alesolano/Elasticity.ipynb

## Elasticity.ipynb
{
 "cells": [
  {
   "cell_type": "code",
   "execution_count": 1,
   "metadata": {
    "collapsed": true
   },
   "outputs": [],
   "source": [
    "import numpy as np\n",
    "import matplotlib.pyplot as plt"
   ]
  },
  {
   "cell_type": "markdown",
   "metadata": {},
   "source": [
    "## Drawing Mohr's circles"
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 2,
   "metadata": {},
   "outputs": [
    {
     "data": {
      "text/plain": [
       "array([[  50,  300,    0],\n",
       "       [ 300, -400,    0],\n",
       "       [   0,    0,    0]])"
      ]
     },
     "execution_count": 2,
     "metadata": {},
     "output_type": "execute_result"
    }
   ],
   "source": [
    "# Given a certain stress tensor\n",
    "σ = np.array([[50, 300, 0], [300, -400, 0], [0, 0, 0]])\n",
    "σ"
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 3,
   "metadata": {
    "collapsed": true
   },
   "outputs": [],
   "source": [
    "n = 100000\n",
    "\n",
    "σn = np.zeros([n, 1]) # array of normal stress component\n",
    "τ = np.zeros([n, 1]) # array of shear stress component\n",
    "\n",
    "for i in range(n):\n",
    "    \n",
    "    # Generate normal vectors to n random planes\n",
    "    θ = np.random.uniform(0, 2*np.pi)\n",
    "    ϕ = np.random.uniform(0, np.pi)\n",
    "    η = np.array([np.sin(ϕ)*np.cos(θ), np.sin(ϕ)*np.sin(θ), np.cos(ϕ)])\n",
    "    \n",
    "    # Cauchy's Law\n",
    "    T = σ.dot(η)\n",
    "    \n",
    "    # Stress components\n",
    "    σn[i, 0] = η.dot(T)\n",
    "    τ[i, 0] = np.sqrt(np.array([(T**2).sum() - σn[i, 0]**2]).astype(np.float32))[0]"
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 4,
   "metadata": {},
   "outputs": [
    {
     "data": {
      "image/png": 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      "text/plain": [
       "<matplotlib.figure.Figure at 0x7fb8efabafd0>"
      ]
     },
     "metadata": {},
     "output_type": "display_data"
    }
   ],
   "source": [
    "# Plot circles\n",
    "plt.plot(σn, τ, 'c.')\n",
    "plt.axis('equal')\n",
    "plt.show()"
   ]
  },
  {
   "cell_type": "markdown",
   "metadata": {},
   "source": [
    "Checking how the maximum and minimum values of the normal stress component match the principal normal stresses."
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 5,
   "metadata": {},
   "outputs": [
    {
     "data": {
      "text/plain": [
       "(-549.99030444725634, 199.97520159297252)"
      ]
     },
     "execution_count": 5,
     "metadata": {},
     "output_type": "execute_result"
    }
   ],
   "source": [
    "# Principal normal stresses (not including σz), numerically\n",
    "σn.min(), σn.max()"
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 6,
   "metadata": {},
   "outputs": [
    {
     "data": {
      "text/plain": [
       "(-550.0, 200.0)"
      ]
     },
     "execution_count": 6,
     "metadata": {},
     "output_type": "execute_result"
    }
   ],
   "source": [
    "σx = σ[0, 0]\n",
    "σy = σ[1, 1]\n",
    "τxy = σ[0, 1]\n",
    "\n",
    "# Center and radius of the external circle\n",
    "C = (σx + σy)/2\n",
    "R = np.sqrt(((σx - σy)/2)**2 + τxy**2)\n",
    "\n",
    "# Principal normal stresses (not including σz), graphically\n",
    "C - R, C + R"
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 7,
   "metadata": {},
   "outputs": [
    {
     "data": {
      "text/plain": [
       "array([ 200., -550.,    0.])"
