# **【Python 視覺化 : Matplotlib (Seaborn)、Plotly】** :::info - 前兩篇[【Python 資料處理_1 : NumPy】🔗](https://hackmd.io/@workcata/HJZIGYnJp) - 前一篇[【Python 資料處理_2 : Pandas、實例應用】🔗](https://hackmd.io/@workcata/r1d6fSZeT) - Matplotlib - 基本介紹 - 繪製基礎圖表 - 創建圖表的三種方式 - 創建子圖的三種方式 - 創建圖中圖的一種方式 - 散佈圖 scatter - 直方圖 hist - 橫條圖 barh (直條圖 bar) - 折線圖 plot - 箱型圖 boxplot - 補充: plt.style.use(' ') - 面積圖 area - 線圖 line - 六邊形圖 hexbin - 密度圖 density、kde - Matplotlib (Seaborn) - 基本介紹 - 創建圖中圖 - 散點圖 scatterplot - 散點圖矩陣 pairplot - 線圖 lineplot - 直方圖 histplot (displot 更靈活) - 條形圖 barplot - 計數圖 countplot - 聯合圖 jointplot - 地毯圖 rugplot 、密度估計圖 kdeplot - 箱型圖 boxplot - 小提琴圖 viplinplot - 帶狀圖 stirplot、swarmplot - 繪製分類數據圖形 catplot - 熱力圖 heatmap - 補充: .set_style(' ') - 數據透視表 pivot_table - 關聯性網格圖 sns.FacetGrid - 線性回歸模型 lmplot - Plotly - 初始化 - 散佈圖 scatter - 直方圖 histplot - 分布圖 distplot - 直條圖 barplot - 橫條圖 barhplot - 圓餅圖 pie - 箱型圖 boxplot - 3D圖 - 氣泡圖 bubble - 熱力圖 choropleth - 熱力圖 heatmap ::: PS 程式碼後面沒有print()、plt.show()，是因為用jupyter notebook ## Matplotlib ### 基本介紹 > Matplotlib 是Python的數據可視化庫，用於創建各種類型的圖形，折線圖、散點圖、直方圖、條形圖、餅圖... ```= import matplotlib.pyplot as plt %matplotlib inline # 如果用jupyter notebook 要加 ``` - 假設我先創一個x,y ```= import numpy as np x = np.linspace(0,5,11) y = x**2 ``` x 為 array([0. , 0.5, 1. , 1.5, 2. , 2.5, 3. , 3.5, 4. , 4.5, 5. ]) y 為 array(\[ 0. , 0.25, 1. , 2.25, 4. , 6.25, 9. , 12.25, 16. , 20.25, 25. \]) ### 繪製基礎圖表 ```= plt.plot(x,y) plt.show() ```  <br/> ### 創建圖表的三種方式 方法一 ```= plt.figure(figsize=(8, 2), dpi=100) # 先設置畫布 plt.plot(x, y, 'r') # 繪製基礎圖、顏色 plt.plot(x+1, y+1, 'b') plt.xlabel('X Axis Title Here') # 標註 label plt.ylabel('Y Axis Title Here') plt.title('String Title Here') # 標註 title plt.legend(labels=['Line 1', 'Line 2'], loc=1) # 添加圖例，loc=1 在右上角 plt.savefig("filename.png") # 如果要存成檔案 plt.show() ```  <br/> 方法二 ```= fig, axes = plt.subplots(figsize=(8,2), dpi=100) axes.plot(x, y, 'r') axes.plot(x+1, y+1, 'b') axes.set_xlabel('X Axis Title Here') axes.set_ylabel('Y Axis Title Here') axes.set_title('String Title Here') axes.legend(labels=['Line 1', 'Line 2'], loc=1) fig.savefig("filename.png") plt.show() ``` 創建了一個包含軸（axes）的圖表對象(figure)，後面都一樣 plt.figure() 用來創建一個圖，但plt.subplots() 之後可以產成多個子圖  <br/> 方法三 使用【對象導向】方法，明確地創建了圖形對象和軸對象，並通過添加軸來進行繪圖 [0.1, 0.1, 0.8, 0.8] 軸的左邊緣距離圖形左邊緣10％，底邊緣距離圖形底邊緣10％，寬度佔圖形寬度的80％，高度佔圖形高度的80％ ```= fig = plt.figure(figsize=(8, 2), dpi=100) axes = fig.add_axes([0.1, 0.1, 0.8, 0.8]) axes.plot(x, y, 'r') axes.plot(x+1, y+1, 'b') axes.set_xlabel('X Axis Title Here') axes.set_ylabel('Y Axis Title Here') axes.set_title('String Title Here') axes.legend(labels=['Line 1', 'Line 2'], loc=1) fig.savefig("filename.png") plt.show() ```  <br/> ### 創建子圖的三種方式 (改欄/行的數量，就能增加子圖數量) 方法一 使用 plt.figure() 創建圖形，然後使用 plt.subplot() 來創建子圖 plt.subplot() 接受三個參數，(行數, 列數,子圖的索引) ```= plt.figure(figsize=(8, 2), dpi=100) plt.subplot(1,2,1) # (一欄,兩列,第一個圖) plt.plot(x, y, 'r--') plt.plot(x+1, y+1, 'b') plt.xlabel('X1 Axis Title Here') plt.ylabel('Y1 Axis Title Here') plt.title('String Title Here') plt.legend(labels=['Line 1', 'Line 2'], loc=1) plt.subplot(1,2,2) # (一欄,兩列,第二個圖) plt.plot(y, x, 'g*-') plt.plot(y-1, x-1, 'g*-') plt.xlabel('X2 Axis Title Here') plt.ylabel('Y2 Axis Title Here') plt.title('String Title Here') plt.legend(labels=['Line 1', 'Line 2'], loc=1) plt.savefig("filename.png") plt.show() ```  <br/> 方法二 