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数据可视化是目前最牛逼的行业之一!这些必学库你会几个呢?

数据可视化是目前最牛逼的行业之一!这些必学库你会几个呢?

作者: 919b0c54458f | 来源:发表于2018-12-05 14:11 被阅读34次

    推荐

    数据可视化的库有挺多的,这里推荐几个比较常用的:

    Matplotlib

    Plotly

    Seaborn

    Ggplot

    Bokeh

    Pyechart

    Pygal

    Plotly

    Plotly 文档地址:

    https://plot.ly/python/#financial-charts

    进群:548377875   即可获取数十套PDF的获取方式,进入自行下载即可!

    使用方式:

    Plotly 有 online 和 offline 两种方式,这里只介绍 offline 的。

    这是 Plotly 官方教程的一部分

    import plotly.plotly as py

    import numpy as np

    data = [dict(

    visible=False,

    line=dict(color='#00CED1', width=6), # 配置线宽和颜色

    name=' = ' + str(step),

    x=np.arange(0, 10, 0.01), # x 轴参数

    y=np.sin(step * np.arange(0, 10, 0.01))) for step in np.arange(0, 5, 0.1)] # y 轴参数

    data[10]['visible'] = True

    py.iplot(data, filename='Single Sine Wave')

    只要将最后一行中的

    py.iplot

    替换为下面代码

    py.offline.plot

    便可以运行。

    漏斗图

    这个图代码太长了,就不 po 出来了。

    Basic Box Plot

    import plotly.plotly

    import plotly.graph_objs as go

    import numpy as np

    y0 = np.random.randn(50)-1

    y1 = np.random.randn(50)+1

    trace0 = go.Box(

    y=y0

    )

    trace1 = go.Box(

    y=y1

    )

    data = [trace0, trace1]

    plotly.offline.plot(data)

    Wind Rose Chart

    import plotly.graph_objs as go

    trace1 = go.Barpolar(

    r=[77.5, 72.5, 70.0, 45.0, 22.5, 42.5, 40.0, 62.5],

    text=['North', 'N-E', 'East', 'S-E', 'South', 'S-W', 'West', 'N-W'],

    name='11-14 m/s',

    marker=dict(

    color='rgb(106,81,163)'

    )

    )

    trace2 = go.Barpolar(

    r=[57.49999999999999, 50.0, 45.0, 35.0, 20.0, 22.5, 37.5, 55.00000000000001],

    text=['North', 'N-E', 'East', 'S-E', 'South', 'S-W', 'West', 'N-W'], # 鼠标浮动标签文字描述

    name='8-11 m/s',

    marker=dict(

    color='rgb(158,154,200)'

    )

    )

    trace3 = go.Barpolar(

    r=[40.0, 30.0, 30.0, 35.0, 7.5, 7.5, 32.5, 40.0],

    text=['North', 'N-E', 'East', 'S-E', 'South', 'S-W', 'West', 'N-W'],

    name='5-8 m/s',

    marker=dict(

    color='rgb(203,201,226)'

    )

    )

    trace4 = go.Barpolar(

    r=[20.0, 7.5, 15.0, 22.5, 2.5, 2.5, 12.5, 22.5],

    text=['North', 'N-E', 'East', 'S-E', 'South', 'S-W', 'West', 'N-W'],

    name='< 5 m/s',

    marker=dict(

    color='rgb(242,240,247)'

    )

    )

    data = [trace1, trace2, trace3, trace4]

    layout = go.Layout(

    title='Wind Speed Distribution in Laurel, NE',

    font=dict(

    size=16

    ),

    legend=dict(

    font=dict(

    size=16

    )

    ),

    radialaxis=dict(

    ticksuffix='%'

    ),

    orientation=270

    )

    fig = go.Figure(data=data, layout=layout)

    plotly.offline.plot(fig, filename='polar-area-chart')

