From 78c9fce14d219db6218d7e40773c03b265aad961 Mon Sep 17 00:00:00 2001 From: Nico Theron Date: Thu, 23 May 2019 19:46:36 +0200 Subject: [PATCH] Changes to Section_10_LibreOffice, Section_11_Reading_And_Writing_Data and Section_12_Matrices --- Section_10_LibreOffice.ipynb | 13 +- Section_11_Reading_And_Writing_Data.ipynb | 245 +++++++++++++++++++--- Section_12_Matrices.ipynb | 159 ++++++++++---- 3 files changed, 349 insertions(+), 68 deletions(-) diff --git a/Section_10_LibreOffice.ipynb b/Section_10_LibreOffice.ipynb index b781a94..2e583c3 100644 --- a/Section_10_LibreOffice.ipynb +++ b/Section_10_LibreOffice.ipynb @@ -1,5 +1,14 @@ { "cells": [ + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "# Important notice\n", + "\n", + "Please note that from 2019 LibreOffice is no longer used in the MPR 213 module, which to a large extent makes this file or section irrelevant. The Excel spreadsheet which is used to illustrate all the Excel functions, in 2019, is available on clickUP." + ] + }, { "cell_type": "markdown", "metadata": { @@ -537,7 +546,7 @@ "metadata": { "anaconda-cloud": {}, "kernelspec": { - "display_name": "Python [default]", + "display_name": "Python 3", "language": "python", "name": "python3" }, @@ -551,7 +560,7 @@ "name": "python", "nbconvert_exporter": "python", "pygments_lexer": "ipython3", - "version": "3.5.2" + "version": "3.7.1" } }, "nbformat": 4, diff --git a/Section_11_Reading_And_Writing_Data.ipynb b/Section_11_Reading_And_Writing_Data.ipynb index 1cd2ee3..49dab2d 100644 --- a/Section_11_Reading_And_Writing_Data.ipynb +++ b/Section_11_Reading_And_Writing_Data.ipynb @@ -11,7 +11,7 @@ "# Reading And Writing Data\n", "\n", "- [Overview](#Overview)\n", - "- [Data From LibreOffice](#Data-From-LibreOffice)\n", + "- [Data From Excel](#Data-From-Excel)\n", "- [Data Into Python](#Data-Into-Python)\n", "- [Dictionaries Introduction](#Dictionaries-Introduction)\n", "- [Data From Python](#Data-From-Python)\n" @@ -27,7 +27,7 @@ "source": [ "## Overview\n", "\n", - "- In *LibreOffice* $\\to$ save as `.csv.` or `.xlsx` files\n", + "- In *Excel* $\\to$ save as `.csv` or `.xlsx` files\n", "- In *Python* $\\to$ use the `pandas` module\n", "- Further `pandas` documentation:\n", " - [10 Minutes to Pandas](http://pandas.pydata.org/pandas-docs/stable/10min.html)\n", @@ -44,19 +44,16 @@ "source": [ "## Getting Data In/Out\n", "\n", - "### Data From *LibreOffice*\n", + "### Data From *Excel*\n", "\n", - "- Saving data $\\to$ Save As $\\to$ `ODF Spreadsheet (.ods)`\n", + "- Saving data $\\to$ Save As $\\to$ `xlsx Spreadsheet (.xlsx)`\n", "- Saving data $\\to$ Save As $\\to$ `Text CSV (.csv)`\n", " - Export settings:\n", " - Field delimiter $\\to$ separates data by this character\n", - " - Text delimiter $\\to$ wraps text with this character\n", - " - Quote all text cells $\\to$ adds Text delimiter to text\n", "- Saving data $\\to$ Save As $\\to$ `Microsoft Excel (.xlsx)`\n", - "- `.ods` vs `.csv` vs `.xlsx`\n", - " - `.ods` $\\to$ can't load data with `pandas`\n", + "- `.csv` vs `.xlsx`\n", " - `.csv` $\\to$ raw text data $\\to$ no formula are stored $\\to$ only values stored\n", - " - `.xlsx` $\\to$ similar to `.ods` $\\to$ stored formula and values" + " - `.xlsx` $\\to$ store formula and values" ] }, { @@ -88,20 +85,80 @@ }, { "cell_type": "code", - "execution_count": null, + "execution_count": 1, "metadata": { + "scrolled": false, "slideshow": { "slide_type": "subslide" } }, - "outputs": [], + "outputs": [ + { + "name": "stdout", + "output_type": "stream", + "text": [ + " x coord y coord dist in circle\n", + "0 1.405 -1.217 1.859 True\n", + "1 1.814 -0.096 1.817 True\n", + "2 -0.857 1.391 1.633 True\n", + "3 -0.125 -0.258 0.286 True\n", + "4 1.714 -1.784 2.474 False\n", + "5 0.535 0.609 0.811 True\n", + "6 0.150 0.055 0.160 True\n", + "7 -0.731 