使用 plt.subplots() 創建一個包含兩個子圖的 fig 和 axes（軸）對象陣列 axes 是一個包含兩個軸對象的陣列，分別對應於兩個子圖 ```= fig, axes = plt.subplots(nrows=1, ncols=2,figsize=(8,2), dpi=100) axes[0].plot(x, y, 'r--' ) axes[0].plot(x+1, y-1, 'b--' ) axes[0].set_xlabel('X1 Axis Title Here') axes[0].set_ylabel('Y1 Axis Title Here') axes[0].set_title('String Title Here') axes[0].legend(labels=['Line 1', 'Line 2'], loc=1) axes[1].plot(y, x, 'g*-') axes[1].plot(y-1, x+1, 'g*-') axes[1].set_xlabel('X2 Axis Title Here') axes[1].set_ylabel('Y2 Axis Title Here') axes[1].set_title('String Title Here') axes[1].legend(labels=['Line 1', 'Line 2'], loc=1) fig.savefig("filename.png") plt.show() ```  <br/> 方法三 使用【對象導向】方法，明確地創建了圖形對象和軸對象，並通過添加軸來進行繪圖 ```= fig = plt.figure(figsize=(8, 2), dpi=100) axes1 = fig.add_axes([0.1, 0.1, 0.4, 0.8]) axes1.plot(x, y, 'r') axes1.plot(x+1, y+1, 'b') axes1.set_xlabel('X1 Axis Title Here') axes1.set_ylabel('Y1 Axis Title Here') axes1.set_title('String Title 1') axes2 = fig.add_axes([0.6, 0.1, 0.4, 0.8]) axes2.plot(y, x, 'g*-') axes2.plot(y+1, x+1, 'g*-') axes2.set_xlabel('X2 Axis Title Here') axes2.set_ylabel('Y2 Axis Title Here') axes2.set_title('String Title 2') plt.savefig("filename.png") plt.show() ```  <br/> > 補充 > >import matplotlib.pyplot as plt > >fig, axes = plt.subplots(nrows=1, ncols=3, figsize=(10, 4), dpi=100) > >x = [1, 2, 3, 4, 5] y1 = [1, 4, 9, 16, 25] y2 = [1, 8, 27, 64, 125] y3 = [1, 16, 81, 256, 625] > >for i, ax in enumerate(axes): if i == 0: new_x = [val + 1 for val in x] new_y1 = [val + 3 for val in y1] ax.plot(x, y1, 'r--') ax.plot(new_x, new_y1, 'r--') ax.set_title('Subplot 1') ax.legend(labels=['Line 1', 'Line 2'], loc=1) elif i == 1: ax.plot(x, y2, 'g*-') ax.set_title('Subplot 2') else: ax.plot(x, y3, 'b.-') ax.set_title('Subplot 3') ax.set_xlabel('X_label') ax.set_ylabel('Y_label') > > > #調整子圖距離 plt.tight_layout() > >plt.savefig("filename.png") > >plt.show() > <br/> ### 創建圖中圖的一種方式 先看比較 ```= fig = plt.figure() axes1 = fig.add_axes([0.1, 0.1, 0.8, 0.8]) axes2 = fig.add_axes([0.2, 0.5, 0.4, 0.3]) ```  ```= fig = plt.figure() axes1 = fig.add_axes([0.1, 0.1, 0.8, 0.8]) axes2 = fig.add_axes([0.8, 0.15, 0.4, 0.3]) ```  圖中圖 ```= fig = plt.figure() axes1 = fig.add_axes([0.1, 0.1, 0.8, 0.8]) axes2 = fig.add_axes([0.2, 0.5, 0.4, 0.3]) axes1.plot(x, y, color="r", alpha=0.8, lw=1.5, ls='--', marker='s', markersize=10, markeredgewidth=1.5, markerfacecolor="yellow") # 透明度 0.8, linewidth 1.5, linestyle --, marker 'square', markeredgewidth 標記外框線寬度 # 可以這樣標 ax.plot(x, x+1, color="#8B008B", alpha=0.5) # linestyle 可以換成 ‘-‘, ‘–’, ‘-.’, ‘:’ ... # marker 可以換成 '+', 'o', '*', 's', '^', ',', '.', '1', '2', '3' ... axes1.set_xlabel('X1 Axis Title Here') axes1.set_ylabel('Y1 Axis Title Here') axes1.set_title('String Title Here') axes2.plot(y, x, 'b') axes2.set_xlabel('X2 Axis Title Here') axes2.set_ylabel('Y2 Axis Title Here') axes2.set_title('String Title Here') plt.savefig("filename.png") plt.show() ```  圖中圖練習 ```= fig = plt.figure(figsize=(7,2), dpi=100) ax = fig.add_axes([0, 0, 0.8, 0.8]) ax.plot(x,y, color='purple', lw=4, ls='-.', marker='o', markersize='10', markerfacecolor='yellow', alpha=0.3, label="X Squared") ax.legend(loc=0) ```  ```= fig = plt.figure(figsize=(7,2), dpi=100) ax = fig.add_axes([0, 0, 0.8, 0.8]) ax.plot(x,y, color='purple', lw=4, ls='-.', marker='o', markersize='10', markerfacecolor='yellow', alpha=0.3, label="X