) |
| |
|
| | |
| | X, Y, Z = axes3d.get_test_data(0.05) |
| |
|
| | |
| | for ax in axs: |
| | ax.plot_wireframe(X, Y, Z, rstride=10, cstride=10) |
| |
|
| | |
| | axs[0].set_proj_type('ortho') |
| | axs[0].set_title("'ortho'\nfocal_length = ∞", fontsize=10) |
| |
|
| | |
| | axs[1].set_proj_type('persp') |
| | axs[1].set_title("'persp'\nfocal_length = 1 (default)", fontsize=10) |
| |
|
| | axs[2].set_proj_type('persp', focal_length=0.2) |
| | axs[2].set_title("'persp'\nfocal_length = 0.2", fontsize=10) |
| |
|
| | plt.show() |
| |
|
