5 O% k$ ~& D0 s1 t( Y4 Q8 R$ h7 [0 b 在我们科研、工作中,将数据完美展现出来尤为重要。
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数据可视化是以数据为视角,探索世界。我们真正想要的是 — 数据视觉,以数据为工具,以可视化为手段,目的是描述真实,探索世界。
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下面介绍一些数据可视化的作品(包含部分代码),主要是地学领域,可迁移至其他学科。
. ~; w: k9 x Y6 [ Example 1 :散点图、密度图(Python)
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import numpy as np
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import matplotlib.pyplot as plt
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# 创建随机数
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n = 100000
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x = np.random.randn(n)
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y = (1.5 * x) + np.random.randn(n)
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fig1 = plt.figure()
& w" @1 }1 N# T( T$ C plt.plot(x,y,.r)
$ l4 @% a+ n1 ?3 N( B plt.xlabel(x)
1 A4 V. C2 @7 v- H. c% _4 I$ ` plt.ylabel(y)
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plt.savefig(2D_1V1.png,dpi=600)
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nbins = 200
# p, c) k3 E5 v" X4 x
H, xedges, yedges = np.histogram2d(x,y,bins=nbins)
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# H needs to be rotated and flipped
7 ^- l2 f; u5 V# Z H = np.rot90(H)
& d5 I& c# _4 } H = np.flipud(H)
7 X* s" H) U: s3 b # 将zeros mask
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Hmasked = np.ma.masked_where(H==0,H)
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# Plot 2D histogram using pcolor
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fig2 = plt.figure()
% P+ F0 @& q+ {8 F plt.pcolormesh(xedges,yedges,Hmasked)
4 c2 s3 v* ?% `: I* @5 U plt.xlabel(x)
2 b; h; z9 l, [) H plt.ylabel(y)
9 l7 `. y6 m- X+ B cbar = plt.colorbar()
* E+ w: e/ t. C6 Q* E- R0 ?) P cbar.ax.set_ylabel(Counts)
* [% @, U1 Z, K/ R- E1 t9 |; x plt.savefig(2D_2V1.png,dpi=600)
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plt.show()
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打开凤凰新闻,查看更多高清图片
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- S+ k5 m6 o) u* w. Q Example 2 :双Y轴(Python)
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import csv
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import pandas as pd
$ ^( r! [5 q! q1 S import matplotlib.pyplot as plt
4 t: I8 Z' e( H+ o from datetime import datetime
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data=pd.read_csv(LOBO0010-2020112014010.tsv,sep=)
/ y- B3 U6 T( o' Y3 s/ g& W time=data[date [AST]]
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sal=data[salinity]
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tem=data[temperature [C]]
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print(sal)
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DAT = []
& D3 d% }! e( v2 P4 @1 \/ q for row in time:
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DAT.append(datetime.strptime(row,"%Y-%m-%d %H:%M:%S"))
: [$ ~+ k* Q' ` x; A: @9 m #create figure
) k# l6 E8 }0 d fig, ax =plt.subplots(1)
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# Plot y1 vs x in blue on the left vertical axis.
( x5 A. t) x8 R: a: \# x+ d plt.xlabel("Date [AST]")
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plt.ylabel("Temperature [C]", color="b")
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plt.tick_params(axis="y", labelcolor="b")
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plt.plot(DAT, tem, "b-", linewidth=1)
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plt.title("Temperature and Salinity from LOBO (Halifax, Canada)")
D; |. H1 d# y/ t+ Q fig.autofmt_xdate(rotation=50)
- F( ]" B; A# J. C! I5 H9 h # Plot y2 vs x in red on the right vertical axis.
