diff --git a/02_activities/assignments/assignment_1.ipynb b/02_activities/assignments/assignment_1.ipynb index 593bceaed..2a96de55c 100644 --- a/02_activities/assignments/assignment_1.ipynb +++ b/02_activities/assignments/assignment_1.ipynb @@ -34,7 +34,7 @@ }, { "cell_type": "code", - "execution_count": null, + "execution_count": 1, "id": "4a3485d6-ba58-4660-a983-5680821c5719", "metadata": {}, "outputs": [], @@ -56,10 +56,288 @@ }, { "cell_type": "code", - "execution_count": null, + "execution_count": 2, "id": "a431d282-f9ca-4d5d-8912-71ffc9d8ea19", "metadata": {}, - "outputs": [], + "outputs": [ + { + "data": { + "text/html": [ + "
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178 rows × 14 columns

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" + ], + "text/plain": [ + " alcohol malic_acid ash alcalinity_of_ash magnesium total_phenols \\\n", + "0 14.23 1.71 2.43 15.6 127.0 2.80 \n", + "1 13.20 1.78 2.14 11.2 100.0 2.65 \n", + "2 13.16 2.36 2.67 18.6 101.0 2.80 \n", + "3 14.37 1.95 2.50 16.8 113.0 3.85 \n", + "4 13.24 2.59 2.87 21.0 118.0 2.80 \n", + ".. ... ... ... ... ... ... \n", + "173 13.71 5.65 2.45 20.5 95.0 1.68 \n", + "174 13.40 3.91 2.48 23.0 102.0 1.80 \n", + "175 13.27 4.28 2.26 20.0 120.0 1.59 \n", + "176 13.17 2.59 2.37 20.0 120.0 1.65 \n", + "177 14.13 4.10 2.74 24.5 96.0 2.05 \n", + "\n", + " flavanoids nonflavanoid_phenols proanthocyanins color_intensity hue \\\n", + "0 3.06 0.28 2.29 5.64 1.04 \n", + "1 2.76 0.26 1.28 4.38 1.05 \n", + "2 3.24 0.30 2.81 5.68 1.03 \n", + "3 3.49 0.24 2.18 7.80 0.86 \n", + "4 2.69 0.39 1.82 4.32 1.04 \n", + ".. ... ... ... ... ... \n", + "173 0.61 0.52 1.06 7.70 0.64 \n", + "174 0.75 0.43 1.41 7.30 0.70 \n", + "175 0.69 0.43 1.35 10.20 0.59 \n", + "176 0.68 0.53 1.46 9.30 0.60 \n", + "177 0.76 0.56 1.35 9.20 0.61 \n", + "\n", + " od280/od315_of_diluted_wines proline class \n", + "0 3.92 1065.0 0 \n", + "1 3.40 1050.0 0 \n", + "2 3.17 1185.0 0 \n", + "3 3.45 1480.0 0 \n", + "4 2.93 735.0 0 \n", + ".. ... ... ... \n", + "173 1.74 740.0 2 \n", + "174 1.56 750.0 2 \n", + "175 1.56 835.0 2 \n", + "176 1.62 840.0 2 \n", + "177 1.60 560.0 2 \n", + "\n", + "[178 rows x 14 columns]" + ] + }, + "execution_count": 2, + "metadata": {}, + "output_type": "execute_result" + } + ], "source": [ "from sklearn.datasets import load_wine\n", "\n", @@ -91,12 +369,25 @@ }, { "cell_type": "code", - "execution_count": null, + "execution_count": 9, "id": "56916892", "metadata": {}, - "outputs": [], + "outputs": [ + { + "data": { + "text/plain": [ + "178" + ] + }, + "execution_count": 9, + "metadata": {}, + "output_type": "execute_result" + } + ], "source": [ - "# Your answer here" + "# Your answer here\n", + "wine_df.shape[0]\n", + "# The data set contains 178 rows" ] }, { @@ -109,12 +400,25 @@ }, { "cell_type": "code", - "execution_count": null, + "execution_count": 10, "id": "df0ef103", "metadata": {}, - "outputs": [], + "outputs": [ + { + "data": { + "text/plain": [ + "14" + ] + }, + "execution_count": 10, + "metadata": {}, + "output_type": "execute_result" + } + ], "source": [ - "# Your answer here" + "# Your answer here\n", + "wine_df.shape[1]\n", + "# the data set contains 14 columns" ] }, { @@ -127,12 +431,24 @@ }, { "cell_type": "code", - "execution_count": null, + "execution_count": 17, "id": "47989426", "metadata": {}, - "outputs": [], + "outputs": [ + { + "data": { + "text/plain": [ + "(dtype('int32'), array([0, 1, 2]))" + ] + }, + "execution_count": 17, + "metadata": {}, + "output_type": "execute_result" + } + ], "source": [ - "# Your answer here" + "# Your answer here\n", + "wine_df['class'].dtype, wine_df['class'].unique()" ] }, { @@ -146,12 +462,25 @@ }, { "cell_type": "code", - "execution_count": null, + "execution_count": 19, "id": "bd7b0910", "metadata": {}, - "outputs": [], + "outputs": [ + { + "data": { + "text/plain": [ + "13" + ] + }, + "execution_count": 19, + "metadata": {}, + "output_type": "execute_result" + } + ], "source": [ - "# Your answer here" + "# Your answer here\n", + "len(wine_df.columns) - 1\n", + "#There are 13 predictor variables" ] }, { @@ -175,10 +504,37 @@ }, { "cell_type": "code", - "execution_count": null, + "execution_count": 21, "id": "cc899b59", "metadata": {}, - "outputs": [], + "outputs": [ + { + "name": "stdout", + "output_type": "stream", + "text": [ + " alcohol malic_acid ash alcalinity_of_ash magnesium \\\n", + "0 1.518613 -0.562250 0.232053 -1.169593 1.913905 \n", + "1 0.246290 -0.499413 -0.827996 -2.490847 0.018145 \n", + "2 0.196879 0.021231 1.109334 -0.268738 0.088358 \n", + "3 1.691550 -0.346811 0.487926 -0.809251 0.930918 \n", + "4 0.295700 0.227694 1.840403 0.451946 1.281985 \n", + "\n", + " total_phenols flavanoids nonflavanoid_phenols proanthocyanins \\\n", + "0 0.808997 1.034819 -0.659563 1.224884 \n", + "1 0.568648 0.733629 -0.820719 -0.544721 \n", + "2 0.808997 1.215533 -0.498407 2.135968 \n", + "3 2.491446 1.466525 -0.981875 1.032155 \n", + "4 0.808997 0.663351 0.226796 0.401404 \n", + "\n", + " color_intensity hue od280/od315_of_diluted_wines proline \n", + "0 0.251717 0.362177 1.847920 1.013009 \n", + "1 -0.293321 0.406051 1.113449 0.965242 \n", + "2 0.269020 0.318304 0.788587 1.395148 \n", + "3 1.186068 -0.427544 1.184071 2.334574 \n", + "4 -0.319276 0.362177 0.449601 -0.037874 \n" + ] + } + ], "source": [ "# Select predictors (excluding the last column)\n", "predictors = wine_df.iloc[:, :-1]\n", @@ -204,7 +560,7 @@ "id": "403ef0bb", "metadata": {}, "source": [ - "> Your answer here..." + "> Standardization allows the model to consider each variable equally based on its relationship to the outcome rather than its scale." ] }, { @@ -220,7 +576,7 @@ "id": "fdee5a15", "metadata": {}, "source": [ - "> Your answer here..." + "> Since distances are computed solely between predictor variables, standardizing the response variable is generally unnecessary. Doing so could complicate result interpretation without offering meaningful advantages." ] }, { @@ -231,12 +587,22 @@ "(iii) A second essential step is to set a random seed. Do so below (Hint: use the random.seed function). Why is setting a seed important? Is the particular seed value important? Why or why not?" ] }, + { + "cell_type": "code", + "execution_count": null, + "id": "c0d29332", + "metadata": {}, + "outputs": [], + "source": [ + "np.random.seed(43)\n" + ] + }, { "cell_type": "markdown", "id": "f0676c21", "metadata": {}, "source": [ - "> Your answer here..." + "Setting a seed is important because it ensures consistent results when running code involving randomness, such as data splitting or model training. While the specific seed value usually doesn't matter, using a fixed value helps maintain reproducibility and allows for easier comparison of experiments." ] }, { @@ -251,7 +617,7 @@ }, { "cell_type": "code", - "execution_count": null, + "execution_count": 26, "id": "72c101f2", "metadata": {}, "outputs": [], @@ -282,12 +648,27 @@ }, { "cell_type": "code", - "execution_count": null, + "execution_count": 29, "id": "08818c64", "metadata": {}, - "outputs": [], + "outputs": [ + { + "data": { + "text/plain": [ + "8" + ] + }, + "execution_count": 29, + "metadata": {}, + "output_type": "execute_result" + } + ], "source": [ - "# Your code here..." + "knn = KNeighborsClassifier()\n", + "param_grid = {'n_neighbors': np.arange(1, 51)}\n", + "grid_search = GridSearchCV(knn, param_grid, cv=10)\n", + "grid_search.fit(train_predictors, train_response)\n", + "grid_search.best_params_['n_neighbors']\n" ] }, { @@ -303,12 +684,26 @@ }, { "cell_type": "code", - "execution_count": null, + "execution_count": 32, "id": "ffefa9f2", "metadata": {}, - "outputs": [], + "outputs": [ + { + "data": { + "text/plain": [ + "0.9473684210526315" + ] + }, + "execution_count": 32, + "metadata": {}, + "output_type": "execute_result" + } + ], "source": [ - "# Your code here..." + "best_knn = KNeighborsClassifier(n_neighbors=grid_search.best_params_['n_neighbors'])\n", + "best_knn.fit(train_predictors, train_response)\n", + "accuracy = accuracy_score(test_response, best_knn.predict(test_predictors)) \n", + "accuracy" ] }, { @@ -363,7 +758,7 @@ ], "metadata": { "kernelspec": { - "display_name": "Python 3.10.4", + "display_name": "dsi_participant", "language": "python", "name": "python3" }, @@ -377,12 +772,7 @@ "name": "python", "nbconvert_exporter": "python", "pygments_lexer": "ipython3", - "version": "3.9.19" - }, - "vscode": { - "interpreter": { - "hash": "497a84dc8fec8cf8d24e7e87b6d954c9a18a327edc66feb9b9ea7e9e72cc5c7e" - } + "version": "3.9.15" } }, "nbformat": 4,