MatPlotLib - 子图的子图或单个图上的多个断轴图
MatPlotLib - Subplots of subplot or multiple broken axis charts on single plot
想知道是否可以创建子图的子图。我想要这样做的原因是在一个图上创建 3 个断轴图。我了解如何使用下面的示例代码创建单个断轴图,但由于断轴图需要使用子图,我现在处于尝试使用子图创建 3 列的位置,然后将这些列子图绘制成一个包含 2 行的子图,用于创建断轴图。请参阅下面的直观说明。
"""
EXAMPLE OF A SINGLE BROKEN AXIS CHART
"""
import matplotlib.pyplot as plt
import numpy as np
# 30 points between 0 0.2] originally made using np.random.rand(30)*.2
ptsA = np.array([
0.015, 0.166, 0.133, 0.159, 0.041, 0.024, 0.195, 0.039, 0.161, 0.018,
0.143, 0.056, 0.125, 0.096, 0.094, 0.051, 0.043, 0.021, 0.138, 0.075,
0.109, 0.195, 0.050, 0.074, 0.079, 0.155, 0.020, 0.010, 0.061, 0.008])
# Now let's make two outlier points which are far away from everything.
ptsA[[3, 14]] += .8
# 30 points between 0 0.2] originally made using np.random.rand(30)*.2
ptsB = np.array([
0.015, 0.166, 0.133, 0.159, 0.041, 0.024, 0.195, 0.039, 0.161, 0.018,
0.143, 0.056, 0.125, 0.096, 0.094, 0.051, 0.043, 0.021, 0.138, 0.075,
0.109, 0.195, 0.050, 0.074, 0.079, 0.155, 0.020, 0.010, 0.061, 0.008])
# Now let's make two outlier points which are far away from everything.
ptsB[[1, 7, 9, 13, 15]] += .95
# If we were to simply plot pts, we'd lose most of the interesting
# details due to the outliers. So let's 'break' or 'cut-out' the y-axis
# into two portions - use the top (ax) for the outliers, and the bottom
# (ax2) for the details of the majority of our data
f, (ax, ax2) = plt.subplots(2, 1, sharex=True)
# plot the same data on both axes
ax.plot(ptsB)
ax2.plot(pts)
# zoom-in / limit the view to different portions of the data
ax.set_ylim(.78, 1.) # outliers only
ax2.set_ylim(0, .22) # most of the data
# hide the spines between ax and ax2
ax.spines['bottom'].set_visible(False)
ax2.spines['top'].set_visible(False)
ax.xaxis.tick_top()
ax.tick_params(labeltop='off') # don't put tick labels at the top
ax2.xaxis.tick_bottom()
# This looks pretty good, and was fairly painless, but you can get that
# cut-out diagonal lines look with just a bit more work. The important
# thing to know here is that in axes coordinates, which are always
# between 0-1, spine endpoints are at these locations (0,0), (0,1),
# (1,0), and (1,1). Thus, we just need to put the diagonals in the
# appropriate corners of each of our axes, and so long as we use the
# right transform and disable clipping.
d = .015 # how big to make the diagonal lines in axes coordinates
# arguments to pass plot, just so we don't keep repeating them
kwargs = dict(transform=ax.transAxes, color='k', clip_on=False)
ax.plot((-d, +d), (-d, +d), **kwargs) # top-left diagonal
ax.plot((1 - d, 1 + d), (-d, +d), **kwargs) # top-right diagonal
kwargs.update(transform=ax2.transAxes) # switch to the bottom axes
ax2.plot((-d, +d), (1 - d, 1 + d), **kwargs) # bottom-left diagonal
ax2.plot((1 - d, 1 + d), (1 - d, 1 + d), **kwargs) # bottom-right diagonal
# What's cool about this is that now if we vary the distance between
# ax and ax2 via f.subplots_adjust(hspace=...) or plt.subplot_tool(),
# the diagonal lines will move accordingly, and stay right at the tips
# of the spines they are 'breaking'
plt.show()
期望的输出
3 subplots, each containing 2 subplots
首先,您不能创建子图的子图。子图是放置在图形中的 axes 个对象,轴不能有 "child axes"。
您的问题的解决方案是创建 6 个子图并将 sharex=True 应用于各自的轴。
import matplotlib.pyplot as plt
import numpy as np
data = np.random.rand(17, 6)
data[15:, 3:] = np.random.rand(2, 3)+3.
