目录
matplotlib教程学习笔记
如何创建网格形式的axes的组合呢:
subplots()
GridSpec
SubplotSpec
subplot2grid()
import matplotlib
import matplotlib.pyplot as plt
import matplotlib.gridspec as gridspec
第一个例子是利用subplots()和gridspec来创建一个\(2\times 2\)的网格
首先利用subplots()是很容易做到这一点的:
fig1, fi_axes = plt.subplots(ncols=2, nrows=2, constrained_layout=True) #constrain_layout参数似乎是控制是否会重叠的
使用gridspec需要先创建一个fig对象,再创建Gridspec对象,然后将实例传入add_subplot(),gridspec的使用习惯和numpy数组是相当的
fig2 = plt.figure(constrained_layout=True)
spec2 = gridspec.GridSpec(ncols=2, nrows=2, figure=fig2)
f2_ax1 = fig2.add_subplot(spec2[0, 0])
f2_ax2 = fig2.add_subplot(spec2[0, 1])
f2_ax3 = fig2.add_subplot(spec2[1, 0])
f2_ax4 = fig2.add_subplot(spec2[1, 1])
gridspec有什么厉害的地方呢,我们可以通过索引和切片操作,使得某些axes占据多个格子
fig3 = plt.figure(constrained_layout=True)
gs = fig3.add_gridspec(3, 3)
f3_ax1 = fig3.add_subplot(gs[0, :])
f3_ax1.set_title('gs[0, :]')
f3_ax2 = fig3.add_subplot(gs[1, :-1])
f3_ax2.set_title('gs[1, :-1]')
f3_ax3 = fig3.add_subplot(gs[1:, -1])
f3_ax3.set_title('gs[1:, -1]')
f3_ax4 = fig3.add_subplot(gs[-1, 0])
f3_ax4.set_title('gs[-1, 0]')
f3_ax5 = fig3.add_subplot(gs[-1, -2])
f3_ax5.set_title('gs[-1, -2]');
fig4 = plt.figure(constrained_layout=True)
spec4 = fig4.add_gridspec(ncols=2, nrows=2)
anno_opts = dict(xy=(0.3, 0.3), xycoords='axes fraction',
va='center', ha='center')
f4_ax1 = fig4.add_subplot(spec4[0, 0])
f4_ax1.annotate('GridSpec[0, 0]', **anno_opts)
fig4.add_subplot(spec4[0, 1]).annotate('GridSpec[0, 1:]', **anno_opts)
fig4.add_subplot(spec4[1, 0]).annotate('GridSpec[1:, 0]', **anno_opts)
fig4.add_subplot(spec4[1, 1]).annotate('GridSpec[1:, 1:]', **anno_opts);
另外的,width_ratios和height_ratios参数,参数需要传入一个装有数字,比如[2, 4, 8]和
[1, 2, 4],不过这俩个表示的含义是一样的,因为参数关系的他们之间的比例:
2:4:8与1:2:4是一致的。
fig5 = plt.figure(constrained_layout=True)
widths = [2, 3, 1.5]
heights = [1, 3, 2]
spec5 = fig5.add_gridspec(ncols=3, nrows=3, width_ratios=widths,
height_ratios=heights)
for row in range(3):
for col in range(3):
ax = fig5.add_subplot(spec5[row, col])
label = 'Width: {}\nHeight: {}'.format(widths[col], heights[row])
ax.annotate(label, (0.1, 0.5), xycoords='axes fraction', va='center')
事实上,width_ratio参数和height_ratio参数对于subplots()是十分便利的一个工具,subplots()有一个gridspec_kw参数,事实上,借此我们可以将传入gridspec的参数传入subplots(),具体形式如下:
gs_kw = dict(width_ratios=widths, height_ratios=heights)
fig6, f6_axes = plt.subplots(ncols=3, nrows=3, constrained_layout=True,
gridspec_kw=gs_kw)
for r, row in enumerate(f6_axes):
for c, ax in enumerate(row):
label = 'Width: {}\nHeight: {}'.format(widths[c], heights[r])
ax.annotate(label, (0.1, 0.5), xycoords='axes fraction', va='center')
