File:Gaussian 2d surface.png

Summary

Description
English: Created in Python with Numpy and Matplotlib.
Date
Source Own work
Author Kopak999
PNG development
InfoField
Source code
InfoField

Python code

import numpy as np
import matplotlib as mpl
import matplotlib.pyplot as plt
from matplotlib import cm

exp = np.exp

def Gaussian2D(X, Y, a=1,):
    """
    This function takes meshgrids of X- and Y-values and outputs an array of 
    Z-values in the shape of the Gaussian distribution:
    
    exp(-a(X^2 + Y^2)).
    """
    
    return exp(-a*(X**2 + Y**2))


def plotGaussianSurface(
    X, Y, Z,
    colormap=cm.cividis,  
    title="", 
    filetype="png", 
    saveflag=False, 
    resolution=200, 
    dpi=300,
    numticks_xy=7,
    numticks_z=2,
    numticks_xy_minor=25,
    numticks_z_minor=5,
):
    """
    Plots a 3D-surface of a 2D-Gaussian function.
    
    X, Y: Meshgrids of x- and y-values for the Gaussian.
    
    Z: The output of the Gaussian function.
    
    colormap: The colormap for the surface, mapped to the Z-values of the 
        graph.
    
    title: Title of the graph.
    
    filetype: Three-letter extension of the image filetype for saving the 
        graph. Default is png.
    
    saveflag: Boolean flag to check if the graph should be saved to a file.
        Set to True if you want to save the graph to a file. Default is False.
    
    resolution: Number of pixels to render along the x- and y-axes.
        Default is 200, which gives a 200x200 grid.
    
    dpi: Dots-per-inch of the image. Default is 300.
    """
    
    plt.ioff()
    
    # Set up kwargs:
    limit = int(np.ceil(np.amax(X)))
    zmin = int(np.floor(np.amin(Z)))
    zmax = int(np.ceil(np.amax(Z)))
    norm = mpl.colors.Normalize(vmin=zmin, vmax=zmax)
    aspect = (limit*2 + 1, limit*2 + 1, zmax)
    
    xy_major_params = dict(
        direction = "in",
    )
    xy_minor_params = dict(
        direction = "in",
        which = "minor",
    )
    xy_major_ticks = dict(
        ticks = np.linspace(-limit, limit, numticks_xy, endpoint=True,),
    )
    xy_minor_ticks = dict(
        ticks = np.linspace(-limit, limit, numticks_xy_minor, endpoint=True,), 
        minor = True,
    )
    z_major_params = dict(
        which = "major", 
        labelbottom = True, 
        labeltop = False,
    )
    z_minor_params = dict(
        which = "minor",
    )
    z_major_ticks = dict(
        ticks = np.linspace(0, zmax, numticks_z, endpoint=True,),
    )
    z_minor_ticks = dict(
        ticks = np.linspace(0, zmax, numticks_z_minor, endpoint=True,), 
        minor = True,
    )
    
    tick_labelsize = 7
    
    
    fig = plt.figure(dpi=dpi)
    ax = fig.add_subplot(1, 1, 1, projection ='3d')
    
    # Plot the surface
    surf = ax.plot_surface(
        X, Y, Z, 
        cmap = colormap, 
        linewidth=0, 
        antialiased=False, 
        vmin = zmin, vmax = zmax, 
        rcount = resolution, 
        ccount = resolution,
        norm = norm,
    )
    
    # Customize the z axis.
    ax.set_zlim(zmin, zmax)
    # ax.zaxis.set_major_locator(LinearLocator(10))
    ax.zaxis.set_major_formatter('{x:.1f}')
    
    
    ax.set_title(
        title, 
        fontdict = dict(verticalalignment = "bottom"),
    )
    
    ax.set_box_aspect(aspect)
    # ax.proj_type("ortho")
    ax.set_facecolor('none')
    
    # Set tick parameters
    ax.xaxis.set_tick_params(**xy_major_params)
    ax.xaxis.set_tick_params(**xy_minor_params)
    ax.yaxis.set_tick_params(**xy_major_params)
    ax.yaxis.set_tick_params(**xy_minor_params)
    ax.zaxis.set_tick_params(**z_major_params)
    ax.zaxis.set_tick_params(**z_minor_params)
    ax.set_xticks(**xy_major_ticks)
    ax.set_xticks(**xy_minor_ticks)
    ax.set_yticks(**xy_major_ticks)
    ax.set_yticks(**xy_minor_ticks)
    ax.set_zticks(**z_major_ticks)
    ax.set_zticks(**z_minor_ticks)
    ax.tick_params(labelsize=tick_labelsize)
    
    cbar = fig.colorbar(
        surf, 
        ax=ax, 
        orientation='vertical', 
        shrink=0.5, 
        aspect=12,
        pad = 0.10,
    )
    
    cbar.ax.tick_params(labelsize=tick_labelsize)
    
    if saveflag:
        savePlot(colormap, filetype)
    
    plt.tight_layout()
    
    plt.show()

x = y = np.linspace(-3, 3, 2**10, endpoint=True)
X, Y = np.meshgrid(x, y)

plotargs = dict(
    saveflag = False,
    dpi = 400,
    resolution = 200,
    numticks_xy=7, 
    numticks_xy_minor=25, 
    numticks_z=2, 
    numticks_z_minor=5,
)

plotGaussianSurface(X, Y, Gaussian2D(X, Y), **plotargs,)
Category:PNG created with Python

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w:en:Creative Commons
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Category:CC-BY-SA-4.0#Gaussian%202d%20surface.pngCategory:Self-published work
Category:Surface plots Category:2D Gaussians
Category:2D Gaussians Category:CC-BY-SA-4.0 Category:PNG created with Matplotlib code Category:PNG created with Python Category:Self-published work Category:Surface plots