1.646 1.801 True\n", + "8 0.205 -1.371 1.387 True\n", + "9 1.096 0.639 1.269 True\n", + "10 -1.733 -1.491 2.286 False\n", + "11 1.287 -1.864 2.265 False\n", + "12 0.548 0.233 0.595 True\n", + "13 -1.293 -1.285 1.823 True\n", + "14 0.335 0.204 0.392 True\n", + "15 -0.574 0.257 0.629 True\n", + "16 -1.296 -0.828 1.538 True\n", + "17 0.560 1.776 1.862 True\n", + "18 0.467 0.668 0.816 True\n", + "19 -1.986 -0.816 2.147 False\n", + "20 1.264 1.437 1.914 True\n", + "21 0.825 -0.538 0.985 True\n", + "22 -0.429 1.559 1.617 True\n", + "23 -0.448 -0.358 0.574 True\n", + "24 0.116 0.126 0.171 True\n", + "25 -1.562 1.086 1.903 True\n", + "26 1.677 -1.561 2.291 False\n", + "27 -0.102 0.235 0.256 True\n", + "28 -1.494 1.144 1.881 True\n", + "29 -0.808 -0.845 1.169 True\n" + ] + }, + { + "data": { + "image/png": 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" + ] + }, + "metadata": {}, + "output_type": "display_data" + } + ], "source": [ "%matplotlib inline\n", "import pandas as pd\n", "from matplotlib import pyplot as plt\n", "\n", - "pdata = pd.read_csv('data_files/darts_data.csv')\n", - "# print(pdata)\n", + "#pdata = pd.read_csv('data_files/darts_data.csv')\n", + "pdata = pd.read_csv('data_files\\darts_data.csv')\n", + "print(pdata)\n", "# print(pdata.index)\n", "# print(pdata.columns)\n", "# print(pdata.values)\n", @@ -119,19 +176,41 @@ }, { "cell_type": "code", - "execution_count": null, + "execution_count": 2, "metadata": { "slideshow": { "slide_type": "subslide" } }, - "outputs": [], + "outputs": [ + { + "data": { + "image/png": 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\n", 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" + ] + }, + "metadata": {}, + "output_type": "display_data" + } + ], "source": [ "%matplotlib inline\n", "import pandas as pd\n", "from matplotlib import pyplot as plt\n", "\n", - "pdata = pd.read_excel('data_files/darts_data.xlsx', sheet_name='Sheet1')\n", + "#pdata = pd.read_excel('data_files/darts_data.xlsx', sheet_name='Sheet1')\n", + "pdata = pd.read_excel('data_files\\darts_data.xlsx', sheet_name='Sheet1')\n", "# print(pdata)\n", "# print(pdata.index)\n", "# print(pdata.columns)\n", @@ -161,9 +240,21 @@ }, { "cell_type": "code", - "execution_count": null, + "execution_count": 3, "metadata": {}, - "outputs": [], + "outputs": [ + { + "name": "stdout", + "output_type": "stream", + "text": [ + "{'x': [2, 5, 1, 0, 9], 'y': [1], 'z': [0, 1, 2], 'name': 'SomeName'}\n", + "[2, 5, 1, 0, 9]\n", + "SomeName\n", + "2\n", + "2\n" + ] + } + ], "source": [ "var = {\n", " 'x': [2, 5, 1, 0, 9],\n", @@ -184,9 +275,19 @@ }, { "cell_type": "code", - "execution_count": null, + "execution_count": 4, "metadata": {}, - "outputs": [], + "outputs": [ + { + "name": "stdout", + "output_type": "stream", + "text": [ + "\n", + "[4 2 5 1]\n", + "[ 8 4 10 2]\n" + ] + } + ], "source": [ "import numpy as np\n", "\n", @@ -219,9 +320,17 @@ }, { "cell_type": "code", - "execution_count": null, + "execution_count": 5, "metadata": {}, - "outputs": [], + "outputs": [ + { + "name": "stdout", + "output_type": "stream", + "text": [ + "180\n" + ] + } + ], "source": [ "atomic_weight = {\n", " 'H': 1,\n", @@ -245,9 +354,17 @@ }, { "cell_type": "code", - "execution_count": null, + "execution_count": 6, "metadata": {}, - "outputs": [], + "outputs": [ + { + "name": "stdout", + "output_type": "stream", + "text": [ + "180\n" + ] + } + ], "source": [ "atomic_weight = {'H': 1, 'C': 12, 'N': 14, 'O': 16, 'S': 32}\n", "\n", @@ -290,7 +407,7 @@ }, { "cell_type": "code", - "execution_count": null, + "execution_count": 7, "metadata": { "slideshow": { "slide_type": "subslide" @@ -343,11 +460,23 @@ }, { "cell_type": "code", - "execution_count": null, + "execution_count": 8, "metadata": {}, - "outputs": [], + "outputs": [ + { + "data": { + "image/png": 