{ "cells": [ { "cell_type": "markdown", "metadata": {}, "source": [ "# Support Vector Machine practice notebook with breast cancer data set\n", "\n", "In machine learning, support vector machines (SVMs, also support vector networks) are supervised learning models with associated learning algorithms that analyze data used for classification and regression analysis. Given a set of training examples, each marked as belonging to one or the other of two categories, an SVM training algorithm builds a model that assigns new examples to one category or the other, making it a **non-probabilistic binary linear classifier** (although methods such as Platt scaling exist to use SVM in a probabilistic classification setting). An SVM model is a representation of the examples as points in space, mapped ***so that the examples of the separate categories are divided by a clear gap that is as wide as possible***. New examples are then mapped into that same space and predicted to belong to a category based on which side of the gap they fall. This gap is also called maximum margin and the SVM classifier is called ***maximum margin clasifier***.\n", "\n", "In addition to performing linear classification, SVMs can efficiently perform a non-linear classification using what is called the kernel trick, implicitly mapping their inputs into high-dimensional feature spaces.\n", "![SVM-1](./Images/SVM-1.png)" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "## Import libraries and load data" ] }, { "cell_type": "code", "execution_count": 2, "metadata": { "collapsed": true }, "outputs": [], "source": [ "import pandas as pd\n", "import numpy as np\n", "import matplotlib.pyplot as plt\n", "import seaborn as sns\n", "%matplotlib inline" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "### Get the Data\n", "\n", "We'll use the built in breast cancer dataset from Scikit Learn. Note the load function:" ] }, { "cell_type": "code", "execution_count": 3, "metadata": { "collapsed": true }, "outputs": [], "source": [ "from sklearn.datasets import load_breast_cancer" ] }, { "cell_type": "code", "execution_count": 4, "metadata": { "collapsed": true }, "outputs": [], "source": [ "cancer = load_breast_cancer()" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "**The data set is presented in a dictionary form**" ] }, { "cell_type": "code", "execution_count": 5, "metadata": {}, "outputs": [ { "data": { "text/plain": [ "dict_keys(['data', 'target', 'target_names', 'DESCR', 'feature_names'])" ] }, "execution_count": 5, "metadata": {}, "output_type": "execute_result" } ], "source": [ "cancer.keys()" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "**We can grab information and arrays out of this dictionary to create data frame and understand the features**\n", "\n", "**The description of features are as follows**" ] }, { "cell_type": "code", "execution_count": 7, "metadata": { "scrolled": false }, "outputs": [ { "name": "stdout", "output_type": "stream", "text": [ "Breast Cancer Wisconsin (Diagnostic) Database\n", "=============================================\n", "\n", "Notes\n", "-----\n", "Data Set Characteristics:\n", " :Number of Instances: 569\n", "\n", " :Number of Attributes: 30 numeric, predictive attributes and the class\n", "\n", " :Attribute Information:\n", " - radius (mean of distances from center to points on the perimeter)\n", " - texture (standard deviation of gray-scale values)\n", " - perimeter\n", " - area\n", " - smoothness (local variation in radius lengths)\n", " - compactness (perimeter^2 / area - 1.0)\n", " - concavity (severity of concave portions of the contour)\n", " - concave points (number of concave portions of the contour)\n", " - symmetry \n", " - fractal dimension (\"coastline approximation\" - 1)\n", "\n", " The mean, standard error, and \"worst\" or largest (mean of the three\n", " largest values) of these features were computed for each image,\n", " resulting in 30 features. For instance, field 3 is Mean Radius, field\n", " 13 is Radius SE, field 23 is Worst Radius.