    Basic Ternary Plot with Markers

    篇幅有点长,这里就不 po 代码了。

    Bokeh

    这里展示一下常用的图表和比较抢眼的图表,详细的文档可查看。

    条形图

    这配色看着还挺舒服的,比 pyecharts 条形图的配色好看一点。

    from bokeh.io import show, output_file

    from bokeh.models import ColumnDataSource

    from bokeh.palettes import Spectral6

    from bokeh.plotting import figure

    output_file("colormapped_bars.html")# 配置输出文件名

    fruits = ['Apples', '魅族', 'OPPO', 'VIVO', '小米', '华为'] # 数据

    counts = [5, 3, 4, 2, 4, 6] # 数据

    source = ColumnDataSource(data=dict(fruits=fruits, counts=counts, color=Spectral6))

    p = figure(x_range=fruits, y_range=(0,9), plot_height=250, title="Fruit Counts",

    toolbar_location=None, tools="")# 条形图配置项

    p.vbar(x='fruits', top='counts', width=0.9, color='color', legend="fruits", source=source)

    p.xgrid.grid_line_color = None # 配置网格线颜色

    p.legend.orientation = "horizontal" # 图表方向为水平方向

    p.legend.location = "top_center"

    show(p) # 展示图表

    年度条形图

    可以对比不同时间点的量。

    from bokeh.io import show, output_file

    from bokeh.models import ColumnDataSource, FactorRange

    from bokeh.plotting import figure

    output_file("bars.html") # 输出文件名

    fruits = ['Apple', '魅族', 'OPPO', 'VIVO', '小米', '华为'] # 参数

    years = ['2015', '2016', '2017'] # 参数

    data = {'fruits': fruits,

    '2015': [2, 1, 4, 3, 2, 4],

    '2016': [5, 3, 3, 2, 4, 6],

    '2017': [3, 2, 4, 4, 5, 3]}

    x = [(fruit, year) for fruit in fruits for year in years]

    counts = sum(zip(data['2015'], data['2016'], data['2017']), ())

    source = ColumnDataSource(data=dict(x=x, counts=counts))

    p = figure(x_range=FactorRange(*x), plot_height=250, title="Fruit Counts by Year",

    toolbar_location=None, tools="")

    p.vbar(x='x', top='counts', width=0.9, source=source)

    p.y_range.start = 0

    p.x_range.range_padding = 0.1

    p.xaxis.major_label_orientation = 1

    p.xgrid.grid_line_color = None

    show(p)

    饼图

    from collections import Counter

    from math import pi

    import pandas as pd

    from bokeh.io import output_file, show

    from bokeh.palettes import Category20c

    from bokeh.plotting import figure

    from bokeh.transform import cumsum

    output_file("pie.html")

    x = Counter({

    '中国': 157,

    '美国': 93,

    '日本': 89,

    '巴西': 63,

    '德国': 44,

    '印度': 42,

    '意大利': 40,

    '澳大利亚': 35,

    '法国': 31,

    '西班牙': 29

    })

    data = pd.DataFrame.from_dict(dict(x), orient='index').reset_index().rename(index=str, columns={0:'value', 'index':'country'})

    data['angle'] = data['value']/sum(x.values()) * 2*pi

    data['color'] = Category20c[len(x)]

    p = figure(plot_height=350, title="Pie Chart", toolbar_location=None,

    tools="hover", tooltips="@country: @value")

    p.wedge(x=0, y=1, radius=0.4,

    start_angle=cumsum('angle', include_zero=True), end_angle=cumsum('angle'),

    line_color="white", fill_color='color', legend='country', source=data)

    p.axis.axis_label=None

    p.axis.visible=False

    p.grid.grid_line_color = None

    show(p)

    条形图

    年度水果进出口

    from bokeh.io import output_file, show

    from bokeh.models import ColumnDataSource

    from bokeh.palettes import GnBu3, OrRd3

    from bokeh.plotting import figure

    output_file("stacked_split.html")

    fruits = ['Apples', 'Pears', 'Nectarines', 'Plums', 'Grapes', 'Strawberries']

    years = ["2015", "2016", "2017"]

    exports = {'fruits': fruits,

    '2015': [2, 1, 4, 3, 2, 4],

    '2016': [5, 3, 4, 2, 4, 6],

    '2017': [3, 2, 4, 4, 5, 3]}

    imports = {'fruits': fruits,

    '2015': [-1, 0, -1, -3, -2, -1],

    '2016': [-2, -1, -3, -1, -2, -2],

    '2017': [-1, -2, -1, 0, -2, -2]}

    p = figure(y_range=fruits, plot_height=250, x_range=(-16, 16), title="Fruit import/export, by year",

