{
 "cells": [
  {
   "cell_type": "markdown",
   "metadata": {},
   "source": [
    "## Solving for eigenvalues and eigenvectors\n",
    "\n",
    "We saw in the previous notebook how to set up a matrix by integrating between pairs of basis functions.  In this notebook we will solve for the eigenvalues and eigenvectors of the Hamiltonian for a square well, exploring what happens when we use a finite basis set, and introduce changes to the potential in the square well."
   ]
  },
  {
   "cell_type": "markdown",
   "metadata": {},
   "source": [
    "### Eigenbasis, adding potential\n",
    "\n",
    "We will start by using the eigenbasis (since it's simple) and will add small changes to the potential.  This will give us some insight into the effect of perturbations (and will feed directly into our studies of perturbation theory).  So we'll first set up the bits and pieces of code we'll need, some taken from the previous notebook."
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 2,
   "metadata": {
    "collapsed": false
   },
   "outputs": [],
   "source": [
    "# Import libraries and set up in-line plotting.\n",
    "%matplotlib inline\n",
    "import matplotlib.pyplot as pl\n",
    "import numpy as np\n",
    "# This is a new library - linear algebra includes solving for eigenvalues & eigenvectors of matrices\n",
    "import numpy.linalg as la\n",
    "\n",
    "# Define the eigenbasis - normalisation needed elsewhere\n",
    "# There is a way to make this return a stub that we pass n and norm to\n",
    "def eigenbasis_sw(n,width,norm,x):\n",
    "    \"\"\"The eigenbasis for a square well, running from 0 to a, sin(n pi x/a)\"\"\"\n",
    "    fac = np.pi*n/width\n",
    "    return norm*np.sin(fac*x)\n",
    "\n",
    "# We will also define the second derivative for kinetic energy (KE)\n",
    "def d2eigenbasis_sw(n,width,norm,x):\n",
    "    \"\"\"The eigenbasis for a square well, running from 0 to a, sin(n pi x/a)\"\"\"\n",
    "    fac = np.pi*n/width\n",
    "    return -fac*fac*norm*np.sin(fac*x)\n",
    "\n",
    "# Define the x-axis\n",
    "width = 1.0\n",
    "num_x_points = 101\n",
    "x = np.linspace(0.0,width,num_x_points)\n",
    "dx = width/(num_x_points - 1)\n",
    "\n",
    "# Integrate two functions over the width of the well\n",
    "def integrate_functions(f1,f2,size_x,dx):\n",
    "    \"\"\"Integrate two functions over defined x range\"\"\"\n",
    "    sum = 0.0\n",
    "    for i in range(size_x):\n",
    "        sum = sum + f1[i]*f2[i]\n",
    "    sum = sum*dx\n",
    "    return sum\n",
    "\n",
    "# Now set up the array of basis functions - specify the size of the basis\n",
    "num_basis = 10\n",
    "# These arrays will each hold an array of functions\n",
    "basis_array = np.zeros((num_basis,num_x_points))\n",
    "d2basis_array = np.zeros((num_basis,num_x_points))\n",
    "\n",
    "# Loop over first num_basis basis states, normalise and create an array\n",
    "# NB the basis_array will start from 0\n",
    "for i in range(num_basis):\n",
    "    n = i+1\n",
    "    # Calculate A = <phi_n|phi_n>\n",
    "    integral = integrate_functions(eigenbasis_sw(n,width,1.0,x),eigenbasis_sw(n,width,1.0,x),num_x_points,dx)\n",
    "    # Use 1/sqrt{A} as normalisation constant\n",
    "    normalisation = 1.0/np.sqrt(integral)\n",
    "    basis_array[i,:] = eigenbasis_sw(n,width,normalisation,x)\n",
    "    d2basis_array[i,:] = d2eigenbasis_sw(n,width,normalisation,x)"
   ]
  },
  {
   "cell_type": "markdown",
   "metadata": {},
   "source": [
    "We have now set up all the mechanics that we need to create matrices for different Hamiltonians, except for one thing: the potential.  We have an implicit potential already in the infinite square well (we set $V=\\infty$ when $x=0$ or $x=a$).  If we create a potential function, then we can change this and create different Hamiltonian matrices.  So we'll do this next."