      ]
     },
     "execution_count": 7,
     "metadata": {},
     "output_type": "execute_result"
    }
   ],
   "source": [
    "# Principal normal stresses, analitically\n",
    "np.linalg.eigvals(σ)"
   ]
  },
  {
   "cell_type": "code",
   "execution_count": null,
   "metadata": {
    "collapsed": true
   },
   "outputs": [],
   "source": []
  }
 ],
 "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": "3.6.1"
  }
 },
 "nbformat": 4,
 "nbformat_minor": 2
}
	{
	"cells": [
	{
	"cell_type": "code",
	"execution_count": 1,
	"metadata": {
	"collapsed": true
	},
	"outputs": [],
	"source": [
	"import numpy as np\n",
	"import matplotlib.pyplot as plt"
	]
	},
	{
	"cell_type": "markdown",
	"metadata": {},
	"source": [
	"## Drawing Mohr's circles"
	]
	},
	{
	"cell_type": "code",
	"execution_count": 2,
	"metadata": {},
	"outputs": [
	{
	"data": {
	"text/plain": [
	"array([[ 50, 300, 0],\n",
	" [ 300, -400, 0],\n",
	" [ 0, 0, 0]])"
	]
	},
	"execution_count": 2,
	"metadata": {},
	"output_type": "execute_result"
	}
	],
	"source": [
	"# Given a certain stress tensor\n",
	"σ = np.array([[50, 300, 0], [300, -400, 0], [0, 0, 0]])\n",
	"σ"
	]
	},
	{
	"cell_type": "code",
	"execution_count": 3,
	"metadata": {
	"collapsed": true
	},
	"outputs": [],
	"source": [
	"n = 100000\n",
	"\n",
	"σn = np.zeros([n, 1]) # array of normal stress component\n",
	"τ = np.zeros([n, 1]) # array of shear stress component\n",
	"\n",
	"for i in range(n):\n",
	" \n",
	" # Generate normal vectors to n random planes\n",
	" θ = np.random.uniform(0, 2*np.pi)\n",
	" ϕ = np.random.uniform(0, np.pi)\n",
	" η = np.array([np.sin(ϕ)np.cos(θ), np.sin(ϕ)np.sin(θ), np.cos(ϕ)])\n",
	" \n",
	" # Cauchy's Law\n",
	" T = σ.dot(η)\n",
	" \n",
	" # Stress components\n",
	" σn[i, 0] = η.dot(T)\n",
	" τ[i, 0] = np.sqrt(np.array([(T2).sum() - σn[i, 0]2]).astype(np.float32))[0]"
	]
	},
	{
	"cell_type": "code",
	"execution_count": 4,
	"metadata": {},
	"outputs": [
	{
	"data": {
	"image/png": 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w8jyJqrBB38hIm55Fi3TrP8m9e5YuDV1CIeV5+n9hg76RkTavbNqUQiUizfVEVxdaFSeM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\nYII=\n",
	"text/plain": [
	"<matplotlib.figure.Figure at 0x7fb8efabafd0>"
	]
	},
	"metadata": {},
	"output_type": "display_data"
	}
	],
	"source": [
	"# Plot circles\n",
	"plt.plot(σn, τ, 'c.')\n",
	"plt.axis('equal')\n",
	"plt.show()"
	]
	},
	{
	"cell_type": "markdown",
	"metadata": {},
	"source": [
	"Checking how the maximum and minimum values of the normal stress component match the principal normal stresses."
	]
	},
	{
	"cell_type": "code",
	"execution_count": 5,
	"metadata": {},
	"outputs": [
	{
	"data": {
	"text/plain": [
	"(-549.99030444725634, 199.97520159297252)"
	]
	},
	"execution_count": 5,
	"metadata": {},
	"output_type": "execute_result"
	}
	],
	"source": [
	"# Principal normal stresses (not including σz), numerically\n",
	"σn.min(), σn.max()"
	]
	},
	{
	"cell_type": "code",
	"execution_count": 6,
	"metadata": {},
	"outputs": [
	{
	"data": {
	"text/plain": [
	"(-550.0, 200.0)"
	]
	},
	"execution_count": 6,
	"metadata": {},
	"output_type": "execute_result"
	}
	],
	"source": [
	"σx = σ[0, 0]\n",
	"σy = σ[1, 1]\n",
	"τxy = σ[0, 1]\n",
	"\n",
	"# Center and radius of the external circle\n",
	"C = (σx + σy)/2\n",
	"R = np.sqrt(((σx - σy)/2)2 + τxy2)\n",
	"\n",
	"# Principal normal stresses (not including σz), graphically\n",
	"C - R, C + R"
	]
	},
	{
	"cell_type": "code",
	"execution_count": 7,
	"metadata": {},
	"outputs": [
	{
	"data": {
	"text/plain": [
	"array([ 200., -550., 0.])"
	]
	},
	"execution_count": 7,
	"metadata": {},
	"output_type": "execute_result"
	}
	],
	"source": [
	"# Principal normal stresses, analitically\n",
	"np.linalg.eigvals(σ)"
	]
	},
	{
	"cell_type": "code",
	"execution_count": null,
	"metadata": {
	"collapsed": true
	},
	"outputs": [],
	"source": []
	}
	],
	"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": "3.6.1"
	}
	},
	"nbformat": 4,
	"nbformat_minor": 2
	}