markers=["o", "p", "s"]
colors=["r", "g", "b"]
fig=plt.figure(figsize=(10, 4))
axes = []
for i in range(3):
ax = fig.add_subplot(2,3,i+1)
axes.append(ax)
for i in range(3):
ax = fig.add_subplot(2,3,i+4, sharex=axes[i])
axes.append(ax)
for i in range(3):
# plot same data in both top and down axes
axes[i].plot(data[:,i], data[:,i+3], marker=markers[i], linestyle="", color=colors[i])
axes[i+3].plot(data[:,i], data[:,i+3], marker=markers[i], linestyle="", color=colors[i])
for i in range(3):
axes[i].spines['bottom'].set_visible(False)
axes[i+3].spines['top'].set_visible(False)
axes[i].xaxis.tick_top()
axes[i].tick_params(labeltop='off') # don't put tick labels at the top
axes[i+3].xaxis.tick_bottom()
axes[i].set_ylim([3,4])
axes[i+3].set_ylim([0,1])
axes[i].set_xlim([0,1])
#adjust space between subplots
plt.subplots_adjust(hspace=0.08, wspace=0.4)
plt.show()
想知道是否可以创建子图的子图。我想要这样做的原因是在一个图上创建 3 个断轴图。我了解如何使用下面的示例代码创建单个断轴图,但由于断轴图需要使用子图,我现在处于尝试使用子图创建 3 列的位置,然后将这些列子图绘制成一个包含 2 行的子图,用于创建断轴图。请参阅下面的直观说明。
"""
EXAMPLE OF A SINGLE BROKEN AXIS CHART
"""
import matplotlib.pyplot as plt
import numpy as np
# 30 points between 0 0.2] originally made using np.random.rand(30)*.2
ptsA = np.array([
0.015, 0.166, 0.133, 0.159, 0.041, 0.024, 0.195, 0.039, 0.161, 0.018,
0.143, 0.056, 0.125, 0.096, 0.094, 0.051, 0.043, 0.021, 0.138, 0.075,
0.109, 0.195, 0.050, 0.074, 0.079, 0.155, 0.020, 0.010, 0.061, 0.008])
# Now let's make two outlier points which are far away from everything.
ptsA[[3, 14]] += .8
# 30 points between 0 0.2] originally made using np.random.rand(30)*.2
ptsB = np.array([
0.015, 0.166, 0.133, 0.159, 0.041, 0.024, 0.195, 0.039, 0.161, 0.018,
0.143, 0.056, 0.125, 0.096, 0.094, 0.051, 0.043, 0.021, 0.138, 0.075,
0.109, 0.195, 0.050, 0.074, 0.079, 0.155, 0.020, 0.010, 0.061, 0.008])
# Now let's make two outlier points which are far away from everything.
ptsB[[1, 7, 9, 13, 15]] += .95
# If we were to simply plot pts, we'd lose most of the interesting
# details due to the outliers. So let's 'break' or 'cut-out' the y-axis
# into two portions - use the top (ax) for the outliers, and the bottom
# (ax2) for the details of the majority of our data
f, (ax, ax2) = plt.subplots(2, 1, sharex=True)
# plot the same data on both axes
ax.plot(ptsB)
ax2.plot(pts)
# zoom-in / limit the view to different portions of the data
ax.set_ylim(.78, 1.) # outliers only
ax2.set_ylim(0, .22) # most of the data
# hide the spines between ax and ax2
ax.spines['bottom'].set_visible(False)
ax2.spines['top'].set_visible(False)
ax.xaxis.tick_top()
ax.tick_params(labeltop='off') # don't put tick labels at the top
ax2.xaxis.tick_bottom()
# This looks pretty good, and was fairly painless, but you can get that
# cut-out diagonal lines look with just a bit more work. The important
# thing to know here is that in axes coordinates, which are always
# between 0-1, spine endpoints are at these locations (0,0), (0,1),
# (1,0), and (1,1). Thus, we just need to put the diagonals in the
# appropriate corners of each of our axes, and so long as we use the
# right transform and disable clipping.
d = .015 # how big to make the diagonal lines in axes coordinates
# arguments to pass plot, just so we don't keep repeating them
kwargs = dict(transform=ax.transAxes, color='k', clip_on=False)
ax.plot((-d, +d), (-d, +d), **kwargs) # top-left diagonal
ax.plot((1 - d, 1 + d), (-d, +d), **kwargs) # top-right diagonal
kwargs.update(transform=ax2.transAxes) # switch to the bottom axes
ax2.plot((-d, +d), (1 - d, 1 + d), **kwargs) # bottom-left diagonal
ax2.plot((1 - d, 1 + d), (1 - d, 1 + d), **kwargs) # bottom-right diagonal
# What's cool about this is that now if we vary the distance between
# ax and ax2 via f.subplots_adjust(hspace=...) or plt.subplot_tool(),
# the diagonal lines will move accordingly, and stay right at the tips
# of the spines they are 'breaking'
plt.show()
期望的输出 3 subplots, each containing 2 subplots
首先,您不能创建子图的子图。子图是放置在图形中的 axes 个对象,轴不能有 "child axes"。
您的问题的解决方案是创建 6 个子图并将 sharex=True 应用于各自的轴。
import matplotlib.pyplot as plt
import numpy as np
data = np.random.rand(17, 6)
data[15:, 3:] = np.random.rand(2, 3)+3.
markers=["o", "p", "s"]
colors=["r", "g", "b"]
fig=plt.figure(figsize=(10, 4))
axes = []
for i in range(3):
ax = fig.add_subplot(2,3,i+1)
axes.append(ax)
for i in range(3):
ax = fig.add_subplot(2,3,i+4, sharex=axes[i])
axes.append(ax)
for i in range(3):
# plot same data in both top and down axes
axes[i].plot(data[:,i], data[:,i+3], marker=markers[i], linestyle="", color=colors[i])
axes[i+3].plot(data[:,i], data[:,i+3], marker=markers[i], linestyle="", color=colors[i])
for i in range(3):
axes[i].spines['bottom'].set_visible(False)
axes[i+3].spines['top'].set_visible(False)
axes[i].xaxis.tick_top()
axes[i].tick_params(labeltop='off') # don't put tick labels at the top
axes[i+3].xaxis.tick_bottom()
axes[i].set_ylim([3,4])
axes[i+3].set_ylim([0,1])
axes[i].set_xlim([0,1])
#adjust space between subplots
plt.subplots_adjust(hspace=0.08, wspace=0.4)
plt.show()