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 3,
   "metadata": {
    "collapsed": false
   },
   "outputs": [
    {
     "data": {
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      "text/plain": [
       "<matplotlib.figure.Figure at 0x109e42f10>"
      ]
     },
     "metadata": {},
     "output_type": "display_data"
    }
   ],
   "source": [
    "# Define the potential in the square well\n",
    "def square_well_potential(x,V,a):\n",
    "    \"\"\"Potential for a particle in a square well, expecting two arrays: x, V(x), and potential height, a\"\"\"\n",
    "    for i in range(x.size):\n",
    "        V[i] = 0.0\n",
    "    # Let's define a small bump in the middle of the well\n",
    "    i_mid = x.size/2\n",
    "    V[i_mid-1] = a\n",
    "    V[i_mid] = a\n",
    "    V[i_mid+1] = a\n",
    "    # Plot to ensure that we know what we're getting\n",
    "    pl.plot(x,V)\n",
    "    \n",
    "# Declare space for this potential (Vbump) and call the routine\n",
    "Vbump = np.linspace(0.0,width,num_x_points)\n",
    "pot_bump = square_well_potential(x,Vbump,0.5)"
   ]
  },
  {
   "cell_type": "markdown",
   "metadata": {},
   "source": [
    "### Solving for the eigenvalues\n",
    "\n",
    "Now that we have the potential, we need to build the matrix (remember that we have set $\\hbar = m = 1$):\n",
    "\n",
    "$H_{mn} = \\langle \\phi_m \\vert -\\frac{1}{2}\\nabla^2 + \\hat{V}\\vert\\phi_n\\rangle$\n",
    "\n",
    "By diagonalisation, we will find the eigenvalues.\n",
    "\n",
    "It's worth noting that we act with $\\hat{V}$ by multiplication in position representation:\n",
    "\n",
    "$$\\langle x \\vert \\hat{V} \\vert \\phi_m\\rangle = V(x) \\phi_m(x)$$\n",
    "\n",
    "We will print out the matrix of _just_ the potential first: this will be useful when thinking about perturbation theory (the change in eigenvalues should be the same as the diagonal elements of the potential matrix, to first order in the potential)."
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 14,
   "metadata": {
    "collapsed": false
   },
   "outputs": [
    {
     "name": "stdout",
     "output_type": "stream",
     "text": [
      "Potential matrix elements:\n",
      "   0.030    0.000   -0.030   -0.000    0.030    0.000   -0.030   -0.000    0.029    0.000\n",
      "   0.000    0.000   -0.000   -0.000    0.000    0.000   -0.000   -0.000    0.000    0.000\n",
      "  -0.030   -0.000    0.030    0.000   -0.030   -0.000    0.029    0.000   -0.029   -0.000\n",
      "  -0.000   -0.000    0.000    0.000   -0.000   -0.000    0.000    0.001   -0.000   -0.001\n",
      "   0.030    0.000   -0.030   -0.000    0.030    0.000   -0.029   -0.000    0.029    0.000\n",
      "   0.000    0.000   -0.000   -0.000    0.000    0.001   -0.000   -0.001    0.000    0.001\n",
      "  -0.030   -0.000    0.029    0.000   -0.029   -0.000    0.029    0.000   -0.029   -0.000\n",
      "  -0.000   -0.000    0.000    0.001   -0.000   -0.001    0.000    0.001   -0.000   -0.002\n",
      "   0.029    0.000   -0.029   -0.000    0.029    0.000   -0.029   -0.000    0.028    0.000\n",
      "   0.000    0.000   -0.000   -0.001    0.000    0.001   -0.000   -0.002    0.000    0.002\n",
      "\n",
      "Full Hamiltonian\n",
      "   4.965   -0.000   -0.030   -0.000    0.030    0.000   -0.030   -0.000    0.029   -0.000\n",
      "  -0.000   19.739    0.000   -0.000   -0.000    0.000    0.000   -0.000   -0.000    0.000\n",
      "  -0.030   -0.000   44.443    0.000   -0.030    0.000    0.029   -0.000   -0.029    0.000\n",
      "  -0.000   -0.000    0.000   78.957    0.000   -0.000   -0.000    0.001   -0.000   -0.001\n",