\n", "\n", " - class:\n", " - WDBC-Malignant\n", " - WDBC-Benign\n", "\n", " :Summary Statistics:\n", "\n", " ===================================== ====== ======\n", " Min Max\n", " ===================================== ====== ======\n", " radius (mean): 6.981 28.11\n", " texture (mean): 9.71 39.28\n", " perimeter (mean): 43.79 188.5\n", " area (mean): 143.5 2501.0\n", " smoothness (mean): 0.053 0.163\n", " compactness (mean): 0.019 0.345\n", " concavity (mean): 0.0 0.427\n", " concave points (mean): 0.0 0.201\n", " symmetry (mean): 0.106 0.304\n", " fractal dimension (mean): 0.05 0.097\n", " radius (standard error): 0.112 2.873\n", " texture (standard error): 0.36 4.885\n", " perimeter (standard error): 0.757 21.98\n", " area (standard error): 6.802 542.2\n", " smoothness (standard error): 0.002 0.031\n", " compactness (standard error): 0.002 0.135\n", " concavity (standard error): 0.0 0.396\n", " concave points (standard error): 0.0 0.053\n", " symmetry (standard error): 0.008 0.079\n", " fractal dimension (standard error): 0.001 0.03\n", " radius (worst): 7.93 36.04\n", " texture (worst): 12.02 49.54\n", " perimeter (worst): 50.41 251.2\n", " area (worst): 185.2 4254.0\n", " smoothness (worst): 0.071 0.223\n", " compactness (worst): 0.027 1.058\n", " concavity (worst): 0.0 1.252\n", " concave points (worst): 0.0 0.291\n", " symmetry (worst): 0.156 0.664\n", " fractal dimension (worst): 0.055 0.208\n", " ===================================== ====== ======\n", "\n", " :Missing Attribute Values: None\n", "\n", " :Class Distribution: 212 - Malignant, 357 - Benign\n", "\n", " :Creator: Dr. William H. Wolberg, W. Nick Street, Olvi L. Mangasarian\n", "\n", " :Donor: Nick Street\n", "\n", " :Date: November, 1995\n", "\n", "This is a copy of UCI ML Breast Cancer Wisconsin (Diagnostic) datasets.\n", "https://goo.gl/U2Uwz2\n", "\n", "Features are computed from a digitized image of a fine needle\n", "aspirate (FNA) of a breast mass. They describe\n", "characteristics of the cell nuclei present in the image.\n", "\n", "Separating plane described above was obtained using\n", "Multisurface Method-Tree (MSM-T) [K. P. Bennett, \"Decision Tree\n", "Construction Via Linear Programming.\" Proceedings of the 4th\n", "Midwest Artificial Intelligence and Cognitive Science Society,\n", "pp. 97-101, 1992], a classification method which uses linear\n", "programming to construct a decision tree. Relevant features\n", "were selected using an exhaustive search in the space of 1-4\n", "features and 1-3 separating planes.\n", "\n", "The actual linear program used to obtain the separating plane\n", "in the 3-dimensional space is that described in:\n", "[K. P. Bennett and O. L. Mangasarian: \"Robust Linear\n", "Programming Discrimination of Two Linearly Inseparable Sets\",\n", "Optimization Methods and Software 1, 1992, 23-34].\n", "\n", "This database is also available through the UW CS ftp server:\n", "\n", "ftp ftp.cs.wisc.edu\n", "cd math-prog/cpo-dataset/machine-learn/WDBC/\n", "\n", "References\n", "----------\n", " - W.N. Street, W.H. Wolberg and O.L. Mangasarian. Nuclear feature extraction \n", " for breast tumor diagnosis. IS&T/SPIE 1993 International Symposium on \n", " Electronic Imaging: Science and Technology, volume 1905, pages 861-870,\n", " San Jose, CA, 1993.\n", " - O.L. Mangasarian, W.N. Street and W.H. Wolberg. Breast cancer diagnosis and \n", " prognosis via linear programming. Operations Research, 43(4), pages 570-577, \n", " July-August 1995.\n", " - W.H. Wolberg, W.N. Street, and O.L. Mangasarian. Machine learning techniques\n", " to diagnose breast cancer from fine-needle aspirates. Cancer Letters 77 (1994) \n", " 163-171.\n", "\n" ] } ], "source": [ "print(cancer['DESCR'])" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "**Show the feature names**" ] }, { "cell_type": "code", "execution_count": 8, "metadata": { "scrolled": true }, "outputs": [ { "data": { "text/plain": [ "array(['mean radius', 'mean texture', 'mean perimeter', 'mean area',\n", " 'mean smoothness', 'mean compactness', 'mean concavity',\n", " 'mean concave points', 'mean symmetry', 'mean fractal dimension',\n", " 'radius error', 'texture error', 'perimeter error', 'area error',\n", " 'smoothness error', 'compactness error', 'concavity error',\n", " 'concave points error', 'symmetry error', 'fractal dimension error',\n", " 'worst radius', 'worst texture', 'worst perimeter', 'worst area',\n", " 'worst smoothness', 'worst compactness', 'worst concavity',\n", " 'worst concave points', 'worst symmetry', 'worst fractal dimension'], \n", " dtype='\n", "RangeIndex: 569 entries, 0 to 568\n", "Data columns (total 30 columns):\n", "mean radius 569 non-null float64\n", "mean texture 569 non-null float64\n", "mean perimeter 569 non-null float64\n", "mean area 569 non-null float64\n", "mean smoothness 569 non-null float64\n", "mean compactness 569 non-null float64\n", "mean concavity 569 non-null float64\n", "mean concave points 569 non-null float64\n", "mean symmetry 569 non-null float64\n", "mean fractal dimension 569 