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plt.twinx()
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plt.ylabel("Salinity", color="r")
1 H- f- p2 i& L/ g& V8 d ~ plt.tick_params(axis="y", labelcolor="r")
# O6 f' r8 P7 z& }: d0 e8 p
plt.plot(DAT, sal, "r-", linewidth=1)
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#To save your graph
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plt.savefig(saltandtemp_V1.png ,bbox_inches=tight)
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, C* `5 u- o. \6 C8 d3 h7 h Example 3:拟合曲线(Python)
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import numpy as np
* w6 {7 }2 r# h6 f X) J, @ import pandas as pd
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from datetime import datetime
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import matplotlib.pyplot as plt
2 _8 H6 Z( T, w' B- n import scipy.signal as signal
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data=pd.read_csv(LOBO0010-20201122130720.tsv,sep=)
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time=data[date [AST]]
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temp=data[temperature [C]]
$ S% w& P# N, m" o datestart = datetime.strptime(time[1],"%Y-%m-%d %H:%M:%S")
8 n8 z) E; F& b" \ DATE,decday = [],[]
' ~1 |- V: X5 c4 `% X for row in time:
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daterow = datetime.strptime(row,"%Y-%m-%d %H:%M:%S")
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DATE.append(daterow)
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decday.append((daterow-datestart).total_seconds()/(3600*24))
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# First, design the Buterworth filter
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N = 2 # Filter order
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Wn = 0.01 # Cutoff frequency
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B, A = signal.butter(N, Wn, output=ba)
; W' Z% _5 ?9 w7 g8 q9 E # Second, apply the filter
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tempf = signal.filtfilt(B,A, temp)
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# Make plots
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fig = plt.figure()
. B$ `8 @9 |6 @9 j- X1 I* o ax1 = fig.add_subplot(211)
& P6 Q; q( B+ e+ K/ J, Z- E plt.plot(decday,temp, b-)
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plt.plot(decday,tempf, r-,linewidth=2)
8 m5 M$ a; \$ Q; ~8 ~2 c plt.ylabel("Temperature (oC)")
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plt.legend([Original,Filtered])
, T: |1 n6 d$ O5 I& Q' s: ` plt.title("Temperature from LOBO (Halifax, Canada)")
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ax1.axes.get_xaxis().set_visible(False)
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plt.plot(decday,temp-tempf, b-)
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plt.ylabel("Temperature (oC)")
9 i; t4 @: p+ O plt.xlabel("Date")
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plt.legend([Residuals])
7 d* C F9 K+ o plt.savefig(tem_signal_filtering_plot.png, bbox_inches=tight)
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plt.show()
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Example 4:三维地形(Python)
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# This import registers the 3D projection
9 Y) K; X7 c& X; S# W from mpl_toolkits.mplot3d import Axes3D
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from matplotlib import cbook
& C' v$ d8 y }; F, m+ Q% J from matplotlib import cm
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from matplotlib.colors import LightSource
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import matplotlib.pyplot as plt
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import numpy as np
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filename = cbook.get_sample_data(jacksboro_fault_dem.npz, asfileobj=False)
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with np.load(filename) as dem:
. R' C# S% C7 L9 u& `+ Q9 W0 L z = dem[elevation]
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nrows, ncols = z.shape
8 a t2 q& T6 `: { b x = np.linspace(dem[xmin], dem[xmax], ncols)
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y = np.linspace(dem[ymin], dem[ymax], nrows)
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x, y = np.meshgrid(x, y)
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region = np.s_[5:50, 5:50]
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x, y, z = x[region], y[region], z[region]
6 z% o9 Q. S' I. V# f8 m/ z fig, ax = plt.subplots(subplot_kw=dict(projection=3d))
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ls = LightSource(270, 45)
6 c' E/ H s8 ^7 P* ]" ~ rgb = ls.shade(z, cmap=cm.gist_earth, vert_exag=0.1, blend_mode=soft)
( x& M- u# ?2 ~* U! z+ a surf = ax.plot_surface(x, y, z, rstride=1, cstride=1, facecolors=rgb,
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linewidth=0, antialiased=False, shade=False)
- E" D9 d5 \3 f# B4 S' K, q plt.savefig(example4.png,dpi=600, bbox_inches=tight)
9 S& u4 k: N8 ^9 G plt.show()
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Example 5:三维地形,包含投影(Python)
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Example 6:切片,多维数据同时展现(Python)
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4 d! S- w1 h# B1 z7 q7 x Example 7:SSH GIF 动图展现(Matlab)
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Example 8:Glider GIF 动图展现(Python)
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* m& o, h9 {, Q Example 9:涡度追踪 GIF 动图展现
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