      "   0.030    0.000   -0.030    0.000  123.400    0.000   -0.029    0.000    0.029   -0.000\n",
      "   0.000    0.000    0.000   -0.000    0.000  177.654    0.000   -0.001    0.000    0.001\n",
      "  -0.030    0.000    0.029   -0.000   -0.029   -0.000  241.834   -0.000   -0.029   -0.000\n",
      "   0.000   -0.000   -0.000    0.001    0.000   -0.001   -0.000  315.829   -0.000   -0.002\n",
      "   0.029   -0.000   -0.029   -0.000    0.029    0.000   -0.029   -0.000  399.747    0.000\n",
      "  -0.000    0.000    0.000   -0.001   -0.000    0.001   -0.000   -0.002    0.000  493.482\n"
     ]
    }
   ],
   "source": [
    "# Declare space for the matrix elements - simplest with the identity function\n",
    "Hmat = np.eye(num_basis)\n",
    "\n",
    "# Define a function to act on a basis function with the potential\n",
    "def add_pot_on_basis(Hphi,V,phi):\n",
    "    for i in range(V.size):\n",
    "        Hphi[i] = Hphi[i] + V[i]*phi[i]\n",
    "        \n",
    "print \"Potential matrix elements:\"\n",
    "# Loop over basis functions phi_n (the bra in the matrix element)\n",
    "# Calculate and output matrix elements of the potential\n",
    "\n",
    "for n in range(num_basis):\n",
    "    # Loop over basis functions phi_m (the ket in the matrix element)\n",
    "    for m in range(num_basis):\n",
    "        # Act with H on phi_m and store in H_phi_m\n",
    "        H_phi_m = np.zeros(num_x_points)\n",
    "        add_pot_on_basis(H_phi_m,Vbump,basis_array[m])\n",
    "        # Create matrix element by integrating\n",
    "        H_mn = integrate_functions(basis_array[n],H_phi_m,num_x_points,dx)\n",
    "        # The comma at the end prints without a new line; the %8.3f formats the number\n",
    "        print \"%8.3f\" % H_mn,\n",
    "    # This print puts in a new line when we have finished looping over m\n",
    "    print\n",
    "\n",
    "print\n",
    "print \"Full Hamiltonian\"\n",
    "# Loop over basis functions phi_n (the bra in the matrix element)\n",
    "# Calculate and store the matrix elements for the full Hamiltonian\n",
    "for n in range(num_basis):\n",
    "    # Loop over basis functions phi_m (the ket in the matrix element)\n",
    "    for m in range(num_basis):\n",
    "        # Act with H on phi_m and store in H_phi_m\n",
    "        # First the kinetic energy\n",
    "        H_phi_m = -0.5*d2basis_array[m] \n",
    "        # Now the potential\n",
    "        add_pot_on_basis(H_phi_m,Vbump,basis_array[m])\n",
    "        # Create matrix element by integrating\n",
    "        H_mn = integrate_functions(basis_array[n],H_phi_m,num_x_points,dx)\n",
    "        Hmat[m,n] = H_mn\n",
    "        # The comma at the end prints without a new line; the %8.3f formats the number\n",
    "        print \"%8.3f\" % H_mn,\n",
    "    # This print puts in a new line when we have finished looping over m\n",
    "    print"
   ]
  },
  {
   "cell_type": "markdown",
   "metadata": {},
   "source": [
    "Notice that two things have changed compared to the perfect square well: first, the diagonal elements are _slightly_ larger; second, there are now off-diagonal elements.  Does it surprise that these alternate (i.e. only in odd row and columns) ? Think about the symmetries of the system, particularly of the wavefunctions.\n",
    "\n",
    "What effect will this have on the eigenvalues and eigenvectors ? We'll diagonalise, print out the eigenvalues and plot the first few eigenvectors (as well as looking at their coefficients to get a rough idea of how much they've changed)."