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mkYPd82B5klVGozPSce6hUst8baYy30z3Mlx8TsWpG4WXbyQvYSVk5IlSuzLX+n85zZavTv5wo+I4NaBUZd7V1UVHRwe9vb2sW7eO3t5eOjo66OrqqoeauaISn0fwTyzUntH1ViDv1GK4oLjA17MV2SrDTnmhsIqvs7OTvr4+2tvb67q6L09l0cwyD5EWwg9VhlN5fE4lA+UKZSXmVPJU8CuhS7PlSSXIy/3Uag6wFjIa6V4anaxzKt5TcYaE92Tyiz8bJwvVLiduVJwh0WrDCXkaDipXGdTq2bjxamyqXU58or6J8EnJypOcYK93BZqXlVt50cPJJ1U3KpLaJN0m6ap4PUXSnyXdK+liSWOj+/GSVklaHo9PJmQcF8PfK+m4hPt+ku6UdJ+k76uJa9MsBsNfdqdR8AbQQJpltVsteiqfA/oS12cD55rZXsCzQEfC72Izmx6PCwAkTQBOA94GvBU4TdL2MfwPgBOBveJxaFXvpI64wXCaCS/PA8mSJ+WMRh7ytapGRdIk4P1AwUAIOBC4LAZZAMwuI+Y9wPVm9oyZPQtcDxwqaWdgGzP7Y9xC4KcZZDmO4zQseTAa5ah2T+W7wJeAjfF6B+A5M1sfrx8Fdk2E/5CkOyRdJmm36LYr8EgiTCHOrvG82H0Akk6UtFTS0lWrVo3ohpzGIQ9DAU7+qUU5aaWyWDWjIukw4EkzW5Z0TglaMLn/DUw2szcCvyP0YgaLM5is/o5mPzazGWY2Y+LEiZn0dxqfRmjVOfWnFuWklcpiNXsq7wSOkLQS+AVh2Ou7wHaSCkuZJwGPAZjZ02a2Jrr/F7BfPH8UKPRaknEejefF7o7jOE6dqJpRMbNTzGySmU0GjgEWm9lHgF7gqBjsOOAKgDhHUuAINk/uXwscImn7OEF/CHCtmT0OvCjpX+NczccLshzHcZz6UI//qcwFTpZ0H2GOpSe6f1bSXZJuBz4LHA9gZs8AXwP+Eo8zoxvApwmLAO4D7geuqdVNOM1BsyzjdJxKUImvkNbkH/VmdiNwYzx/gLA0uDjMKcApJeLPB+anuC8FplVQVafFqMS/i1ttlwGnOVm0aBFdXV309PQwc+ZMlixZQkdH+MfHUDY49X/UO47jOHR3d9PT08OsWbMYM2YMs2bNoqenh+7u7iHJ8b2/Wgjfsym/+LNx6k1fXx8zZ87s5zZz5kz6+vpKxEjHeyotRCsta2w0/Nk49aZSXyFtaaPiE6yO41SCZqhLKvUV0pYe/vIJVsdxKkEz1CWV+gppy3/5sVZfKKzVF+xaTddyNNv9uq6Vl+G6DvQrkAyjjF9+bOnhL8dxHKc/I53fc6PiOI7jVIxBjYrCB7Z+VytlHMdxnMZmUKNiZhuAVyRtWyN9HMdxnAYmy+qv1cCdkq4HXi44mtlnq6aV4ziO05BkMSpXx8NxHMdxBqWsUTGzBZK2BHY3s3tqoJPjOI7ToJRd/SXpcGA58Nt4PV3SldVWzHHK0Qz/YnacZiPLkuLTCVvVPwdgZsuBKVXUyXEy4ftlOU7+yGJU1pvZ80Vu/hY7juM4A8gyUb9C0rFAm6S9CF9lvLm6ajmO4ziNSJaeSicwFVgDLAJeAP69mko5Th6YMGHCpvmawtzNhAkT6qyVU0uKy4A///JkWf31CtAl6exwaS9WXy3HqT/PPvvsgPmavC4KmDBhAs8++yywWcftt9+eZ555pqrpVCONPFFcBvL6/PNEltVfb5F0J3AH4U+Qt0var/qqOY6TlULllzwKlX8106lGGrXEeyKVJ8vwVw/wGTObbGaTgX8DflJVrVqIZhti8Zc0v9Tq2TRSGWg2I5kHshiVF83spsKFmS0BMg+BxU0pb5N0VbyeIunPku6VdLGksdH9ZEl3S7pD0g2S9kjI2CBpeTyuTLinymokatXCrBWt9pJ6BVqddMrla7M1xspRuN9GKGsljYqkN0t6M3CLpB9JOkDS/pLOB24cQhqfA/oS12cD55rZXsCzQEd0vw2YYWZvBC4DvpWI808zmx6PIzLIaikaqcA1G61mRGtFuXxttsZYORrpfgfrqZwTj+nA3sBphD9CtgNvzyJc0iTg/cAF8VrAgQSjAbAAmA1gZr1xUQDAn4BJZWSXlFUr8tJKbaQC5zhOc1Ny9ZeZzaqA/O8CXwLGx+sdgOfMbH28fhTYNSVeB3BN4nqcpKXAeuAsM7t8CLKQdCJwIsDuu+8+/LspIsvKkEqslmm1FTeO4wydvNQTZZcUS9oO+DgwORm+3Nb3kg4DnjSzZZIOKDinBO23ZlPSR4EZwP4J593N7DFJewKL42q0F8rJSuj6Y+DHEL5RP5jelaYSSxLzsqyxVstWHccZOnmpJ7L8o/43hOGoO4GNQ5D9TuAISe8DxgHbEHou20kaHXsYk4DHChEkHQx0Afub2ZqCu5k9Fn8fkHQj8Cbgl4PJcipPJf63kTRMhfjFhikvLS7HcYZOltVf48zsZDP7iZktKBzlIpnZKWY2KS5DPgZYbGYfAXqBo2Kw44ArACS9CfgRcISZPVmQI2l7SVvE8x0JxupuC7VbqqxKkZc5k1pRi/vNMv9Ti9VDtcIXUQyk2ZY2+0q1/mTpqVwk6VPAVYStWgAws+E2HecCv5D0dcKKr57o/m1ga+DS+AAejiu92oEfSdpIMIJnmdndZWRVhLx0J2tFM91vXu6lkf6VXytq9Wzykk6rlYEsRmUtocLvYvOchQF7Zk3EzG4kLkM2swcIW+kXhzm4RNybgTeU8EuV5TiO00g005BvluGvk4HXxX/UT4lHZoOSV/IyPOIMD39+lceH6upHM/3fKUtP5S7glbKhGoy8DI84w8OfX+VptWGaVqQWPaIsRmUDsFxSL/3nVAZdUuw4TuVopuERp37UojGWZfjrcqCb8GGuZYnDaSB8uGggecmTLHo00/CIk18q8U5k+Z5K2eXDTv7x4aKB5CVP8qKH41SiLGb5R/2DpPxTvRkm65sFO20bOH3bgW5O1SnOe893p9VR8cTcgADSDonLccDRwAQzO7WailWLGTNm2NKlS5E0wCKnTVIOFqYaMhop3UbStdXSTXUrangEt+crnu5Q0xmOjFT/LGGS/hl0ycvzzEO6kpaZ2QzKUNaopEaSlpjZzCFHzAFuVFpT11ZLt5F09TxqjHSzGpUsw19vTlyOImz2OL5EcMdxHKfCNNIQd5YlxeckztcDK4EPV0UbJ5Vajdv7/IBTjmYrI41yPzrjhfRex+n10WcwhjX81cj48Fed42QYC2+mPGqkZ9Nq6WYKU4V5meHEycOzyTr8VdKoSPr4YBHN7KflhOcRNyr51zUvE6yVMIB1rfxyqmte0m0kXfOQbiWMyrw0Z+BwYFczyzJ0ljvcqLSmrq2WbiPp6nnUGI2xERuVIkUEfISw1fzdQLeZ3VE2Yg6ppFHJ8hBrsYwzTy9lrZatNkoe1asyqJauzZRuI+laq3QHK4sVMSqSRgPHA58H/gx808zuKSc0zxSMSjUMQsUe4hDTqWuBy6murZ5uI+na7HmUp/dmJHXaiI2KpH8DPgfcQPgw1kPlhDUCPvzVGrp6L7JxdPU8aox0K2FUNgJPAqvov02LADOzN5YTnkfcqDSHrrXoRebpfmsSp0Yr8/Iy3DecOPVMt5jinaobwajsMVhEa9CeS6salby8yHnOozxX1M3cq2okw1utdDP1rAeRVy1dK2pUmpVWNSp5iePp5jdOq6XbaLqW88uLUWnIZcGO4zh5IU//ypc2D5Ntv/32ddGh6kZFUhuwFPi7mR0maQrwC2ACcCvwMTNbK2kL4KfAfsDTwP82s5VRxilAB+ErlJ81s2uj+6HA94A24AIzO6va9+M4jpOkeAsVSXXZPiXRoyjZy6kFWb78uAlJ20sa6gT954C+xPXZwLlmthfwLMFYEH+fNbPXAefGcEjaBzgGmAocCpwvqS0aq/8HvBfYB5gTwzqO4zh1oqxRkXSjpG0kTQBuB34i6TtZhEuaBLwfuCBeCzgQuCwGWQDMjudHxmui/0Ex/JHAL8xsjZk9CNwHvDUe95nZA2a2ltD7OTKLXo2IpE1Hvbq1TuPj5cipNll6Ktua2QvAB4GfmNl+wMEZ5X8X+BKwMV7vADxnZuvj9aPArvF8V+ARgOj/fAy/yb0oTin3AUg6UdJSSUtXrVqVUfX8YGaburNm1m8ZoeNkxcvR8HBDPDSyGJXRknYmbHd/VVbBkg4DnjSzZUnnlKBWxm+o7gMdzX5sZjPMbMbEiRMH0dpxnEYhWdmPpMIfTIYb4qGTZaL+TOBaYImZ/UXSnsC9GeK9EzhC0vsInyHehtBz2U7S6NgbmQQ8FsM/CuwGPKqwPcy2wDMJ9wLJOKXcnWGSh9UjjlOOSk1K52VyO0+MtA4o21Mxs0vN7I1m9pl4/YCZfShDvFPMbJKZTSZMtC82s48AvcBRMdhxwBXx/Mp4TfRfbOEpXwkcI2mLuHJsL+AW4C/AXpKmSBob07gy0107qXirrH74EIuTBypRB5TsqShsfV/SdJvZZ4ecWmAu8AtJXwduA3qiew9wkaT7CD2UY2I6d0m6hLA78nrg38xsQ9TxJEIvqg2Yb2Z3DVMnpwFpll6Vt5bTaZbn22oMNvy1NP6+k7Bk9+J4fTSwLDVGCczsRuDGeP4AYeVWcZjVUXZa/G6gO8X9N8BvhqJLkrwU2qQekO8XKC+65qkiLleO8pJnjUSenq8zNEoaFTNbACDpeGCWma2L1z8ErquJdlWkloV2sEqnkV6erLrmxVhXgnIGoVyeZN16o5GoxPNtpjLi9CfLRP0uwHjCkBTA1tHNyUAjGY1KUKn7zUOl02rPLguVyBPP1+Ymi1E5C7hNUm+83h84vWoaNRh5qPyK9YDGbv01k2GqJI00zJaXvM+LHq1EWaNiZj+RdA3wtuj0ZTN7orpq5YdGGLpqxiGWkZKXZ1Mpsg6z5eF+86JLXvRoNQZb/fXmIqfCv9d3kbSLmd1aPbXygRdKx3FqRbP0qgbrqZwziJ8R9vByGohmKbSVxPPEyQPN1IAdbPXXrFoq4lSXPBXavIz95ylP8kJenk2j4fNdmyk7pyJpDPBp4N3R6UbgR4Ulxo4zFHz+J7/4sxkePt/Vnyyrv34AjAHOj9cfi26frIpGjuM4TsOSxai8xcz2TVwvlnR7tRRyHMdxGpcsW99vkPTawkXcpXhD9VRyHMdxGpUsPZUvAr2SHiB8w2QP4BNV1cpxHMdpSLL8+fEGSXsBrycYlb+a2Zqqa+Y4juM0HFl6KgD7AZNj+H3jyoGfVk0rx3EcpyHJsqT4IuC1wHI2z6UY4EbFcRzH6UeWnsoMYB+r9wJrx3EcJ/dkWf21AnhNtRVxHMdxGp8sPZUdgbsl3QJsmqA3syOqppXjOI5TFwrbuAz3X/dZjMrpQ5bqOI7jVJyRVvhZGKncLEblDcDPzezZEaXkOI7jjIhGmNrOMqfyGuAvki6RdKiKt9t0HMdxnEhZo2JmXwX2AnqA44F7JX0juXVLGpLGSbpF0u2S7pJ0RnQ/UNKtklZIWiBpdHT/oqTl8VghaYOkCdFvpaQ7o9/SRBoTJF0v6d746/t0O47j1JEsPRXicuIn4rEe2B64TNK3Bom2BjgwbkY5HThU0juABcAxZjYNeAg4LqbxbTObbmbTgVOA/zGzZxLyZkX/GQm3LwM3mNlewA3xuqYkxzgdx8mGvzfVIQ/5WtaoSPqspGXAt4A/AG8ws08T/mX/oVLxLPBSvBwTjw3AGjP7W3S/voSMOcCiDPofSTBSxN/ZGeJUFDPbdDiOkw1/b6pDHvI1S09lR+CDZvYeM7u08HEuM9sIHDZYREltkpYDTxIMyC3AGEmF3sZRwG5FcbYCDgV+mXA24DpJyySdmHB/tZk9HvV5HNiphB4nSloqaemqVasy3LLjOI4zHLLMqZwK7CbpEwCSJkqaEv36ysTdEIezJgFvBaYCxwDnxv+9vEgYTktyOPCHoqGvd5rZm4H3Av8m6d0MATP7sZnNMLMZEydOHErUhqISXd88dJ8rRTPdi+MsWrSIadOm0dbWxrRp01i0KMtgTu3JMvx1GjCXMM8BYRjrZ0NJxMyeI3yG+FAz+6OZvcvM3gr8Hri3KPgxFA2Yjw6gAAAZ6klEQVR9mdlj8fdJ4NcEAwXwD0k7Rz13JvSImpIsFWQlur556D5Xima6F6e1WbRoEV1dXcybN4/Vq1czb948urq6cmlYsgx/fQA4AngZNlXw48tFij2a7eL5lsDBwF8l7RTdtiAYqx8m4mwL7A9ckXB7laTxhXPgEMLWMQBXEif64++meM2GV5CO07p0d3fT09PDrFmzGDNmDLNmzaKnp4fu7u56qzaALH9+XGtmJslgU8WehZ2BBZLaCMbrEjO7StK3JR0W3X5gZosTcT4AXGdmLyfcXg38OrbQRwMLzey30e8s4BJJHcDDwNEZdXOchqMW/6Z2BpKHfO/r62PmzJn93GbOnElf36AzEHUhi1G5RNKPgO0kfQo4AbigXCQzuwN4U4r7Fwlfk0yLcyFwYZHbA8C+JcI/DRxUThfHaQbckAydShiEPOR7e3s7Z5xxBpdffjl9fX20t7cze/Zs2tvb663aALJM1P8ncBlhNdbrgVPN7PvVVsxxHGekNMuw8axZszj77LM54YQTePHFFznhhBM4++yzmTVrVr1VG0DWPz9eb2ZfNLMvAIslfaTKejlNjCRfqVZEXu6lUs/GqSy9vb3MnTuX+fPnM378eObPn8/cuXPp7e2tt2oDKGlUJG0j6RRJ50k6RIGTgAeAD9dORafZSLYefaVaWNkzdepURo0axdSpU6u6oqecwajUs6kFyXtpdgPY19fHaaedxooVK9iwYQMrVqzgtNNOy+WcymA9lYsIw113Ap8EriNMhB9pZkfWQDfHaXpqvVS0UQxGFhrJAI6U9vZ2lixZ0s9tyZIluZxTGfBgEg/ozsR5G/AsML5U+EY59ttvP0vCph1lSpMlzEhlVCKNSuhRKRm1SqcSaRSOkegx3DBTp061rq4umzp1qo0aNarf9XDIUzlqlDJQqXQq8Y6XCrNw4UKbMmWKLV682NauXWuLFy+2KVOm2MKFC6uia4k4Sy1DHTvY6q91CcOzQdKDZvZiRSyZ09TkYQlmVuqt3913383LL7/M/PnzmTlzJkuWLOGEE07goYceqqteeaCRylG1mTNnDgCdnZ2bVn91d3dvcs8TKvWwJG0g/uERELAl8Eo8NzPbpiYaVpgZM2bY0qWbds/PVGArUajLyajVi1OLe6kUealMKlVG0sKMGzeOb3zjG5x88smb3L7zne/wla98hdWrV1dF10pQq/emVuTlHc/T80uJs8z67xKfSsk5FTNrM7Nt4jHezEYnzhvSoBRTq1UuvprGKcXatWs577zz6O3tZd26dfT29nLeeeexdu3aeqtWEi/PzmBk+fNj01KrVlSjtNac2rPPPvswe/bsfsMaxx57LJdffnm9VSuJl+eh00pDeZn+p+I4BbyVWlm6urpYuHBhv9VfCxcupKurq96qORUkOZHd7LR0T8UZOq3wUtSSOXPmcPPNN/Pe976XNWvWsMUWW/CpT30qlxOwQ6GVWuZOf7yn4jh1ZNGiRVx99dVcc801rF27lmuuuYarr746l1uaD4VWapk7/XGjkgNa6Z/BrUqpYcNG2tLccbJQcklxs1K8pLgcyUqg0fOq0e4lL0MnWZaKFhiqvm1tbaxevZoxY8Zsclu3bh3jxo1jw4YNFdfVGUil3ouR5n0t38+6LCl2As3UjW+me8kTI8nXhtp+o0nJy3uRBz0q8cliNyqOU0e6urro6Ojo9z+Vjo6OYa3+8pV5zkio1D50Pvzl5Ja8DOVUW49FixbR3d296X8qXV1dDb/6qxXJS3nNQpqu06ZNY/bs2QM+BHb55ZezYsWKzMNfblSc3JKXlzQvejj5ppHKSZquo0aNYo899kjdh27jxo0+p+I0NnkZyvGVeU6zUerdGjt2LJ2dnf1WInZ2djJ27NghyXej4uSSPExaFutRb10cpxKUKs+V2oeuakZF0jhJt0i6XdJdks6I7gdKulXSCkkLJI2O7gdIel7S8nicmpB1qKR7JN0n6csJ9ymS/izpXkkXSxqaSXUcx3GAsA/dscceS2dnJ+PGjaOzs5Njjz2WffbZZ0hyqtlTWQMcaGb7AtOBQyW9A1gAHGNm04CHgOMScW4ys+nxOBNAUhvw/4D3AvsAcyQV7vJs4Fwz24vwEbGOKt5Py1OJ5YaO4+STiu1Dl+VLXiM9gK2AW4G3Afcl3N8F/CaeHwBclRL37cC1ietT4iHgKWB0WrhSR+HLjwsXLuz3tb3hfkGtVaj0l+ccp9mgRl+prCaD1Ytk/PJjtY1JG7AceInQqxChdzIj+n+P+NniaFSeBm4HrgGmRvejgAsSMj8GnAfsWGSgdgNWlNNpv/32q2kF2SzGa+rUqbZ48eJ+bosXLx72Z28dp9loBqMyGLkwKpsSge2AXmBa7FHcBNwCfB24LYbZBtg6nr8PuDeeH51iVOYBE1OMyp0l0j8RWAos3X333WtWQTZa634wAzhq1Chbu3Ztv/Br1661UaNG1VpNx8kdwKajWcmVUQn6cBrwhSK3Q4BLSoRfGXsjFR/+qlUF2Uit+3IGsJHuxXGc4ZHr4a/Yk9gunm8ZeyeHATtFty2AGwiT+QCvYfOfMd8KPBwNx2jgAWAKMDYOjxWGxi4lTPoD/BD4TDm99ttvv5pVkI3Uui+XJ43W63IcZ2iUe8fzYFTeCNwG3AGsAE6N7t8G+oB7gH9PhD8JuCsajT8B70j4vQ/4G3A/0JVw3zMOo90XDcwW5fSq5ZxKI7XusxjAZpkfchxnIOXqq7oblbwetVz91Uit+0YygI7jVJ5yDUs3KmWMSq1olNZ9IxlAx3Eqj/dUGsSoNBKNYgAdx6k8lZpT8V2KHcdxHGDwzzD41vclcKPiOI4zdHzreye31GIPMd+nzHHqw+h6K+C0FoVPlvb09Gz6EFBHR9gHtFJfO6xFGo7jlCDLxEszHT5RX19qsXTZl0c7TuXBJ+rT8TmV+tLW1sbq1asZM2bMJrd169Yxbtw4NmzY0DBpOE6r4XMqTi5pb29nyZIl/dyWLFlCe3t7Q6XhOE46blScmtLV1UVHR0e/T5Z2dHQM/UNAdU7DcZx0fKLeqSmFifLOzs5Na+G7u7srOoFeizQcx0nH51QcpwkY7E9rjlMJss6peE/FcRocX0Lt5AnvqThOgzNt2jTmzZvHrFmzNrn19vbS2dnJihUr6qiZ00z4Ni0lcKPiNBu+hNqpBb6k2HFaBF9C7eQJNyqO0+D4EmonT/hEveM0OL6E2skTPqfiOI7jlMXnVBzHcZya40bFcRzHqRhVMyqSxkm6RdLtku6SdEZ0P1DSrZJWSFogaXR0/4ikO+Jxs6R9E7JWSrpT0nJJSxPuEyRdL+ne+Lt9te7HcRzHKU81eyprgAPNbF9gOnCopHcAC4BjzGwa8BBwXAz/ILC/mb0R+Brw4yJ5s8xsetGY3peBG8xsL+CGeO04juPUiaoZlfhdl5fi5Zh4bADWmNnfovv1wIdi+JvN7Nno/idgUoZkjiQYKeLv7Ero7jiO4wyPqs6pSGqTtBx4kmBAbgHGSCr0No4CdkuJ2gFck7g24DpJyySdmHB/tZk9DhB/dyqhx4mSlkpaumrVqpHdlOM4jlOSqv5Pxcw2ANMlbQf8GpgKHAOcK2kL4DpgfTKOpFkEozIz4fxOM3tM0k7A9ZL+ama/H4IePyYOp82YMaO11lA7juPUkJqs/jKz54AbgUPN7I9m9i4zeyvwe+DeQjhJbwQuAI40s6cT8R+Lv08SjNNbo9c/JO0c4+5M6BE5juM4daKaq78mxh4KkrYEDgb+GnsbxJ7KXOCH8Xp34FfAxxJzLkh6laTxhXPgEKCw9eqVbJ7oPw64olr34ziO45SnmsNfOwMLJLURjNclZnaVpG9LOiy6/cDMFsfwpwI7AOdLAlgfV3q9Gvh1dBsNLDSz38Y4ZwGXSOoAHgaOruL9OI7jOGXwbVqqjH+Rz3GcZsC//JgD/It8juO0Gt5TqSL+RT7HcZoF//JjCWppVPyLfI7jNAu+S3EO8C/yOY7TarhRqSL+RT7HcVoNn6ivIv5FPsdxWg2fU3Ecx3HK4nMqjuM4Ts1xo+I4juNUDDcqjuM4TsVwo+I4juNUDDcqjuM4TsVoudVfklYBDyWcdgSeKhOtXJi8yKhVOq2ma6vdb63SyYuMWqXT6LruYWYTy8gFM2vpA1g60jB5keG65leG65pfGa7r8GSUOnz4y3Ecx6kYblQcx3GciuFGBX5cgTB5kVGrdFpN11a731qlkxcZtUqn2XRNpeUm6h3HcZzq4T0Vx3Ecp2K4UXEcx3Eqx3CXjTX6AcwHngRWlPDfDegF+oC7gM+lhBkH3ALcHsOcUUJWG3AbcFUJ/5XAncBySizlA7YDLgP+GnV6e8Lv9TFu4XgB+PcUGf8R9VwBLALGFfl/LvrdVYiflk/ABOB64N74+7OUMEdHORuBK1L8vx3v5Q7g1yVkfC36LweuizqnPjPgC4ABq4pknA78PZE316XJADqBe4BngZeLZFyciL8SeDpF1+nAn2KYp4Bnivz3Bf4Yn/N/A+1p5SuRtw9GGfcU+Sfz9f0lZBTyti/mR7GMZL7+D/CHYhkp+bokJZ1C3t4FvAg8XCwjka/3RP9iGYW8vQv4J7C6yD+Zr7cDS1NkJPP26him3zsJTAH+DNwXn98dRf4nRT8DdiXlvQZ+nsjLVSn+PdHtDuBXaXok8uV8YEOKjAvjsy/c74qUMAK6gb/F5/xQSpibEjLWAs8X+R8E3BrD/CGGK5ZxYAyzAlgAjM5Ut9a7cq/XAbwbeDOljcrOwJvj+fj4APcpCiNg63g+Jhbaf02RdTKwkMGNyo5l9F0AfDKejwW2KxGuDXiC8EelpPuusbBuGa8vAY5P+E+LhWcrwnd2fgfslZZPwLeAL8fzL8eXrThMO8HY3Qh8KsX/kEIhBc4uIWObxPlnCcZpwDMjNACujfd9IAONyhcGe+7ArHi/W0T/gwYpF+cQKo9iGdcB743nXyJUKEn/vwD7x/MTgHPTylchb2P5+37Mm6R/Ml/fU0LGIfEZ7kyopIplJPP1q8BlaeU8ka+PAgempHM6weikvitF+bozcFCp9yn6XwScWiQjma8fITa6isIU5+1Zxe8kobwfQ3hnLwA+XeT/JmAy8V0k5b0G3hfjC7g0RUYyX78DnJpWNwAz4r2+lJLGhcBRg9UvwCeAnxJGmgRMLlUHRf/LgY8Xyfgb0B7DfAb4WZGMdwCPAHtH9zOBjix1a8sOf5nZ7wktwVL+j5vZrfH8RULraNeiMGZmL8XLMfHot/JB0iRCi/KC4eoqaRtCZdcT011rZs+VCH4QcL+ZPZTiNxrYUtJogvF4LOHXDvzJzF4xs/WEFuwHSuTTkQQjR/ydURzGzPrM7J54eVuK/3UxHQgtUVLCvJC4fFXUN+2ZnUuoyFcTeholKXE/nyZURGui//1pcSUJ+DBwVooMA7aJ548QWvBJXg/8Pp5fD7ynRPk6ElhgZo8D3wRmJ/2L8vXpNBmFvI0yrgAmFfkn83UDodWdVs4L+bqe0PpOfRcGeVeS+fq4md1QSgahQXAAsKjIP5mvGwmVYbGM4rw9Ip4n38kDCcbTCO/R7KS/md1mZisT9zTgvTaz38R33oCbgUlF/i/ApnKyJbCmWIakNkJP8kuJe0+tOwapXz4NnGlmG2OYlYPI2RrYn2BYkv7JfN2W0ItMytgArDGzvyXy9UNkIYvladaD0DJJbZGmhHuYREsk4ddG6EK+BJyd4n8ZsB/hhSnVU3mQ0M1cBpyY4j+d0B2/kFBBXwC8qoSs+cBJJfw+F/VcBfy8yK+d8MLuQDA4fwTmpeUT8FxR3GdL5SWhRT1jsLwmDAd9NC0MoZv/CKEXNTFFlyOA78XzlYQWZ3FPZSWhUpwPbJ8iYzlwBqGF9j9RZtq9vJvNLeViGe2xjBQMyjuL/G8GjoznJwMvppWvQfK2X/kr5Gu5MlqUt5v8i/M1RY/ifN0xJUypvC34F+frW0rpmpK3BRnF+bpHSpgBeUvinST0PO5LpLUHYahtwDvL5p5KyfeaUOneShj+7ecP/AT4B2FYcutiGYR38D/i+Usp/hcShtjuIBj1LVPCPA10EXrD17B5+DtN148T6qBiGe+Kch4F7iYMryfzTIRhtRkx/PeAOzPVq1kCNetBBqMSC8Yy4INlwm0XC9K0hNthwPnx/ABKG5Vd4u9OhHHNdxf5zyC0Ft+WeMBfS5EzljCe/+oUv+2BxYSKeQyh5fLRojAd8WX5PfBD4Ny0fKKCRiW+HL+Ohbjk8wBOIVRQm8IQjN+fgW3j9UoGGpVXEyqIUYSKdH7K/awgDDUJeCuxsk3R4QfA50vkyfeBD8XzDxPmIJL+/0IYylkGnEboZQwoXyXydkD5I2FUimWk5G3JMpzI101hSuTrjim6FuftT4v8i/P1wUF0/QHw+ZQ0ivP1dylhSuVt4Z18F/2Nym6E+Ze0d3YliaHoEmH+C/juIP5thDmTTxSFeXcsF4Vh35eKZRCGAUUYMlzA5iG0ZJiX2FwOPwjcNIgu1yTyLynjV2yuT74IXJAS5u2EuZlbgK8Dtw1WB25KM0ugZj0oY1QIle+1wMkZ5Z1G//H7bxJaAisJ3ftXiGOXg8g4PSkjur0GWJm4fhdwdUrcI4HrSsg9GuhJXH+caPBKhP8G8Jm0fCK0pHaO5zvH69S8ZBCjAhxH6BFtVe55EFqXK+hvVN5AmDBfGY/1hNbsXwd73in381vggMT1Q0BfUdzRhBbopBJ58jyb//clQmu51L3sHV/UAeWrKG93IywaGFD+EvmaWkYTebtNmn9Kvm4KUyJfHyZUNqXkvC7ec/JeivP1fkLDpljXQt5OTsmP4nx9ocz97A3cUvROfpHQ2CpU5m8Hri3xzq6kaH4zGSaeXw6MKvXeR7f9STQiY5jTCPVAIV83Eo1dCRkHpMj4AmFyfnIiT54voesOhN7IuJT8uD/htjtwd5n7OQS4pFR9kTxadk6lHHFctIdQuXynRJiJkraL51sCBxMeOABmdoqZTTKzyYRJwsVm9tEiGa+SNL5wTnh4K5JhzOwJ4BFJr49OBxG6rMXMIayQSuNh4F8lbRXv7SDCmHRSl53i7+6EFlApWVcSKi3i7xUlwpVE0qHAXOAIM3ulRJi9EpdHkMhbADO708x2MrPJMY8fJfQO1ydk7JyI8gGK8jZyOWHMHUl7s3lMOcnBBGP1aIlbeoxQkRBlrSy6l0LejiJMjv+Q9PJ1JXBcfEZXpPgXM0BGMm+B81L8i/N1fDJMiXz9I3B7kZyd468IZeWxIl2L8/U1wB0p91N4b85Mud/ifF2Xcj/JvP0acb4v8U72EQziUZImEhaOXJH2zkZ2SHuvJX2SsDiikzgfkfC/R9LrEvnxYULPLBlmmZm9JubpW4BXzOx1RWkk83QOYYituH7ZlK+E53d/ShgIDcnrCatUi/Nj2/hMILwX96XcbyFftyCUpx+ShSyWpxkPwkvwOKGQPkrRygZgJmEyq7D0cjnwvqIwbyTMcdxBqKxOHSS9A0gZ/gL2pP9yvq4S8acTxlDviIVq+yL/rQitkm0H0eGMWOBWEFafbFHkfxPBWN3O5pU6A/KJ0AK6gVDgbwB+mRLmA/F8DWECfU2R/32EYaZC3t6bIuOXUdc7CHMDl5d5Zi8RWoJJGRcRhjruIFTYv05JZyxhSfMKwgT808VpEMa6/88geTKTMPxyO6FVvKrI/3OEOau/ESb6U8tXIm8fif53Ffkn8/WZEjIKeXtv9H+6yD+Zr39Ik1GUr4+XSKeQt4WluHcX+Sfz9Z5S6cS8/XaJNJL5eleJMMm87SHlnSS8Z7cQGlfPRr2T/p+N+bqe0Et7KkXGekIF/lfCqMMTBX/CEOAfEnKvZvPy4gF1A6Hu2JCSxuKEjKvSZBCGqK6O4W4nGIkB6RB6s58ukR8fSMT/S8zb4jDfjrLvIeUvCqUO36bFcRzHqRg+/OU4juNUDDcqjuM4TsVwo+I4juNUDDcqjuM4TsVwo+I4juNUDDcqTksjaYOk5ZJWSLpU0lZDjP9S+VAl4x4vaaOkNybcVkiaPFyZldLNcYaLGxWn1fmnmU03s2mELcL/T9JTgWq+J48StlPJFXHTUccZMm5UHGczNwGvkzRZUp+k8wl7oe0maY6kO2NP4uxkJEnnSLpV0g3xH9tIeq2k30paJukmSf9SIs2rgKmJ3RKScl9KnB8l6cJ4fqGkH0jqlfSApP0lzY86Xzhc3aLc70jqJWwq6DhDxo2K47CpZf5ewr+MIez8+lMzexPhn/FnE7bGmA68RdLsGO5VwK1m9mbCTrynRfcfA51mth9hv6bzSyS9kfANla8MUeXtoz7/Qdht4FxgKvAGSdNHoNvewMFm9vkh6uM4QNjIzXFamS0lLY/nNxG2+dgFeMjMCt95eQtwo5mtApD0c8KOs5cTjMLFMdzPgF9J2prwkaNLwxZOQNh1thQLgS5JU4ag93+bmUm6E/iHmd0ZdbuLsDHj8mHqdqmZFe975jiZcaPitDr/NLPpSYdY2b6cdBqCPCOMADxXLLdkBLP1ks4hbNpXLKvAuCK/wgegNibOC9el3ussur1cwt1xMuHDX45Tnj8D+0vaMX65bw5hOAnCO3RUPD8WWGLhC4APSjoaNk3271smjQsJu8NOTLj9Q1J7XCjwgWHoXSndHCczblQcpwwWPst7CmH79NsJ8xSF7f5fJky0LyPMcZwZ3T8CdEgq7K57ZJk01hI+SLVTwvnLhIn8xYSdgodKRXRznKHguxQ7juM4FcN7Ko7jOE7FcKPiOI7jVAw3Ko7jOE7FcKPiOI7jVAw3Ko7jOE7FcKPiOI7jVAw3Ko7jOE7F+P8JIaoBvbV/2gAAAABJRU5ErkJggg==\n", + "text/plain": [ + "