non-null float64\n", "radius error 569 non-null float64\n", "texture error 569 non-null float64\n", "perimeter error 569 non-null float64\n", "area error 569 non-null float64\n", "smoothness error 569 non-null float64\n", "compactness error 569 non-null float64\n", "concavity error 569 non-null float64\n", "concave points error 569 non-null float64\n", "symmetry error 569 non-null float64\n", "fractal dimension error 569 non-null float64\n", "worst radius 569 non-null float64\n", "worst texture 569 non-null float64\n", "worst perimeter 569 non-null float64\n", "worst area 569 non-null float64\n", "worst smoothness 569 non-null float64\n", "worst compactness 569 non-null float64\n", "worst concavity 569 non-null float64\n", "worst concave points 569 non-null float64\n", "worst symmetry 569 non-null float64\n", "worst fractal dimension 569 non-null float64\n", "dtypes: float64(30)\n", "memory usage: 133.4 KB\n" ] } ], "source": [ "df = pd.DataFrame(cancer['data'],columns=cancer['feature_names'])\n", "df.info()" ] }, { "cell_type": "code", "execution_count": 24, "metadata": {}, "outputs": [ { "data": { "text/html": [ "
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mean radiusmean texturemean perimetermean areamean smoothnessmean compactnessmean concavitymean concave pointsmean symmetrymean fractal dimension...worst radiusworst textureworst perimeterworst areaworst smoothnessworst compactnessworst concavityworst concave pointsworst symmetryworst fractal dimension
count569.000000569.000000569.000000569.000000569.000000569.000000569.000000569.000000569.000000569.000000...569.000000569.000000569.000000569.000000569.000000569.000000569.000000569.000000569.000000569.000000
mean14.12729219.28964991.969033654.8891040.0963600.1043410.0887990.0489190.1811620.062798...16.26919025.677223107.261213880.5831280.1323690.2542650.2721880.1146060.2900760.083946
std3.5240494.30103624.298981351.9141290.0140640.0528130.0797200.0388030.0274140.007060...4.8332426.14625833.602542569.3569930.0228320.1573360.2086240.0657320.0618670.018061
min6.9810009.71000043.790000143.5000000.0526300.0193800.0000000.0000000.1060000.049960...7.93000012.02000050.410000185.2000000.0711700.0272900.0000000.0000000.1565000.055040
25%11.70000016.17000075.170000420.3000000.0863700.0649200.0295600.0203100.1619000.057700...13.01000021.08000084.110000515.3000000.1166000.1472000.1145000.0649300.2504000.071460
50%13.37000018.84000086.240000551.1000000.0958700.0926300.0615400.0335000.1792000.061540...14.97000025.41000097.660000686.5000000.1313000.2119000.2267000.0999300.2822000.080040
75%15.78000021.800000104.100000782.7000000.1053000.1304000.1307000.0740000.1957000.066120...18.79000029.720000125.4000001084.0000000.1460000.3391000.3829000.1614000.3179000.092080
max28.11000039.280000188.5000002501.0000000.1634000.3454000.4268000.2012000.3040000.097440...36.04000049.540000251.2000004254.0000000.2226001.0580001.2520000.2910000.6638000.207500
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" ], "text/plain": [ " mean radius mean texture mean perimeter mean area \\\n", "count 569.000000 569.000000 569.000000 569.000000 \n", "mean 14.127292 19.289649 91.969033 654.889104 \n", "std 3.524049 4.301036 24.298981 351.914129 \n", "min 6.981000 9.710000 43.790000 143.500000 \n", "25% 11.700000 16.170000 75.170000 420.300000 \n", "50% 13.370000 18.840000 86.240000 551.100000 \n", "75% 15.780000 21.800000 104.100000 782.700000 \n", "max 28.110000 39.280000 188.500000 2501.000000 \n", "\n", " mean smoothness mean compactness mean concavity mean concave points \\\n", "count 569.000000 569.000000 569.000000 569.000000 \n", "mean 0.096360 0.104341 0.088799 0.048919 \n", "std 0.014064 0.052813 0.079720 0.038803 \n", "min 0.052630 0.019380 0.000000 0.000000 \n", "25% 0.086370 0.064920 0.029560 0.020310 \n", "50% 0.095870 0.092630 0.061540 0.033500 \n", "75% 0.105300 0.130400 0.130700 0.074000 \n", "max 0.163400 0.345400 0.426800 0.201200 \n", "\n", " mean symmetry mean fractal dimension ... \\\n", "count 569.000000 569.000000 ... \n", "mean 0.181162 0.062798 ... \n", "std 0.027414 0.007060 ... \n", "min 0.106000 0.049960 ... \n", "25% 0.161900 0.057700 ... \n", "50% 0.179200 0.061540 ... \n", "75% 0.195700 0.066120 ... \n", "max 0.304000 0.097440 ... \n", "\n", " worst radius worst texture worst perimeter worst area \\\n", "count 569.000000 569.000000 569.000000 569.000000 \n", "mean 16.269190 25.677223 107.261213 880.583128 \n", "std 4.833242 6.146258 33.602542 569.356993 \n", "min 7.930000 12.020000 50.410000 185.200000 \n", "25% 