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 5,
   "metadata": {
    "collapsed": false
   },
   "outputs": [
    {
     "name": "stdout",
     "output_type": "stream",
     "text": [
      "[   4.9647   19.7393   44.443    78.9571  123.3996  177.6536  241.8344\n",
      "  315.8286  399.7474  493.4821]\n",
      "[  1.0000e+00  -2.0635e-17   7.5696e-04  -7.1521e-17  -2.5115e-04\n",
      "   7.7171e-17  -1.2461e-04   3.6019e-17  -7.3983e-05   5.9905e-17]\n",
      "[  2.2443e-17   1.0000e+00  -2.2204e-15  -2.6578e-06   2.2204e-16\n",
      "   1.4901e-06   5.5511e-17   1.0548e-06   3.8858e-16  -8.1916e-07]\n",
      "[  7.5708e-04  -2.2204e-15  -1.0000e+00  -3.4056e-16   3.7569e-04\n",
      "   1.3964e-16   1.4913e-04   1.0053e-16   8.1990e-05  -2.4266e-16]\n"
     ]
    }
   ],
   "source": [
    "# Solve using linalg module of numpy (which we've imported as la above)\n",
    "eigval, eigvec = la.eigh(Hmat)\n",
    "# This call above does the entire solution for the eigenvalues and eigenvectors !\n",
    "# Print results roughly, though apply precision of 4 to the printing\n",
    "np.set_printoptions(precision=4)\n",
    "print eigval\n",
    "print eigvec[0]\n",
    "print eigvec[1]\n",
    "print eigvec[2]"
   ]
  },
  {
   "cell_type": "markdown",
   "metadata": {},
   "source": [
    "We can see that the eigenvalues look close to the perfect well values (we'll check them properly below).  The eigenvector coefficients show a single dominant value (corresponding to the unchanged eigenvector), with very small contributions from other eigenvectors.  Now print the eigenvalues and calculate the change."
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 6,
   "metadata": {
    "collapsed": false
   },
   "outputs": [
    {
     "name": "stdout",
     "output_type": "stream",
     "text": [
      " Changed Original  Difference\n",
      "   4.965    4.935    0.030\n",
      "  19.739   19.739    0.000\n",
      "  44.443   44.413    0.030\n",
      "  78.957   78.957    0.000\n",
      " 123.400  123.370    0.030\n",
      " 177.654  177.653    0.001\n",
      " 241.834  241.805    0.029\n",
      " 315.829  315.827    0.001\n",
      " 399.747  399.719    0.028\n",
      " 493.482  493.480    0.002\n"
     ]
    }
   ],
   "source": [
    "# Now print out eigenvalues and the eigenvalues of the perfect square well, and the difference\n",
    "print \" Changed Original  Difference\"\n",
    "for i in range(num_basis):\n",
    "    n = i+1\n",
    "    print \"%8.3f %8.3f %8.3f\" % (eigval[i],n*n*np.pi*np.pi/2.0,eigval[i] - n*n*np.pi*np.pi/2.0)"
   ]
  },
  {
   "cell_type": "markdown",
   "metadata": {},
   "source": [
    "Compare the differences in eigenvalues due to the small potential we've added to the diagonal terms of the potential matrix.  How close is the agreement ? You might like to change the magnitude of the potential (higher up - it's passed as an argument to the potential function) and see how this agreement changes.\n",
    "\n",
    "Now we'll plot the eigenvectors (after building them) and look at the change with respect to the eigenvectors of the original system.  Remember that any function in this space can be written as:\n",
    "\n",
    "$$\\vert\\psi\\rangle = \\sum_i c_i \\vert \\phi_i \\rangle$$\n",
    "\n",
    "We'll use this to build the eigenfunctions of the perturbed system.  In this case, $c_i$ are the coefficients in the eigenvector of the matrix, and $\\vert\\phi_i\\rangle$ are the basis functions."