    toolbar_location=None)

    p.hbar_stack(years, y='fruits', height=0.9, color=GnBu3, source=ColumnDataSource(exports),

    legend=["%s exports" % x for x in years])

    p.hbar_stack(years, y='fruits', height=0.9, color=OrRd3, source=ColumnDataSource(imports),

    legend=["%s imports" % x for x in years])

    p.y_range.range_padding = 0.1

    p.ygrid.grid_line_color = None

    p.legend.location = "top_left"

    p.axis.minor_tick_line_color = None

    p.outline_line_color = None

    show(p)

    散点图

    from bokeh.plotting import figure, output_file, show

    output_file("line.html")

    p = figure(plot_width=400, plot_height=400)

    p.circle([1, 2, 3, 4, 5], [6, 7, 2, 4, 5], size=20, color="navy", alpha=0.5)

    show(p)

    六边形图

    这两天,马蜂窝刚被发现数据造假,这不,与马蜂窝应应景。

    import numpy as np

    from bokeh.io import output_file, show

    from bokeh.plotting import figure

    from bokeh.util.hex import axial_to_cartesian

    output_file("hex_coords.html")

    q = np.array([0, 0, 0, -1, -1, 1, 1])

    r = np.array([0, -1, 1, 0, 1, -1, 0])

    p = figure(plot_width=400, plot_height=400, toolbar_location=None) #

    p.grid.visible = False # 配置网格是否可见

    p.hex_tile(q, r, size=1, fill_color=["firebrick"] * 3 + ["navy"] * 4,

    line_color="white", alpha=0.5)

    x, y = axial_to_cartesian(q, r, 1, "pointytop")

    p.text(x, y, text=["(%d, %d)" % (q, r) for (q, r) in zip(q, r)],

    text_baseline="middle", text_align="center")

    show(p)

    环比条形图

    这个实现挺厉害的,看了一眼就吸引了我。我在代码中都做了一些注释,希望对你理解有帮助。注:圆心为正中央,即直角坐标系中标签为(0,0)的地方。

    from collections import OrderedDict

    from math import log, sqrt

    import numpy as np

    import pandas as pd

    from six.moves import cStringIO as StringIO

    from bokeh.plotting import figure, show, output_file

    antibiotics = """

    bacteria, penicillin, streptomycin, neomycin, gram

    结核分枝杆菌, 800, 5, 2, negative

    沙门氏菌, 10, 0.8, 0.09, negative

    变形杆菌, 3, 0.1, 0.1, negative

    肺炎克雷伯氏菌, 850, 1.2, 1, negative

    布鲁氏菌, 1, 2, 0.02, negative

    铜绿假单胞菌, 850, 2, 0.4, negative

    大肠杆菌, 100, 0.4, 0.1, negative

    产气杆菌, 870, 1, 1.6, negative

    白色葡萄球菌, 0.007, 0.1, 0.001, positive

    溶血性链球菌, 0.001, 14, 10, positive

    草绿色链球菌, 0.005, 10, 40, positive

    肺炎双球菌, 0.005, 11, 10, positive

    """

    drug_color = OrderedDict([# 配置中间标签名称与颜色

    ("盘尼西林", "#0d3362"),

    ("链霉素", "#c64737"),

    ("新霉素", "black"),

    ])

    gram_color = {

    "positive": "#aeaeb8",

    "negative": "#e69584",

    }

    # 读取数据

    df = pd.read_csv(StringIO(antibiotics),

    skiprows=1,

    skipinitialspace=True,

    engine='python')

    width = 800

    height = 800

    inner_radius = 90

    outer_radius = 300 - 10

    minr = sqrt(log(.001 * 1E4))

    maxr = sqrt(log(1000 * 1E4))

    a = (outer_radius - inner_radius) / (minr - maxr)

    b = inner_radius - a * maxr

    def rad(mic):