subplots和gridspec二者可以结合,比如,我们可以通过subplots先创建大部分的axes,再利用gridspec组合某些部分,当然,这可能需要利用到
get_gridspec方法和remove方法
fig7, f7_axs = plt.subplots(ncols=3, nrows=3)
gs = f7_axs[1, 2].get_gridspec()
# remove the underlying axes
for ax in f7_axs[1:, -1]:
ax.remove()
axbig = fig7.add_subplot(gs[1:, -1])
axbig.annotate('Big Axes \nGridSpec[1:, -1]', (0.1, 0.5),
xycoords='axes fraction', va='center')
fig7.tight_layout();
当gridspec被显示使用的时候,我们可以通过一些参数来进行细微的调整,注意这个选择与constrained_layout或者figure.tight_layout是有冲突的
left : axes左边缘距离画板左侧的距离
right: axes右边缘距离画板左侧的距离
top : axes上边缘距离画板下侧的距离
bottom : axes下边缘距离画板下侧的距离
hspace: 预留给subplots之间的高度的距离
wspace: 预留给subplots之间的宽度的距离
fig8 = plt.figure(constrained_layout=False) #注意设置为False否则会冲突
gs1 = fig8.add_gridspec(nrows=3, ncols=3, right=0.88, wspace=0.05)
f8_ax1 = fig8.add_subplot(gs1[:-1, :])
f8_ax2 = fig8.add_subplot(gs1[-1, :-1])
f8_ax3 = fig8.add_subplot(gs1[-1, -1])
这些细微的调整只对由gridspec创建的格子有效
fig9 = plt.figure(constrained_layout=False)
gs1 = fig9.add_gridspec(nrows=3, ncols=3, left=0.05, right=0.48,
wspace=0.05)
f9_ax1 = fig9.add_subplot(gs1[:-1, :])
f9_ax2 = fig9.add_subplot(gs1[-1, :-1])
f9_ax3 = fig9.add_subplot(gs1[-1, -1])
gs2 = fig9.add_gridspec(nrows=3, ncols=3, left=0.55, right=0.98,
hspace=0.05)
f9_ax4 = fig9.add_subplot(gs2[:, :-1])
f9_ax5 = fig9.add_subplot(gs2[:-1, -1])
f9_ax6 = fig9.add_subplot(gs2[-1, -1])
fig10 = plt.figure(constrained_layout=True)
gs0 = fig10.add_gridspec(1, 2)
gs00 = gs0[0].subgridspec(2, 3)
gs01 = gs0[1].subgridspec(3, 2)
for a in range(2):
for b in range(3):
fig10.add_subplot(gs00[a, b])
fig10.add_subplot(gs01[b, a])
import numpy as np
from itertools import product
def squiggle_xy(a, b, c, d, i=np.arange(0.0, 2*np.pi, 0.05)):
return np.sin(i*a)*np.cos(i*b), np.sin(i*c)*np.cos(i*d)
fig11 = plt.figure(figsize=(8, 8), constrained_layout=False)
# gridspec inside gridspec
outer_grid = fig11.add_gridspec(4, 4, wspace=0.0, hspace=0.0) #4 x 4个大格子
for i in range(16):
inner_grid = outer_grid[i].subgridspec(3, 3, wspace=0.0, hspace=0.0) #3 x 3个小格子
a, b = int(i/4)+1, i % 4+1
for j, (c, d) in enumerate(product(range(1, 4), repeat=2)):
ax = plt.Subplot(fig11, inner_grid[j])
ax.plot(*squiggle_xy(a, b, c, d))
ax.set_xticks([])
ax.set_yticks([])
fig11.add_subplot(ax)
all_axes = fig11.get_axes()
# show only the outside spines
# 之显示每个大格子外面的边框,小格子的边框就不显示
for ax in all_axes:
for sp in ax.spines.values():
sp.set_visible(False)
if ax.is_first_row():
ax.spines['top'].set_visible(True)
if ax.is_last_row():
ax.spines['bottom'].set_visible(True)
if ax.is_first_col():
ax.spines['left'].set_visible(True)
if ax.is_last_col():
ax.spines['right'].set_visible(True)
plt.show()
手机扫一扫
移动阅读更方便
你可能感兴趣的文章