13.010000 21.080000 84.110000 515.300000 \n", "50% 14.970000 25.410000 97.660000 686.500000 \n", "75% 18.790000 29.720000 125.400000 1084.000000 \n", "max 36.040000 49.540000 251.200000 4254.000000 \n", "\n", " worst smoothness worst compactness worst concavity \\\n", "count 569.000000 569.000000 569.000000 \n", "mean 0.132369 0.254265 0.272188 \n", "std 0.022832 0.157336 0.208624 \n", "min 0.071170 0.027290 0.000000 \n", "25% 0.116600 0.147200 0.114500 \n", "50% 0.131300 0.211900 0.226700 \n", "75% 0.146000 0.339100 0.382900 \n", "max 0.222600 1.058000 1.252000 \n", "\n", " worst concave points worst symmetry worst fractal dimension \n", "count 569.000000 569.000000 569.000000 \n", "mean 0.114606 0.290076 0.083946 \n", "std 0.065732 0.061867 0.018061 \n", "min 0.000000 0.156500 0.055040 \n", "25% 0.064930 0.250400 0.071460 \n", "50% 0.099930 0.282200 0.080040 \n", "75% 0.161400 0.317900 0.092080 \n", "max 0.291000 0.663800 0.207500 \n", "\n", "[8 rows x 30 columns]" ] }, "execution_count": 24, "metadata": {}, "output_type": "execute_result" } ], "source": [ "df.describe()" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "**Is there any missing data?**" ] }, { "cell_type": "code", "execution_count": 25, "metadata": {}, "outputs": [ { "data": { "text/plain": [ "0" ] }, "execution_count": 25, "metadata": {}, "output_type": "execute_result" } ], "source": [ "np.sum(pd.isnull(df).sum()) # Sum of the count of null objects in all columns of data frame" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "**What are the 'target' data in the data set?**" ] }, { "cell_type": "code", "execution_count": 16, "metadata": {}, "outputs": [ { "data": { "text/plain": [ "array([0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 0,\n", " 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 0, 0, 0, 0, 0, 0, 0, 0,\n", " 1, 0, 1, 1, 1, 1, 1, 0, 0, 1, 0, 0, 1, 1, 1, 1, 0, 1, 0, 0, 1, 1, 1,\n", " 1, 0, 1, 0, 0, 1, 0, 1, 0, 0, 1, 1, 1, 0, 0, 1, 0, 0, 0, 1, 1, 1, 0,\n", " 1, 1, 0, 0, 1, 1, 1, 0, 0, 1, 1, 1, 1, 0, 1, 1, 0, 1, 1, 1, 1, 1, 1,\n", " 1, 1, 0, 0, 0, 1, 0, 0, 1, 1, 1, 0, 0, 1, 0, 1, 0, 0, 1, 0, 0, 1, 1,\n", " 0, 1, 1, 0, 1, 1, 1, 1, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 1, 1, 1, 1,\n", " 0, 0, 1, 0, 1, 1, 0, 0, 1, 1, 0, 0, 1, 1, 1, 1, 0, 1, 1, 0, 0, 0, 1,\n", " 0, 1, 0, 1, 1, 1, 0, 1, 1, 0, 0, 1, 0, 0, 0, 0, 1, 0, 0, 0, 1, 0, 1,\n", " 0, 1, 1, 0, 1, 0, 0, 0, 0, 1, 1, 0, 0, 1, 1, 1, 0, 1, 1, 1, 1, 1, 0,\n", " 0, 1, 1, 0, 1, 1, 0, 0, 1, 0, 1, 1, 1, 1, 0, 1, 1, 1, 1, 1, 0, 1, 0,\n", " 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 1, 1, 0, 1, 0, 1,\n", " 1, 0, 1, 1, 0, 1, 0, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 1,\n", " 1, 0, 1, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 1, 1, 1, 0,\n", " 1, 0, 1, 1, 1, 1, 0, 0, 0, 1, 1, 1, 1, 0, 1, 0, 1, 0, 1, 1, 1, 0, 1,\n", " 1, 1, 1, 1, 1, 1, 0, 0, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 1,\n", " 0, 0, 0, 1, 0, 0, 1, 1, 1, 1, 1, 0, 1, 1, 1, 1, 1, 0, 1, 1, 1, 0, 1,\n", " 1, 0, 0, 1, 1, 1, 1, 1, 1, 0, 1, 1, 1, 1, 1, 1, 1, 0, 1, 1, 1, 1, 1,\n", " 0, 1, 1, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 1, 0, 0, 1, 0, 1,\n", " 1, 1, 1, 1, 0, 1, 1, 0, 1, 0, 1, 1, 0, 1, 0, 1, 1, 1, 1, 1, 1, 1, 1,\n", " 0, 0, 1, 1, 1, 1, 1, 1, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 1, 1, 1,\n", " 1, 1, 1, 1, 0, 1, 0, 1, 1, 0, 1, 1, 1, 1, 1, 0, 0, 1, 0, 1, 0, 1, 1,\n", " 1, 1, 1, 0, 1, 1, 0, 1, 0, 1, 0, 0, 1, 1, 1, 0, 1, 1, 1, 1, 1, 1, 1,\n", " 1, 1, 1, 1, 0, 1, 0, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1,\n", " 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0, 0, 0, 1])" ] }, "execution_count": 16, "metadata": {}, "output_type": "execute_result" } ], "source": [ "cancer['target']" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "** Adding the target data to the DataFrame**" ] }, { "cell_type": "code", "execution_count": 26, "metadata": { "scrolled": false }, "outputs": [ { "data": { "text/html": [ "
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mean radiusmean texturemean perimetermean areamean smoothnessmean compactnessmean concavitymean concave pointsmean symmetrymean fractal dimension...worst textureworst perimeterworst areaworst smoothnessworst compactnessworst concavityworst concave pointsworst symmetryworst fractal dimensionCancer
017.9910.38122.801001.00.118400.277600.30010.147100.24190.07871...17.33184.602019.00.16220.66560.71190.26540.46010.118900
120.5717.77132.901326.00.084740.078640.08690.070170.18120.05667...23.41158.801956.00.12380.18660.24160.18600.27500.089020