    return a * np.sqrt(np.log(mic * 1E4)) + b

    big_angle = 2.0 * np.pi / (len(df) + 1)

    small_angle = big_angle / 7

    # 整体配置

    p = figure(plot_width=width, plot_height=height, title="",

    x_axis_type=None, y_axis_type=None,

    x_range=(-420, 420), y_range=(-420, 420),

    min_border=0, outline_line_color="black",

    background_fill_color="#f0e1d2")

    p.xgrid.grid_line_color = None

    p.ygrid.grid_line_color = None

    # annular wedges

    angles = np.pi / 2 - big_angle / 2 - df.index.to_series() * big_angle #计算角度

    colors = [gram_color[gram] for gram in df.gram] # 配置颜色

    p.annular_wedge(

    0, 0, inner_radius, outer_radius, -big_angle + angles, angles, color=colors,

    )

    # small wedges

    p.annular_wedge(0, 0, inner_radius, rad(df.penicillin),

    -big_angle + angles + 5 * small_angle, -big_angle + angles + 6 * small_angle,

    color=drug_color['盘尼西林'])

    p.annular_wedge(0, 0, inner_radius, rad(df.streptomycin),

    -big_angle + angles + 3 * small_angle, -big_angle + angles + 4 * small_angle,

    color=drug_color['链霉素'])

    p.annular_wedge(0, 0, inner_radius, rad(df.neomycin),

    -big_angle + angles + 1 * small_angle, -big_angle + angles + 2 * small_angle,

    color=drug_color['新霉素'])

    # 绘制大圆和标签

    labels = np.power(10.0, np.arange(-3, 4))

    radii = a * np.sqrt(np.log(labels * 1E4)) + b

    p.circle(0, 0, radius=radii, fill_color=None, line_color="white")

    p.text(0, radii[:-1], [str(r) for r in labels[:-1]],

    text_font_size="8pt", text_align="center", text_baseline="middle")

    # 半径

    p.annular_wedge(0, 0, inner_radius - 10, outer_radius + 10,

    -big_angle + angles, -big_angle + angles, color="black")

    # 细菌标签

    xr = radii[0] * np.cos(np.array(-big_angle / 2 + angles))

    yr = radii[0] * np.sin(np.array(-big_angle / 2 + angles))

    label_angle = np.array(-big_angle / 2 + angles)

    label_angle[label_angle < -np.pi / 2] += np.pi # easier to read labels on the left side

    # 绘制各个细菌的名字

    p.text(xr, yr, df.bacteria, angle=label_angle,

    text_font_size="9pt", text_align="center", text_baseline="middle")

    # 绘制圆形,其中数字分别为 x 轴与 y 轴标签

    p.circle([-40, -40], [-370, -390], color=list(gram_color.values()), radius=5)

    # 绘制文字

    p.text([-30, -30], [-370, -390], text=["Gram-" + gr for gr in gram_color.keys()],

    text_font_size="7pt", text_align="left", text_baseline="middle")

    # 绘制矩形,中间标签部分。其中 -40,-40,-40 为三个矩形的 x 轴坐标。18,0,-18 为三个矩形的 y 轴坐标

    p.rect([-40, -40, -40], [18, 0, -18], width=30, height=13,

    color=list(drug_color.values()))

    # 配置中间标签文字、文字大小、文字对齐方式

    p.text([-15, -15, -15], [18, 0, -18], text=list(drug_color),

    text_font_size="9pt", text_align="left", text_baseline="middle")

    output_file("burtin.html", title="burtin.py example")

    show(p)

    元素周期表

    元素周期表,这个实现好牛逼啊,距离初三刚开始学化学已经很遥远了,想当年我还是化学课代表呢!由于基本用不到化学了,这里就不实现了。

    真实状态

    Pyecharts

    pyecharts 也是一个比较常用的数据可视化库,用得也是比较多的了,是百度 Echarts 库的 Python 支持。这里也展示一下常用的图表。

    文档地址为:

    http://pyecharts.org/#/zh-cn/prepare?id=%E5%AE%89%E8%A3%85-pyecharts

    条形图

    from pyecharts import Bar

    bar = Bar("我的第一个图表", "这里是副标题")

    bar.add("服装", ["衬衫", "羊毛衫", "雪纺衫", "裤子", "高跟鞋", "袜子"], [5, 20, 36, 10, 75, 90])