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 7,
   "metadata": {
    "collapsed": false
   },
   "outputs": [
    {
     "data": {
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AQ4S50A7t74G9QktpxxjjBpr7YGJXZgimHLcEh6KONGeiIavaoPY3jxhjWnkmMMZ0R1+k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\nMPkTZZiKKgAAAABJRU5ErkJggg==\n",
      "text/plain": [
       "<matplotlib.figure.Figure at 0x10a271610>"
      ]
     },
     "metadata": {},
     "output_type": "display_data"
    }
   ],
   "source": [
    "# Define a figure to take two plots\n",
    "fig = pl.figure(figsize=[12,3])\n",
    "# Add subplots: number in y, x, index number\n",
    "ax = fig.add_subplot(121,autoscale_on=False,xlim=(0,1),ylim=(-2,2))\n",
    "ax.set_title(\"Eigenvectors for changed system\")\n",
    "ax2 = fig.add_subplot(122,autoscale_on=False,xlim=(0,1),ylim=(-0.002,0.002))\n",
    "ax2.set_title(\"Difference to perfect eigenvectors\")\n",
    "for m in range(4): # Plot the first four states\n",
    "    psi = np.zeros(num_x_points)\n",
    "    for i in range(num_basis):\n",
    "        psi = psi+eigvec[i,m]*basis_array[i]\n",
    "    if eigvec[m,m] < 0:  # This is just to ensure that psi and the basis function have the same phase\n",
    "        psi = -psi\n",
    "    ax.plot(x,psi)\n",
    "    psi = psi - basis_array[m]\n",
    "    ax2.plot(x,psi)\n"
   ]
  },
  {
   "cell_type": "markdown",
   "metadata": {},
   "source": [
    "Notice how the eigenvectors for this changed system are *very* close to the original system.  This is a perfect example of a good system to study with perturbation theory.  The changes in the eigenvectors can be related to matrix elements of the potential, but we won't do this just yet."
   ]
  },
  {
   "cell_type": "markdown",
   "metadata": {},
   "source": [
    "## A more drastic change in the potential\n",
    "\n",
    "Now let's try a more significant change to the potential.  It will be instructive to place a quantum harmonic oscillator potential into our square well, and then build the Hamiltonian, again using the square well eigenvectors as a basis set.  We will look at two cases: first, a small magnitude for the potential (a small perturbation, where we would expect to see small changes in the square well energies); second, a large magnitude for the potential (where the first few eigenstates should be very close to the QHO eigenstates)."
   ]
  },
  {
   "cell_type": "markdown",
   "metadata": {},
   "source": [
    "### Small perturbation - close to square well"
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 16,
   "metadata": {
    "collapsed": false
   },
   "outputs": [
    {
     "data": {
      "image/png": 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Ngf8DnnX3G9dyfq3IzTFPPRUW3IwZE2b3SHFavhyOOSZMx3zwwdAhkNyRyRW5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\nWHFyAAAAAElFTkSuQmCC\n",
      "text/plain": [
       "<matplotlib.figure.Figure at 0x10baa8090>"
      ]
     },
     "metadata": {},
     "output_type": "display_data"
    }
   ],
   "source": [
    "# Define the potential in the square well\n",
    "def square_well_potential2(x,V,a):\n",
    "    \"\"\"QHO Potential for a particle in a square well, expecting two arrays: x, V(x), and potential height, a\"\"\"\n",
    "    # Note that we offset x so that the QHO well is centred on the square well\n",
    "    for i in range(x.size):\n",
    "        V[i] = 0.5*a*(x[i]-0.5)**2 \n",
    "    # Plot to ensure that we know what we're getting\n",