Squared") ax.set_xlim([0,1]) # 設置 x 和 y 軸的範圍 ax.set_ylim([0,2]) ```  <br/> ### 散佈圖 scatter ```= plt.scatter(x,y) ```  ```= plt.scatter(x=tips['total_bill'], y=tips['tip']) ```  加上c 分組, s 形狀大小 ```= titanic.plot.scatter(x='fare',y='age',c='survived',cmap='coolwarm') ```  <br/> >https://matplotlib.org/stable/plot_types/index 'default'：默認風格 'classic'：經典風格，類似於 MATLAB 的風格 'ggplot'：仿照 ggplot2 的風格 'seaborn'：仿照 seaborn 的風格 'fivethirtyeight'：仿照 FiveThirtyEight 網站的風格 'bmh'：較簡單的風格，適合科學繪圖 ```= ```= import matplotlib.pyplot as plt import numpy as np plt.style.use('_mpl-gallery') # 使用指定的風格 # 生成資料 np.random.seed(3) x = 4 + np.random.normal(0, 2, 24) y = 4 + np.random.normal(0, 2, len(x)) # 設定點的大小和顏色 sizes = np.random.uniform(15, 80, len(x)) colors = np.random.uniform(15, 80, len(x)) fig, ax = plt.subplots() ax.scatter(x, y, s=sizes, c=colors, vmin=0, vmax=100) ax.set(xlim=(0, 8), xticks=np.arange(1, 8), ylim=(0, 8), yticks=np.arange(1, 8)) # vmin、vmax 顏色映射的範圍 plt.show() ```  帶入鳶尾花數據 ```= import seaborn as sns iris = sns.load_dataset('iris') iris.head() import matplotlib.pyplot as plt plt.scatter(iris['sepal_length'], iris['sepal_width']) plt.xlabel('Sepal Length') plt.ylabel('Sepal Width') plt.show() ```  <br/> ### 直方圖 hist ```= from random import sample data = sample(range(1, 1000), 100) plt.hist(data) plt.xlabel('X Label') plt.ylabel('Frequency') plt.title('Histogram of y') plt.show() ```  <br/> 加上bin，可以控制柱數 ```= from random import sample data = sample(range(1, 1000), 100) plt.hist(data, bins=6) plt.xlabel('X Label') plt.ylabel('Frequency') plt.title('Histogram of y') plt.show() ```  <br/> 加上框線 ```= from random import sample data = sample(range(1, 1000), 100) plt.hist(data, bins=6, edgecolor='black', lw= 0.3) plt.xlabel('X Label') plt.ylabel('Frequency') plt.title('Histogram of y') plt.show() ```  ```= tips['total_bill'].hist(alpha=0.5,bins=25) plt.xlabel('total bill') plt.ylabel('count') ```  帶入鳶尾花數據 ```= import seaborn as sns iris = sns.load_dataset('iris') iris.head() import matplotlib.pyplot as plt plt.hist(iris['sepal_length']) plt.xlabel('Sepal Length') plt.ylabel('Frequency') plt.show() ```  <br/> ### 橫條圖 barh 假設已經有一個確診國家排名前20  ```= plt.figure(figsize=(15,10)) plots = plt.barh(top_20['Country'], top_20['Confirmed'], height=0.5, left=None, align='center', color=['lightsteelblue', 'cornflowerblue', 'royalblue', 'midnightblue', 'navy', 'darkblue', 'mediumblue']) plt.xlabel('Confirmed') plt.ylabel('Country') plt.title('Covid 19 Statics Top 20 Countries') plt.show() ```  ```= top_6_total_bill = tips['total_bill'].value_counts().head(6) top_6_total_bill.plot(kind='barh') ```  PS 改成 plt.bar，就是直條圖 加下面這行，x 軸刻度旋轉 90 度，避免文字重疊 plt.xticks(rotation=90)  ```= plt.bar(x=tips['total_bill'], height=tips['tip']) ```  ```= top_6_total_bill = tips['total_bill'].value_counts().head(6) top_6_total_bill.plot(kind='bar') ```  <br/> ### 折線圖 plot ```= import matplotlib.pyplot as plt plt.style.use('_mpl-gallery') # 使用指定的風格 # 月份 months = ['Jan', 'Feb', 'Mar', 'Apr', 'May', 'Jun'] # 每個月的支出金額 expenses = [1500, 1800, 1200, 2000, 1600, 1900] fig, ax = plt.subplots() ax.plot(months, expenses, marker='o', linestyle='-', linewidth=2.0) ax.set(xlabel='Month', ylabel='Expenses', title='Monthly Expenses') plt.show() ```  ```= import matplotlib.pyplot as plt import