219.6921.25130.001203.00.109600.159900.19740.127900.20690.05999...25.53152.501709.00.14440.42450.45040.24300.36130.087580
311.4220.3877.58386.10.142500.283900.24140.105200.25970.09744...26.5098.87567.70.20980.86630.68690.25750.66380.173000
420.2914.34135.101297.00.100300.132800.19800.104300.18090.05883...16.67152.201575.00.13740.20500.40000.16250.23640.076780
\n", "

5 rows × 31 columns

\n", "
" ], "text/plain": [ " mean radius mean texture mean perimeter mean area mean smoothness \\\n", "0 17.99 10.38 122.80 1001.0 0.11840 \n", "1 20.57 17.77 132.90 1326.0 0.08474 \n", "2 19.69 21.25 130.00 1203.0 0.10960 \n", "3 11.42 20.38 77.58 386.1 0.14250 \n", "4 20.29 14.34 135.10 1297.0 0.10030 \n", "\n", " mean compactness mean concavity mean concave points mean symmetry \\\n", "0 0.27760 0.3001 0.14710 0.2419 \n", "1 0.07864 0.0869 0.07017 0.1812 \n", "2 0.15990 0.1974 0.12790 0.2069 \n", "3 0.28390 0.2414 0.10520 0.2597 \n", "4 0.13280 0.1980 0.10430 0.1809 \n", "\n", " mean fractal dimension ... worst texture worst perimeter worst area \\\n", "0 0.07871 ... 17.33 184.60 2019.0 \n", "1 0.05667 ... 23.41 158.80 1956.0 \n", "2 0.05999 ... 25.53 152.50 1709.0 \n", "3 0.09744 ... 26.50 98.87 567.7 \n", "4 0.05883 ... 16.67 152.20 1575.0 \n", "\n", " worst smoothness worst compactness worst concavity worst concave points \\\n", "0 0.1622 0.6656 0.7119 0.2654 \n", "1 0.1238 0.1866 0.2416 0.1860 \n", "2 0.1444 0.4245 0.4504 0.2430 \n", "3 0.2098 0.8663 0.6869 0.2575 \n", "4 0.1374 0.2050 0.4000 0.1625 \n", "\n", " worst symmetry worst fractal dimension Cancer \n", "0 0.4601 0.11890 0 \n", "1 0.2750 0.08902 0 \n", "2 0.3613 0.08758 0 \n", "3 0.6638 0.17300 0 \n", "4 0.2364 0.07678 0 \n", "\n", "[5 rows x 31 columns]" ] }, "execution_count": 26, "metadata": {}, "output_type": "execute_result" } ], "source": [ "df['Cancer'] = pd.DataFrame(cancer['target'])\n", "df.head()" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "## Exploratory Data Analysis\n" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "### Check the relative counts of benign (0) vs malignant (1) cases of cancer" ] }, { "cell_type": "code", "execution_count": 27, "metadata": {}, "outputs": [ { "data": { "text/plain": [ "" ] }, "execution_count": 27, "metadata": {}, "output_type": "execute_result" }, { "data": { "image/png": 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"text/plain": [ "" ] }, "metadata": {}, "output_type": "display_data" } ], "source": [ "sns.set_style('whitegrid')\n", "sns.countplot(x='Cancer',data=df,palette='RdBu_r')" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "### Run a 'for' loop to draw boxlots of all the mean features (first 10 columns) for '0' and '1' CANCER OUTCOME" ] }, { "cell_type": "code", "execution_count": 30, "metadata": { "scrolled": false }, "outputs": [ { "data": { "image/png": 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Hh0pKSnTZZZcpLy/PiWwAABtZFkC/fv1UWFioq666SmlpaZo7d662bt3qRDYAgI0sC6Bv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\nAGAoCgAADEUBAIChKAAAMBQFAACG+n/1QN1P2m8BXQAAAABJRU5ErkJggg==\n", 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"text/plain": [ "" ] }, "metadata": {}, "output_type": "display_data" }, { "data": { "text/plain": [ "" ] }, "metadata": {}, "output_type": "display_data" } ], "source": [ "l=list(df.columns[0:10])\n", "for i in range(len(l)-1):\n", " sns.boxplot(x='Cancer',y=l[i], data=df, palette='winter')\n", " plt.figure()" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "### Not all the features seperate out the cancer predictions equally clearly\n", "**For example, from the following two plots it is clear that smaller area generally is indicative of positive cancer detection, while nothing concrete can be said from the plot of mean smoothness**" ] }, { "cell_type": "code", "execution_count": 38, "metadata": {}, "outputs": [ { "data": { "text/plain": [ "" ] }, "execution_count": 38, "metadata": {}, "output_type": "execute_result" }, { "data": { "image/png": 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PP/xQfn5+uuGGG/T0008X2XbDhg3l5eWlBQsW6MEHH3St/+CDD+r222/X3Llzi6yzefNm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\n+mt98MEH8vHxUVhYmGbNmiV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"text/plain": [ "" ] }, "metadata": {}, "output_type": "display_data" } ], "source": [ "f,(ax1, ax2) = plt.subplots(1, 2, sharey=True,figsize=(12,6))\n", "ax1.scatter(df['mean area'],df['Cancer'])\n", "ax1.set_title(\"Cancer cases as a function of mean area\", fontsize=15)\n", "ax2.scatter(df['mean smoothness'],df['Cancer'])\n", "ax2.set_title(\"Cancer cases as a function of mean smoothness\", fontsize=15)" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "## Training and prediction" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "### Train Test Split" ] }, { "cell_type": "code", "execution_count": 54, "metadata": {}, "outputs": [ { "data": { "text/html": [ "