    # bar.print_echarts_options() # 该行只为了打印配置项,方便调试时使用

    bar.render() # 生成本地 HTML 文件

    散点图

    from pyecharts import Polar

    import random

    data_1 = [(10, random.randint(1, 100)) for i in range(300)]

    data_2 = [(11, random.randint(1, 100)) for i in range(300)]

    polar = Polar("极坐标系-散点图示例", width=1200, height=600)

    polar.add("", data_1, type='scatter')

    polar.add("", data_2, type='scatter')

    polar.render()

    饼图

    import random

    from pyecharts import Pie

    attr = ['A', 'B', 'C', 'D', 'E', 'F']

    pie = Pie("饼图示例", width=1000, height=600)

    pie.add(

    "",

    attr,

    [random.randint(0, 100) for _ in range(6)],

    radius=[50, 55],

    center=[25, 50],

    is_random=True,

    )

    pie.add(

    "",

    attr,

    [random.randint(20, 100) for _ in range(6)],

    radius=[0, 45],

    center=[25, 50],

    rosetype="area",

    )

    pie.add(

    "",

    attr,

    [random.randint(0, 100) for _ in range(6)],

    radius=[50, 55],

    center=[65, 50],

    is_random=True,

    )

    pie.add(

    "",

    attr,

    [random.randint(20, 100) for _ in range(6)],

    radius=[0, 45],

    center=[65, 50],

    rosetype="radius",

    )

    pie.render()

    词云

    这个是我在前面的文章中用到的图片实例,这里就不 po 具体数据了。

    from pyecharts import WordCloud

    name = ['Sam S Club'] # 词条

    value = [10000] # 权重

    wordcloud = WordCloud(width=1300, height=620)

    wordcloud.add("", name, value, word_size_range=[20, 100])

    wordcloud.render()

    树图

    这个是我在前面的文章中用到的图片实例,这里就不 po 具体数据了。

    from pyecharts import TreeMap

    data = [ # 键值对数据结构

    {

    value: 1212, # 数值

    # 子节点

    children: [

    {

    # 子节点数值

    value: 2323,

    # 子节点名

    name: 'description of this node',

    children: [...],

    },

    {

    value: 4545,

    name: 'description of this node',

    children: [

    {

    value: 5656,

    name: 'description of this node',

    children: [...]

    },

    ...

    ]

    }

    ]

    },

    ...

    ]

    treemap = TreeMap(title, width=1200, height=600) # 设置标题与宽高

    treemap.add("深圳", data, is_label_show=True, label_pos='inside', label_text_size=19)

    treemap.render()

    地图

    from pyecharts import Map

    value = [155, 10, 66, 78, 33, 80, 190, 53, 49.6]

    attr = [

    "福建", "山东", "北京", "上海", "甘肃", "新疆", "河南", "广西", "西藏"

    ]

    map = Map("Map 结合 VisualMap 示例", width=1200, height=600)

    map.add(

    "",

    attr,

    value,

    maptype="china",

    is_visualmap=True,

    visual_text_color="#000",

    )

    map.render()

    3D 散点图

    from pyecharts import Scatter3D

    import random

    data = [

    [random.randint(0, 100),

    random.randint(0, 100),

    random.randint(0, 100)] for _ in range(80)

    ]

    range_color = [

    '#313695', '#4575b4', '#74add1', '#abd9e9', '#e0f3f8', '#ffffbf',

    '#fee090', '#fdae61', '#f46d43', '#d73027', '#a50026']

    scatter3D = Scatter3D("3D 散点图示例", width=1200, height=600) # 配置宽高

    scatter3D.add("", data, is_visualmap=True, visual_range_color=range_color) # 设置颜色等

    scatter3D.render() # 渲染

    后记

    大概介绍就是这样了,三个库的功能都挺强大的,Bokeh 的中文资料会少一点,如果阅读英文有点难度,还是建议使用 pyecharts 就好。总体也不是很难,按照文档来修改数据都能够直接上手使用。主要是多练习。

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