numpy as np plt.style.use('_mpl-gallery') # 使用指定的風格 # 生成資料 x = np.linspace(0, 10, 100) y = 4 + 2 * np.sin(2 * x) # 繪製圖表 fig, ax = plt.subplots() ax.plot(x, y, linewidth=2.0) ax.set(xlim=(0, 8), xticks=np.arange(1, 8), ylim=(0, 8), yticks=np.arange(1, 8)) plt.show() ```  <br/> 也可以把表格某欄位設為索引 ```= import pandas as pd # 建立要繪製的 DataFrame data = top_20[['Country', 'Confirmed', 'Active', 'Recovered', 'Deaths']] # 設定 Country 欄位為索引 data = data.set_index('Country') data.plot(kind='line', marker='o') plt.title('COVID-19 Statistics - Top 20 Countries') plt.xlabel('Country') plt.ylabel('Confirmed') plt.show() ```  ```= tips['total_bill'].plot() ```  帶入鳶尾花數據 ```= import seaborn as sns iris = sns.load_dataset('iris') iris.head() import matplotlib.pyplot as plt plt.plot(iris['sepal_length'], label='Sepal Length') plt.plot(iris['sepal_width'], label='Sepal Width') plt.xlabel('Index') plt.ylabel('Value') plt.legend() plt.show() ```  <br/> ### 箱型圖 boxplot ```= data = [np.random.normal(0, std, 100) for std in range(1, 4)] # rectangular box plot boxprops = dict(facecolor='green', color='green') plt.boxplot(data, vert=True, patch_artist=True, boxprops=boxprops) # vert 垂直, patch_artist 填充顏色 plt.xlabel('Data Set') plt.ylabel('Value') plt.title('Box Plot with Green Fill Color') plt.show() ```  ```= plt.boxplot(tips['total_bill']) ```  <br/> ### 補充: plt.style.use(' ') default'、ggplot'、'seaborn'、'fivethirtyeight'、'bmh'、'dark_background' ```= import matplotlib.pyplot as plt plt.style.use('bmh') tips['total_bill'].hist() plt.xlabel('total bill') plt.ylabel('count') ```  <br/> ### 面積圖 area ```= tips_2[['total_bill','tip']][0:30].plot.area(alpha=0.4) ```  <br/> ### 線圖 line ```= tips.plot.line(x='total_bill',y='tip',figsize=(8,3),lw=1) ```  ### 六邊形圖 hexbin ```= tips.plot.hexbin(x='tip',y='total_bill',gridsize=25,cmap='Oranges') ```  <br/> ### 密度圖 density、kde ```= tips.plot.density() ```  ```= tips.plot.kde() ```  ```= tips['total_bill'].plot.kde(lw=5,ls='--') ```  <br/> <br/> ## Matplotlib (Seaborn) ### 基本介紹 > Seaborn 是建立在 Matplotlib 的高級數據可視化庫。簡化創建統計圖形 ```= import seaborn as sns %matplotlib inline # 如果用jupyter notebook 要加 ``` 可以先預設上下文參數 poster 是相對較大的上下文 poster > talk > notebook > paper ```= sns.set_context('poster',font_scale=0.6) ``` <br/> seaborn 我最喜歡的部分! 有提供kaggle比較有熱門的開源資料: iris, tips, titanic, exercise, flights, anscombe, dots 直接抓取，不需要再下載csv :+1: ```= tips = sns.load_dataset('tips') titanic = sns.load_dataset('titanic') flights = sns.load_dataset('flights') ``` <br/> 創建圖中圖 ```= fig = plt.figure(figsize=(6,4)) # 將 axe 新增到實例化後 2×2 的 figure 上，並指定第 1,2,3 個 ax_1 = fig.add_subplot(2, 2, 1) ax_2 = fig.add_subplot(2, 2, 2) ax_3 = fig.add_subplot(2, 2, 3) ```  <br/> 帶入鳶尾花數據 ### 散點圖 scatterplot ```= import seaborn as sns iris = sns.load_dataset('iris') iris.head() sns.scatterplot(x='sepal_length', y='sepal_width', data=iris) plt.show() ```  <br/> ### 散點圖矩陣 pairplot ```= sns.pairplot(tips, hue='sex', palette='coolwarm', diag_kind='auto') # 使用tips數據,'sex' 分組, 調色板 'coolwarm', 對角線上的圖形類型 'auto' ```  diag_kind='auto' ， 可以換成'hist'、'None'、diag_kind='kde' <br/> ### 線圖 lineplot 帶入鳶尾花數據 ```= import seaborn as sns iris = sns.load_dataset('iris') iris.head() sns.lineplot(data=iris[['sepal_length', 'sepal_width']]) plt.show() ```  <br/> ### 直方圖 histplot (displot 更靈活) #### histplot ```= sns.histplot(tips['total_bill'], kde=False) ```  ```= sns.histplot(tips['total_bill'], kde=True,bins=20) ```   帶入鳶尾花數據 ```= import seaborn as sns iris = sns.load_dataset('iris') iris.head() sns.histplot(data=iris, x='sepal_length') plt.show() ``` <br/> #### displot ```= sns.displot(tips['total_bill'], kde=True,bins=20) ```  PS displot 更靈活 加上不同的x軸 ```= sns.displot(data=data, x="total_bill", hue="sex", kde=True, bins=20) ```  多層次直方圖 ```= sns.displot(data=data, x="total_bill", hue="sex", multiple="stack") ```  加上時間序列，可以做直方圖 ```= time_data = sns.load_dataset("flights") sns.displot(data=time_data, x="year", binwidth=5) ```  也可以做 ```= sns.displot(data=data, x="total_bill", y="tip", kind="kde") ```  ```= sns.displot(data=data, x="total_bill", y="tip", kind="hist") ```  <br/> ### 條形圖 barplot ```= # estimator 默認: 平均值，可換 mean、max、min sns.barplot(x='sex',y='total_bill',data=tips,estimator=np.std) ```  <br/> ### 計數圖 countplot ```= sns.countplot(x='sex',data=tips) ```  <br/> ### 聯合圖 jointplot 直條 + 散點圖 ```= sns.jointplot(x='total_bill',y='tip',data=tips,kind='scatter') ```  直條 + 六邊形圖 ```= sns.jointplot(x='total_bill',y='tip',data=tips,kind='hex') ```  直條 + 密度圖 ```= sns.jointplot(x='total_bill',y='tip',data=tips,kind='kde', fill=True) ```  直條 + 線性迴歸散點圖 ```= sns.jointplot(x='total_bill',y='tip',data=tips,kind='reg') ```  <br/> ### 地毯圖 rugplot 、密度估計圖 kdeplot ```= sns.rugplot(tips['total_bill']) ```  ```= sns.kdeplot(tips['total_bill']) sns.rugplot(tips['total_bill']) ```  <br/> ### 箱型圖 boxplot ```= sns.boxplot(x="day", y="total_bill", data=tips, palette='rainbow') ```  橫向 ```= sns.boxplot(x="total_bill", y="day", data=tips,palette='rainbow',orient='h') ```  hue 分組，類似 pandas groupby ```= sns.boxplot(x="day", y="total_bill", hue="smoker",data=tips, palette="coolwarm") ```  <br/> ### 小提琴圖 viplinplot ```= sns.violinplot(x="day", y="total_bill", data=tips,palette='rainbow') ```  橫向 ```= sns.violinplot(x="total_bill", y="day", data=tips,palette='rainbow',orient='h') ```  hue 分組 ```= sns.violinplot(x="day", y="total_bill", data=tips,hue='sex',palette='Set1') ```  split 切割 ```= sns.violinplot(x="day", y="total_bill", data=tips, hue='sex', split=True, palette='Set1') ```  <br/> ### 帶狀圖 stirplot、swarmplot 點有可能重疊 ```= sns.stripplot(x="day", y="total_bill", data=tips, dodge=True, hue='sex',palette='Set1') ```  點有可能重疊，hue 分組 ```= sns.stripplot(x="day", y="total_bill", data=tips, dodge=False, hue='sex', palette='Set1') ```  點不會重疊 ```= sns.swarmplot(x="day", y="total_bill", hue='sex', data=tips, palette="Set1", dodge=True) ```  點不會重疊，hue 分組 ```= sns.swarmplot(x="day", y="total_bill", hue='sex', data=tips, palette="Set1", dodge=False) ```  <br/> PS 混和 ```= sns.violinplot(x="tip", y="day", data=tips,palette='rainbow') sns.swarmplot(x="tip", y="day", data=tips,color='black',size=3) ```  <br/> ### 繪製分類數據圖形 catplot 可替換 bar - 長條圖 point - 散點圖 strip - 長條圖 box - 箱形圖 violin - 小提琴圖 swarm - 蜂群圖 boxen - 箱型圖與蜂群圖組合 pointplot - 點圖 ```= sns.catplot(x="sex", y="total_bill", data=tips, kind="box") ```  ```= sns.catplot(x="sex", y="total_bill", data=tips, kind="boxen") ```  <br/> ### 熱力圖 heatmap ```= sns.heatmap(tips.corr()) ``` PS 如果有不能計算的欄位，先轉換為數字 ```= tips['sex'] = tips['sex'].map({'Female': 0, 'Male': 1}) tips['smoker'] = tips['smoker'].map({'No': 0, 'Yes': 1}) day_mapping = {'Thur': 1, 'Fri': 2, 'Sat': 3, 'Sun': 