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mean radiusmean texturemean perimetermean areamean smoothnessmean compactnessmean concavitymean concave pointsmean symmetrymean fractal dimension...worst radiusworst textureworst perimeterworst areaworst smoothnessworst compactnessworst concavityworst concave pointsworst symmetryworst fractal dimension
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311.4220.3877.58386.10.142500.283900.24140.105200.25970.09744...14.9126.5098.87567.70.20980.86630.68690.25750.66380.17300
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5 rows × 30 columns

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" ], "text/plain": [ " mean radius mean texture mean perimeter mean area mean smoothness \\\n", "0 17.99 10.38 122.80 1001.0 0.11840 \n", "1 20.57 17.77 132.90 1326.0 0.08474 \n", "2 19.69 21.25 130.00 1203.0 0.10960 \n", "3 11.42 20.38 77.58 386.1 0.14250 \n", "4 20.29 14.34 135.10 1297.0 0.10030 \n", "\n", " mean compactness mean concavity mean concave points mean symmetry \\\n", "0 0.27760 0.3001 0.14710 0.2419 \n", "1 0.07864 0.0869 0.07017 0.1812 \n", "2 0.15990 0.1974 0.12790 0.2069 \n", "3 0.28390 0.2414 0.10520 0.2597 \n", "4 0.13280 0.1980 0.10430 0.1809 \n", "\n", " mean fractal dimension ... worst radius \\\n", "0 0.07871 ... 25.38 \n", "1 0.05667 ... 24.99 \n", "2 0.05999 ... 23.57 \n", "3 0.09744 ... 14.91 \n", "4 0.05883 ... 22.54 \n", "\n", " worst texture worst perimeter worst area worst smoothness \\\n", "0 17.33 184.60 2019.0 0.1622 \n", "1 23.41 158.80 1956.0 0.1238 \n", "2 25.53 152.50 1709.0 0.1444 \n", "3 26.50 98.87 567.7 0.2098 \n", "4 16.67 152.20 1575.0 0.1374 \n", "\n", " worst compactness worst concavity worst concave points worst symmetry \\\n", "0 0.6656 0.7119 0.2654 0.4601 \n", "1 0.1866 0.2416 0.1860 0.2750 \n", "2 0.4245 0.4504 0.2430 0.3613 \n", "3 0.8663 0.6869 0.2575 0.6638 \n", "4 0.2050 0.4000 0.1625 0.2364 \n", "\n", " worst fractal dimension \n", "0 0.11890 \n", "1 0.08902 \n", "2 0.08758 \n", "3 0.17300 \n", "4 0.07678 \n", "\n", "[5 rows x 30 columns]" ] }, "execution_count": 54, "metadata": {}, "output_type": "execute_result" } ], "source": [ "df_feat = df.drop('Cancer',axis=1) # Define a dataframe with only features\n", "df_feat.head()" ] }, { "cell_type": "code", "execution_count": 55, "metadata": {}, "outputs": [ { "data": { "text/plain": [ "0 0\n", "1 0\n", "2 0\n", "3 0\n", "4 0\n", "Name: Cancer, dtype: int32" ] }, "execution_count": 55, "metadata": {}, "output_type": "execute_result" } ], "source": [ "df_target = df['Cancer'] # Define a dataframe with only target results i.e. cancer detections\n", "df_target.head()" ] }, { "cell_type": "code", "execution_count": 56, "metadata": { "collapsed": true }, "outputs": [], "source": [ "from sklearn.model_selection import train_test_split" ] }, { "cell_type": "code", "execution_count": 57, "metadata": { "collapsed": true }, "outputs": [], "source": [ "X_train, X_test, y_train, y_test = train_test_split(df_feat, df_target, test_size=0.30, random_state=101)" ] }, { "cell_type": "code", "execution_count": 53, "metadata": {}, "outputs": [ { "data": { "text/plain": [ "178 1\n", "421 1\n", "57 0\n", "514 0\n", "548 1\n", "Name: Cancer, dtype: int32" ] }, "execution_count": 53, "metadata": {}, "output_type": "execute_result" } ], "source": [ "y_train.head()" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "### Train the Support Vector Classifier" ] }, { "cell_type": "code", "execution_count": 58, "metadata": { "collapsed": true }, "outputs": [], "source": [ "from sklearn.svm import SVC" ] }, { "cell_type": "code", "execution_count": 59, "metadata": { "collapsed": true }, "outputs": [], "source": [ "model = SVC()" ] }, { "cell_type": "code", "execution_count": 60, "metadata": {}, "outputs": [ { "data": { "text/plain": [ "SVC(C=1.0, cache_size=200, class_weight=None, coef0=0.0,\n", " decision_function_shape=None, degree=3, gamma='auto', kernel='rbf',\n", " max_iter=-1, probability=False, random_state=None, shrinking=True,\n", " tol=0.001, verbose=False)" ] }, "execution_count": 60, "metadata": {}, "output_type": "execute_result" } ], "source": [ "model.fit(X_train,y_train)" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "### Predictions and Evaluations" ] }, { "cell_type": "code", "execution_count": 61, "metadata": { "collapsed": true }, "outputs": [], "source": [ "predictions = model.predict(X_test)" ] }, { "cell_type": "code", "execution_count": 62, "metadata": { "collapsed": true }, "outputs": [], "source": [ "from sklearn.metrics import classification_report,confusion_matrix" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "**Notice that we are classifying everything into a single class! This means our model needs to have it parameters adjusted (it may also help to normalize the data)**" ] }, { "cell_type": "code", "execution_count": 63, "metadata": {}, "outputs": [ { "name": "stdout", "output_type": "stream", "text": [ "[[ 0 66]\n", " [ 0 105]]\n" ] } ], "source": [ "print(confusion_matrix(y_test,predictions))" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "**As expected, the classification report card is bad**" ] }, { "cell_type": "code", "execution_count": 64, "metadata": {}, "outputs": [ { "name": "stdout", "output_type": "stream", "text": [ " precision recall f1-score support\n", "\n", " 0 0.00 0.00 0.00 66\n", " 1 0.61 1.00 0.76 105\n", "\n", "avg / total 0.38 0.61 0.47 171\n", "\n" ] }, { "name": "stderr", "output_type": "stream", "text": [ "C:\\Users\\Tirtha\\Python\\Anaconda3\\lib\\site-packages\\sklearn\\metrics\\classification.py:1113: UndefinedMetricWarning: Precision and F-score are ill-defined and being set to 0.0 in labels with no predicted samples.\n", " 'precision', 'predicted', average, warn_for)\n" ] } ], "source": [ "print(classification_report(y_test,predictions))" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "## Gridsearch\n", "\n", "Finding the right parameters (like what C or gamma values to use) is a tricky task! But luckily, Scikit-learn has the functionality of trying a bunch of combinations and see what works best, built in with GridSearchCV! The CV stands for cross-validation.\n", "\n", "**GridSearchCV takes a dictionary that describes the parameters that should be tried and a model to train. The grid of parameters is defined as a dictionary, where the keys are the parameters and the values are the settings to be tested.** " ] }, { "cell_type": "code", "execution_count": 92, "metadata": { "collapsed": true }, "outputs": [], "source": [ "param_grid = {'C': [0.1,1, 10, 100, 1000], 'gamma': [1,0.1,0.01,0.001,0.0001], 'kernel': ['rbf']} " ] }, { "cell_type": "code", "execution_count": 93, "metadata": { "collapsed": true }, "outputs": [], "source": [ "from sklearn.model_selection import GridSearchCV" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "One of the great things about GridSearchCV is that it is a meta-estimator. It takes an estimator like SVC, and creates a new estimator, that behaves exactly the same - in this case, like a classifier. You should add refit=True and choose verbose to whatever number you want, higher the number, the more verbose (verbose just means the text output describing the process)." ] }, { "cell_type": "code", "execution_count": 94, "metadata": { "collapsed": true }, "outputs": [], "source": [ "grid = GridSearchCV(SVC(),param_grid,refit=True,verbose=1)" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "First, it runs the same loop with cross-validation, to find the best parameter combination. Once it has the best combination, it runs fit again on all data passed to fit (without cross-validation), to built a single new model using the best parameter setting." ] }, { "cell_type": "code", "execution_count": 95, "metadata": {}, "outputs": [ { "name": "stdout", "output_type": "stream", "text": [ "Fitting 3 folds for each of 25 candidates, totalling 75 fits\n" ] }, { "name": "stderr", "output_type": "stream", "text": [ "[Parallel(n_jobs=1)]: Done 75 out of 75 | elapsed: 1.5s finished\n" ] }, { "data": { "text/plain": [ "GridSearchCV(cv=None, error_score='raise',\n", " estimator=SVC(C=1.0, cache_size=200, class_weight=None, coef0=0.0,\n", " decision_function_shape=None, degree=3, gamma='auto', kernel='rbf',\n", " max_iter=-1, probability=False, random_state=None, shrinking=True,\n", " tol=0.001, verbose=False),\n", " fit_params={}, iid=True, n_jobs=1,\n", " param_grid={'C': [0.1, 1, 10, 100, 1000], 'gamma': [1, 0.1, 0.01, 0.001, 0.0001], 'kernel': ['rbf']},\n", " pre_dispatch='2*n_jobs', refit=True, return_train_score=True,\n", " scoring=None, verbose=1)" ] }, "execution_count": 95, "metadata": {}, "output_type": "execute_result" } ], "source": [ "# May take awhile!