" + ] + }, + "metadata": {}, + "output_type": "display_data" + } + ], "source": [ "%matplotlib inline\n", + "#%matplotlib qt5\n", "import pandas as pd\n", "from matplotlib import pyplot as plt\n", "\n", @@ -363,6 +492,66 @@ "plt.show()" ] }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "### Re-shape in Numpy" + ] + }, + { + "cell_type": "code", + "execution_count": 9, + "metadata": {}, + "outputs": [ + { + "data": { + "text/plain": [ + "array([[1, 6],\n", + " [2, 7],\n", + " [3, 8],\n", + " [4, 9],\n", + " [5, 0]])" + ] + }, + "execution_count": 9, + "metadata": {}, + "output_type": "execute_result" + } + ], + "source": [ + "import numpy as np\n", + "aa = np.array([1,2,3,4,5,6,7,8,9,0])\n", + "bb = np.copy(aa)\n", + "aa = np.reshape(aa,(5,2),'F')\n", + "aa" + ] + }, + { + "cell_type": "code", + "execution_count": 10, + "metadata": {}, + "outputs": [ + { + "data": { + "text/plain": [ + "array([[1, 2],\n", + " [3, 4],\n", + " [5, 6],\n", + " [7, 8],\n", + " [9, 0]])" + ] + }, + "execution_count": 10, + "metadata": {}, + "output_type": "execute_result" + } + ], + "source": [ + "bb = np.reshape(bb,(5,2))\n", + "bb" + ] + }, { "cell_type": "code", "execution_count": null, @@ -388,7 +577,7 @@ "name": "python", "nbconvert_exporter": "python", "pygments_lexer": "ipython3", - "version": "3.6.4" + "version": "3.7.1" } }, "nbformat": 4, diff --git a/Section_12_Matrices.ipynb b/Section_12_Matrices.ipynb index 3507cc8..26f076c 100644 --- a/Section_12_Matrices.ipynb +++ b/Section_12_Matrices.ipynb @@ -12,7 +12,9 @@ "\n", "- [Arrays Recap](#Arrays-Recap)\n", "- [Lists vs Arrays](#Lists-vs-Arrays)\n", - "- [Matrices](#Matrices)\n" + "- [Matrices](#Matrices)\n", + "- [2D Lists](#2D-Lists)\n", + "- [Other Numpy matrix functions useful in general engineering](#Other-Numpy-matrix-functions-useful-in-general-engineering)\n" ] }, { @@ -61,7 +63,6 @@ "cell_type": "code", "execution_count": null, "metadata": { - "collapsed": true, "slideshow": { "slide_type": "subslide" } @@ -99,9 +100,7 @@ { "cell_type": "code", "execution_count": null, - "metadata": { - "collapsed": true - }, + "metadata": {}, "outputs": [], "source": [ "import numpy as np\n", @@ -132,9 +131,7 @@ { "cell_type": "code", "execution_count": null, - "metadata": { - "collapsed": true - }, + "metadata": {}, "outputs": [], "source": [ "import numpy as np\n", @@ -157,9 +154,7 @@ { "cell_type": "code", "execution_count": null, - "metadata": { - "collapsed": true - }, + "metadata": {}, "outputs": [], "source": [ "import numpy as np\n", @@ -199,9 +194,7 @@ { "cell_type": "code", "execution_count": null, - "metadata": { - "collapsed": true - }, + "metadata": {}, "outputs": [], "source": [ "import numpy as np\n", @@ -234,9 +227,7 @@ { "cell_type": "code", "execution_count": null, - "metadata": { - "collapsed": true - }, + "metadata": {}, "outputs": [], "source": [ "import numpy as np\n", @@ -305,9 +296,7 @@ { "cell_type": "code", "execution_count": null, - "metadata": { - "collapsed": true - }, + "metadata": {}, "outputs": [], "source": [ "import numpy as np\n", @@ -327,7 +316,6 @@ "cell_type": "code", "execution_count": null, "metadata": { - "collapsed": true, "slideshow": { "slide_type": "subslide" } @@ -394,14 +382,16 @@ "- `numpy.zeros` function\n", "\n", "\n", - "- `numpy.dot` function" + "- `numpy.dot` function\n", + "\n", + "\n", + "- @ operator" ] }, { "cell_type": "code", "execution_count": null, "metadata": { - "collapsed": true, "slideshow": { "slide_type": "subslide" } @@ -440,7 +430,6 @@ "cell_type": "code", "execution_count": null, "metadata": { - "collapsed": true, "slideshow": { "slide_type": "subslide" } @@ -466,7 +455,9 @@ "print(\"\\nManual dot calculation 2:\")\n", "print(my_dot_v2(mat1, mat2))\n", "print(\"\\nNumpy dot calculation:\")\n", - "print(np.dot(mat1, mat2))" + "print(np.dot(mat1, mat2))\n", + "print(\"\\n@ operator calculation:\")\n", + "print(mat1@mat2)" ] }, { @@ -512,7 +503,6 @@ "cell_type": "code", "execution_count": null, "metadata": { - "collapsed": true, "slideshow": { "slide_type": "subslide" } @@ -543,7 +533,6 @@ "cell_type": "code", "execution_count": null, "metadata": { - "collapsed": true, "slideshow": { "slide_type": "subslide" } @@ -572,14 +561,12 @@ { "cell_type": "code", "execution_count": null, - "metadata": { - "collapsed": true - }, + "metadata": {}, "outputs": [], "source": [ - "import numpy as np\n", + "# import numpy as np\n", "\n", - "np.lookfor('upper diagonal')" + "# np.lookfor('upper diagonal')" ] }, { @@ -631,7 +618,6 @@ "cell_type": "code", "execution_count": null, "metadata": { - "collapsed": true, "slideshow": { "slide_type": "subslide" } @@ -657,7 +643,6 @@ "cell_type": "code", "execution_count": null, "metadata": { - "collapsed": true, "slideshow": { "slide_type": "subslide" } @@ -680,23 +665,121 @@ "print (smat)" ] }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "## 2D Lists\n", + "\n", + "- List of lists\n", + "- Creating a list of lists \n", + "- Indexing" + ] + }, { "cell_type": "code", "execution_count": null, "metadata": { - "collapsed": true, "slideshow": { "slide_type": "skip" } }, "outputs": [], - "source": [] + "source": [ + "lol1 = [[1,2,3,4],[5,6,7],['Spain','Portugal','Greece']]\n", + "print(lol1)\n", + "type(lol1)" + ] + }, + { + "cell_type": "code", + "execution_count": null, + "metadata": {}, + "outputs": [], + "source": [ + "lol1" + ] + }, + { + "cell_type": "code", + "execution_count": null, + "metadata": {}, + "outputs": [], + "source": [ + "#lol1[2,1]\n", + "lol1[2] # 3rd list" + ] + }, + { + "cell_type": "code", + "execution_count": null, + "metadata": {}, + "outputs": [], + "source": [ + "lol1[2][1]" + ] + }, + { + "cell_type": "code", + "execution_count": null, + "metadata": {}, + "outputs": [], + "source": [ + "lol1[2][1] = 'Italy'\n", + "lol1" + ] + }, + { + "cell_type": "markdown", + "metadata": {}, + "source": [ + "## Other Numpy matrix functions useful in general engineering\n", + "\n", + "The following was not formally taught in the MPR 213 module and will therefore not be tested in the exam. This information is supplied to assist students in using Python effectively in their further engineering studies.\n", + "\n", + "Use `help` or `numpy.info` to get help on how to use these functions:\n", + "\n", + "- cross product of two vectors: `numpy.cross`\n", + "- Solution of system of linear equations (essentially Gaussian elimination): `numpy.linalg.solve`\n", + "- Calculation of eigenvalues and eigenvectors of a square matrix: `numpy.linalg.eig`\n", + "\n", + "### Example of cross product calculation:\n", + "\n", + "Let us define the unit vectors in the Cartesian $x$, $y$ and $z$ directions, $\\vec{\\imath}$, $\\vec{\\jmath}$ and $\\vec{k}$, respectively, as three one-dimensional numpy arrays `ii`, `jj`, and `kk`, respectively:" + ] + }, + { + "cell_type": "code", + "execution_count": null, + "metadata": {}, + "outputs": [], + "source": [ + "import numpy as np\n", + "\n", + "ii = np.array([1.0, 0.0, 0.0])\n", + "jj = np.array([0.0, 1.0, 0.0])\n", + "kk = np.array([0.0, 0.0, 1.0])\n", + "\n", + "should_be_kk = np.cross(ii,jj)\n", + "should_be_ii = np.cross(jj,kk)\n", + "should_be_jj = np.cross(kk,ii)\n", + "\n", + "should_be_minus_kk = np.cross(jj,ii)\n", + "\n", + "should_be_zero = np.cross(ii,ii)\n", + "\n", + "print('should_be_kk = ',should_be_kk)\n", + "print('should_be_ii = ',should_be_ii)\n", + "print('should_be_jj = ',should_be_jj)\n", + "print('should_be_minus_kk = ',should_be_minus_kk)\n", + "print('should_be_zero = ',should_be_zero)" + ] } ], "metadata": { "anaconda-cloud": {}, "kernelspec": { - "display_name": "Python [default]", + "display_name": "Python 3", "language": "python", "name": "python3" }, @@ -710,7 +793,7 @@ "name": "python", "nbconvert_exporter": "python", "pygments_lexer": "ipython3", - "version": "3.5.2" + "version": "3.7.1" } }, "nbformat": 4,