4} tips['day'] = tips['day'].map(day_mapping) time_mapping = {'Lunch': 1, 'Dinner': 2} tips['time'] = tips['time'].map(time_mapping) ```  或是只看數字欄位 ```= tips_2 = tips[['total_bill', 'tip', 'size']] sns.heatmap(tips_2.corr()) ```  加上 相關性係數的標籤 ```= sns.heatmap(tips_2.corr(),cmap='coolwarm',annot=True) ```  <br/> ### 補充: .set_style(' ') ```= sns.set_style('white') sns.countplot(x='sex',data=tips) ```  圖的四個邊緣，添加座標軸刻度線 ```= sns.set_style('ticks') sns.countplot(x='sex',data=tips,palette='deep') ```  .despine() 移除Seaborn繪圖中的上、右邊框線，使得圖形更加清晰 ```= sns.countplot(x='sex',data=tips) sns.despine() # <> sns.despine(left=True) ```  <br/> ### 數據透視表 pivot_table ```= flights.pivot_table(values='passengers',index='month',columns='year') ```  加上熱力圖 ```= pvflights = flights.pivot_table(values='passengers',index='month',columns='year') sns.heatmap(pvflights) ```  ```= # map='magma' 顏色映射 # 'viridis'、'plasma'、'inferno'、'cividis'、'coolwarm'、'RdBu'、'YlGnBu' sns.heatmap(pvflights, cmap='magma',linecolor='white',linewidths=1) ```  <br/> ### 聚類函數 clustermap ```= sns.clustermap(pvflights) ```  ### 關聯性網格圖 sns.FacetGrid ```= g = sns.FacetGrid(tips, col="time", row="smoker") g = g.map(plt.hist, "total_bill") ```  hue 分組 ```= g = sns.FacetGrid(tips, col="time", row="smoker",hue='sex') g = g.map(plt.scatter, "total_bill", "tip") ```  等同sns.jointplot(x='total_bill',y='tip',data=tips,kind='reg') ```= g = sns.JointGrid(x="total_bill", y="tip", data=tips) g = g.plot(sns.regplot, sns.distplot) ``` ### 線性回歸模型 lmplot ```= sns.lmplot(x='total_bill',y='tip',data=tips) ```  hue 分組 ```= sns.lmplot(x='total_bill',y='tip',data=tips,hue='sex',palette='coolwarm') ```  catter_k 散點的大小 100 ```= sns.lmplot(x='total_bill',y='tip',data=tips,hue='sex',palette='seismic', markers=['o','v'],scatter_kws={'s':100}) ```  分組分圖 ```= sns.lmplot(x='total_bill', y='tip', data=tips, col='sex') ```  ```= sns.lmplot(x='total_bill', y='tip', data=tips, row='sex') ```  ```= sns.lmplot(x="total_bill", y="tip", data=tips, row="sex", col="time") ```  ```= sns.lmplot(x='total_bill', y='tip', data=tips, col='day', hue='sex', palette='coolwarm', aspect=0.6, height=8) ```  <br/> ## Plotly ### 初始化 - 參考 https://plotly.com/python/ - 申請api https://chart-studio.plotly.com/settings/api#/ - 先安裝 ```= pip install plotly pip install cufflinks pip install chart_studio ``` - 導入模組 ```= # 離線使用, jupyter notebook 初始化, html file, jupyter notebook 繪圖 from plotly.offline import download_plotlyjs, init_notebook_mode, plot, iplot # Pandas DataFrame 轉為 plotly import cufflinks as cf # 連接Plotly Chart Studio、上傳 Plotly 圖表到 Plotly Chart Studio import chart_studio import chart_studio.plotly as py ``` - 導入api，填入前面申請到的 api key ```= chart_studio.tools.set_credentials_file(username='你的帳號', api_key='your_api_key') ```  - 初始化Plotly以進入離線模式 ```= init_notebook_mode(connected=True) ``` - 先創兩個dataframe df ```= df = pd.DataFrame(np.random.randn(100,4),columns='A B C D'.split()) df ```  df2 ```= df2 = pd.DataFrame({'Category':['A','B','C'],'Values':[32,43,50]}) df2.head() ```  <br/> ### 散佈圖 scatter ```= df.iplot(kind='scatter', x='A', y='B', mode='markers', size=10) ```  ```= import plotly.offline as pyo import plotly.graph_objs as go import numpy as np np.random.seed(50) x_values = np.linspace(0, 1, 100) y_values = np.random.randn(100) trace0 = go.Scatter( x = x_values, y = y_values+5, mode = 'markers', name = 'markers' ) trace1 = go.Scatter( x = x_values, y = y_values, mode = 'lines+markers', name = 'lines+markers' ) trace2 = go.Scatter( x = x_values, y = y_values-5, mode = 'lines', name = 'lines' ) data = [trace0, trace1, trace2] layout = go.Layout( title = 'three different modes of scatter' ) fig = go.Figure(data=data,layout=layout) # pyo.plot(fig, filename='scatter2.html') pyo.iplot(fig) ```  ```= import plotly.offline as pyo import plotly.graph_objs as go import numpy as np np.random.seed(42) random_x = np.random.randint(1,200,100) random_y = np.random.randint(1,300,100) data = [go.Scatter( x = random_x, y = random_y, mode = 'markers', marker=dict( # marker style size = 12, color = 'rgb(50,300,100)', symbol = 'pentagon', line = dict( width = 2, ) ) )] layout = go.Layout( title = 'Random Data Scatterplot', xaxis = dict(title = 'random x-values'), yaxis = dict(title = 'random y-values'), hovermode ='closest' ) fig = go.Figure(data=data, layout=layout) # pyo.plot(fig, filename='scatter2.html') pyo.iplot(fig) ```  <br/> ### 直方圖 hist ```= df['A'].iplot(kind='hist',bins=25) ```  <br/> ### 分布圖 distplot ```= import plotly.offline as pyo import plotly.figure_factory as ff import numpy as np x = np.random.randn(1000) hist_data = [x] group_labels = ['distplot'] fig = ff.create_distplot(hist_data, group_labels) pyo.iplot(fig) ```  ```= import plotly.offline as pyo import plotly.figure_factory as ff import numpy as np x1 = np.random.randn(200)-2 x2 = np.random.randn(200) x3 = np.random.randn(200)+2 x4 = np.random.randn(200)+4 hist_data = [x1,x2,x3,x4] group_labels = ['Group1','Group2','Group3','Group4'] fig = ff.create_distplot(hist_data, group_labels) pyo.iplot(fig) ```  ```= import plotly.offline as pyo import plotly.figure_factory as ff snodgrass = [.209,.205,.196,.210,.202,.207,.224,.223,.220,.201] twain = [.225,.262,.217,.240,.230,.229,.235,.217] hist_data = [snodgrass,twain] group_labels = ['Snodgrass','Twain'] fig = ff.create_distplot(hist_data, group_labels, bin_size=[.005,.005]) pyo.iplot(fig) ```  <br/> ### 直條圖 barplot ```= df2.iplot(kind='bar',x='Category',y='Values') ```  <br/> ### 橫條圖 barhplot ```= df2.iplot(kind='barh', x='Category', y='Values') ```  ```= import plotly.graph_objs as go import plotly.offline as pyo data = [go.Bar( x=titanic['alive'].value_counts().index, y=titanic['alive'].value_counts().values, marker=dict(color='blue') )] layout = go.Layout( title='Survival Count', xaxis=dict(title='Survived'), yaxis=dict(title='Count') ) fig = go.Figure(data=data, layout=layout) pyo.iplot(fig) ```  ```= total_count = len(titanic) titanic['no_survived'] = total_count - df['survived'] trace1 = go.Bar( x=df['sex'], y=df['survived'], name='Survived', marker=dict(color='#FFD700') ) trace2 = go.Bar( x=df['sex'], y=df['no_survived'], name='Not Survived', marker=dict(color='#9EA0A1') ) data = [trace1, trace2] layout = go.Layout( title='Survival by Gender' ) fig = go.Figure(data=data, layout=layout) pyo.iplot(fig) ```  ```= total_count = len(titanic) titanic['no_survived'] = total_count - df['survived'] trace1 = go.Bar( x=df['sex'], y=df['survived'], name='Survived', marker=dict(color='#FFD700') ) trace2 = go.Bar( x=df['sex'], y=df['no_survived'], name='Not Survived', marker=dict(color='#9EA0A1') ) data = [trace1, trace2] layout = go.Layout( title='Survival by