\n", "grid.fit(X_train,y_train)" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "**You can inspect the best parameters found by GridSearchCV in the best\\_params\\_ attribute, and the best estimator in the best\\_estimator\\_ attribute**" ] }, { "cell_type": "code", "execution_count": 96, "metadata": {}, "outputs": [ { "data": { "text/plain": [ "{'C': 10, 'gamma': 0.0001, 'kernel': 'rbf'}" ] }, "execution_count": 96, "metadata": {}, "output_type": "execute_result" } ], "source": [ "grid.best_params_" ] }, { "cell_type": "code", "execution_count": 97, "metadata": {}, "outputs": [ { "data": { "text/plain": [ "SVC(C=10, cache_size=200, class_weight=None, coef0=0.0,\n", " decision_function_shape=None, degree=3, gamma=0.0001, kernel='rbf',\n", " max_iter=-1, probability=False, random_state=None, shrinking=True,\n", " tol=0.001, verbose=False)" ] }, "execution_count": 97, "metadata": {}, "output_type": "execute_result" } ], "source": [ "grid.best_estimator_" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "**Then you can re-run predictions on this grid object just like you would with a normal model**" ] }, { "cell_type": "code", "execution_count": 98, "metadata": { "collapsed": true }, "outputs": [], "source": [ "grid_predictions = grid.predict(X_test)" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "**Now print the confusion matrix to see improved predictions**" ] }, { "cell_type": "code", "execution_count": 99, "metadata": {}, "outputs": [ { "name": "stdout", "output_type": "stream", "text": [ "[[ 60 6]\n", " [ 3 102]]\n" ] } ], "source": [ "print(confusion_matrix(y_test,grid_predictions))" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "**Classification report shows improved F1-score**" ] }, { "cell_type": "code", "execution_count": 100, "metadata": {}, "outputs": [ { "name": "stdout", "output_type": "stream", "text": [ " precision recall f1-score support\n", "\n", " 0 0.95 0.91 0.93 66\n", " 1 0.94 0.97 0.96 105\n", "\n", "avg / total 0.95 0.95 0.95 171\n", "\n" ] } ], "source": [ "print(classification_report(y_test,grid_predictions))" ] }, { "cell_type": "markdown", "metadata": {}, "source": [ "### Another set of parameters for GridSearch" ] }, { "cell_type": "code", "execution_count": 105, "metadata": {}, "outputs": [ { "name": "stdout", "output_type": "stream", "text": [ "Fitting 3 folds for each of 25 candidates, totalling 75 fits\n" ] }, { "name": "stderr", "output_type": "stream", "text": [ "[Parallel(n_jobs=1)]: Done 75 out of 75 | elapsed: 0.7s finished\n" ] }, { "data": { "text/plain": [ "GridSearchCV(cv=None, error_score='raise',\n", " estimator=SVC(C=1.0, cache_size=200, class_weight=None, coef0=0.0,\n", " decision_function_shape=None, degree=3, gamma='auto', kernel='rbf',\n", " max_iter=-1, probability=False, random_state=None, shrinking=True,\n", " tol=1e-05, verbose=False),\n", " fit_params={}, iid=True, n_jobs=1,\n", " param_grid={'C': [50, 75, 100, 125, 150], 'gamma': [0.01, 0.001, 0.0001, 1e-05, 1e-06], 'kernel': ['rbf']},\n", " pre_dispatch='2*n_jobs', refit=True, return_train_score=True,\n", " scoring=None, verbose=1)" ] }, "execution_count": 105, "metadata": {}, "output_type": "execute_result" } ], "source": [ "param_grid = {'C': [50,75,100,125,150], 'gamma': [1e-2,1e-3,1e-4,1e-5,1e-6], 'kernel': ['rbf']} \n", "grid = GridSearchCV(SVC(tol=1e-5),param_grid,refit=True,verbose=1)\n", "grid.fit(X_train,y_train)" ] }, { "cell_type": "code", "execution_count": 106, "metadata": {}, "outputs": [ { "data": { "text/plain": [ "SVC(C=125, cache_size=200, class_weight=None, coef0=0.0,\n", " decision_function_shape=None, degree=3, gamma=1e-05, kernel='rbf',\n", " max_iter=-1, probability=False, random_state=None, shrinking=True,\n", " tol=1e-05, verbose=False)" ] }, "execution_count": 106, "metadata": {}, "output_type": "execute_result" } ], "source": [ "grid.best_estimator_" ] }, { "cell_type": "code", "execution_count": 107, "metadata": {}, "outputs": [ { "name": "stdout", "output_type": "stream", "text": [ "[[ 60 6]\n", " [ 3 102]]\n" ] } ], "source": [ "grid_predictions = grid.predict(X_test)\n", "print(confusion_matrix(y_test,grid_predictions))" ] } ], "metadata": { "kernelspec": { "display_name": "Python 3", "language": "python", "name": "python3" }, "language_info": { "codemirror_mode": { "name": "ipython", "version": 3 }, "file_extension": ".py", "mimetype": "text/x-python", "name": "python", "nbconvert_exporter": "python", "pygments_lexer": "ipython3", "version": "3.6.2" } }, "nbformat": 4, "nbformat_minor": 1 }