Gender', barmode='stack' # 堆叠 ) fig = go.Figure(data=data, layout=layout) pyo.iplot(fig) ```  <br/> ### 圓餅圖 pie ```= import plotly.express as px import pandas as pd # 建立交叉表，計算不同性別和生存狀態的人數 cross_tab = pd.crosstab(titanic['sex'], titanic['alive']) # 重命名列 cross_tab.columns = ['Not Survived', 'Survived'] # 指定順序、顏色 cross_tab['color'] = ['female', 'male'] colors = ['red', 'blue'] fig1 = px.pie( values=cross_tab['Survived'], names=cross_tab.index, title='Survival by Gender', color=cross_tab['color'], color_discrete_sequence=colors ) fig2 = px.pie( values=cross_tab['Not Survived'], names=cross_tab.index, title='Not Survival by Gender', color=cross_tab['color'], color_discrete_sequence=colors ) fig1.show() fig2.show() ```  <br/> ### 箱型圖 boxplot ```= df.iplot(kind='box') ```  ```= import plotly.offline as pyo import plotly.graph_objs as go snodgrass = [.209,.205,.196,.210,.202,.207,.224,.223,.220,.201] twain = [.225,.262,.217,.240,.230,.229,.235,.217] data = [ go.Box( y=snodgrass, name='QCS' ), go.Box( y=twain, name='MT' ) ] layout = go.Layout( title = '' ) fig = go.Figure(data=data, layout=layout) pyo.iplot(fig) ```  <br/> ### 3D圖 ```= df3 = pd.DataFrame({'x':[1,2,3,4,5],'y':[10,20,30,20,10],'z':[5,4,3,2,1]}) df3.iplot(kind='surface',colorscale='rdylbu') ```  <br/> ### 氣泡圖 bubble ```= df.iplot(kind='bubble',x='A',y='B',size='C') ```  <br/> ### 熱力圖 choropleth ```= import chart_studio.plotly as py import plotly.graph_objs as go from plotly.offline import download_plotlyjs, init_notebook_mode, plot, iplot init_notebook_mode(connected=True) data = dict(type = 'choropleth', locations = ['AZ','CA','NY'], locationmode = 'USA-states', colorscale= 'Portland', text= ['text1','text2','text3'], z=[1.0,2.0,3.0], colorbar = {'title':'Colorbar Title'}) ``` ```= layout = dict(geo = {'scope':'usa'}) choromap = go.Figure(data = [data],layout = layout) iplot(choromap) ```  假設有一個df  ```= data = dict( type = 'choropleth', colorscale = 'viridis', locations = df['CODE'], z = df['GDP (BILLIONS)'], text = df['COUNTRY'], colorbar = {'title' : 'GDP Billions US'}, ) layout = dict( title = '2014 Global GDP', geo = dict( scope='world', showframe = False, projection = {'type':'stereographic'} # 類型可換 https://plotly.com/python/reference/ ) ) choromap = go.Figure(data = [data],layout = layout) iplot(choromap) ```  <br/> ### 熱力圖 heatmap ```= import plotly.offline as pyo import plotly.graph_objs as go import pandas as pd import numpy as np np.random.seed(42) days = ['Monday', 'Tuesday', 'Wednesday', 'Thursday', 'Friday', 'Saturday', 'Sunday'] times = [f'{i:02d}:00' for i in range(24)] data = { 'DAY': np.random.choice(days, size=100), 'LST_TIME': np.random.choice(times, size=100), 'T_HR_AVG': np.random.uniform(60, 90, size=100) } df = pd.DataFrame(data) heatmap_data = [go.Heatmap( x=df['DAY'], y=df['LST_TIME'], z=df['T_HR_AVG'], colorscale='Jet' )] layout = go.Layout( title='Hourly Temperatures, June 1-7, 2010 in<br>\ Santa Barbara, CA USA' ) fig = go.Figure(data=heatmap_data, layout=layout) pyo.iplot(fig) ```  PS 假設要顯示不同地區的檔案   ```= import plotly.offline as pyo import plotly.graph_objs as go import pandas as pd df = sns.load_dataset('flights') data = [go.Heatmap( x=df['month'], y=df['year'], z=df['passengers'] )] layout = go.Layout( title='Flights' ) fig = go.Figure(data=data, layout=layout) pyo.iplot(fig) ```