    "    pl.plot(x,V)\n",
    "    \n",
    "omega = 1.0\n",
    "omega2 = omega*omega\n",
    "VbumpQHO = np.linspace(0.0,width,num_x_points)\n",
    "pot_bump = square_well_potential2(x,VbumpQHO,omega2)"
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 18,
   "metadata": {
    "collapsed": false
   },
   "outputs": [
    {
     "name": "stdout",
     "output_type": "stream",
     "text": [
      "   4.951   -0.000    0.019    0.000    0.004    0.000    0.001   -0.000    0.001   -0.000\n",
      "   0.000   19.775   -0.000    0.023    0.000    0.005    0.000    0.002   -0.000    0.001\n",
      "   0.019    0.000   44.452   -0.000    0.024    0.000    0.005   -0.000    0.002    0.000\n",
      "   0.000    0.023    0.000   78.997    0.000    0.024   -0.000    0.006   -0.000    0.002\n",
      "   0.004    0.000    0.024    0.000  123.411    0.000    0.025    0.000    0.006    0.000\n",
      "   0.000    0.005    0.000    0.024    0.000  177.694    0.000    0.025    0.000    0.006\n",
      "   0.001    0.000    0.005   -0.000    0.025   -0.000  241.846   -0.000    0.025   -0.000\n",
      "  -0.000    0.002   -0.000    0.006    0.000    0.025   -0.000  315.869   -0.000    0.025\n",
      "   0.001   -0.000    0.002   -0.000    0.006    0.000    0.025   -0.000  399.760   -0.000\n",
      "  -0.000    0.001    0.000    0.002   -0.000    0.006   -0.000    0.025   -0.000  493.522\n",
      "Perturbation matrix elements:\n",
      "   0.016   -0.000    0.019    0.000    0.004    0.000    0.001    0.000    0.001    0.000\n",
      "  -0.000    0.035   -0.000    0.023   -0.000    0.005   -0.000    0.002   -0.000    0.001\n",
      "   0.019   -0.000    0.039   -0.000    0.024    0.000    0.005    0.000    0.002    0.000\n",
      "   0.000    0.023   -0.000    0.040   -0.000    0.024   -0.000    0.006   -0.000    0.002\n",
      "   0.004   -0.000    0.024   -0.000    0.041    0.000    0.025    0.000    0.006   -0.000\n",
      "   0.000    0.005    0.000    0.024    0.000    0.041   -0.000    0.025   -0.000    0.006\n",
      "   0.001   -0.000    0.005   -0.000    0.025   -0.000    0.041   -0.000    0.025   -0.000\n",
      "  -0.000    0.002    0.000    0.006    0.000    0.025   -0.000    0.041   -0.000    0.025\n",
      "   0.001   -0.000    0.002   -0.000    0.006   -0.000    0.025   -0.000    0.041   -0.000\n",
      "   0.000    0.001    0.000    0.002   -0.000    0.006   -0.000    0.025   -0.000    0.041\n",
      "\n",
      "Eigenvalues and eigenvector coefficients printed roughly\n",
      "[   4.9511   19.7745   44.4521   78.9969  123.4107  177.6938  241.8465\n",
      "  315.8686  399.7603  493.5216]\n",
      "[  1.0000e+00   8.6777e-17   4.8092e-04   9.0367e-17   2.9745e-05\n",
      "  -7.7613e-17   5.2026e-06  -4.4090e-17  -1.4445e-06  -4.9296e-17]\n",
      "[  8.6574e-17  -1.0000e+00   3.3307e-16   3.8017e-04  -2.7756e-17\n",
      "  -3.0108e-05  -4.1633e-17   6.0876e-06   4.4409e-16   1.8574e-06]\n",
      "[ -4.8092e-04   2.2204e-16   1.0000e+00  -2.3945e-16   3.0075e-04\n",
      "  -1.4811e-16   2.6972e-05  -1.2955e-16  -5.9446e-06   2.8739e-16]\n",
      "\n",
      " QHO Square  Perfect QHO  Difference  Perfect Square Difference\n",
      "      4.951        0.500       4.451           4.935      0.016\n",
      "     19.775        1.500      18.275          19.739      0.035\n",
      "     44.452        2.500      41.952          44.413      0.039\n",
      "     78.997        3.500      75.497          78.957      0.040\n",
      "    123.411        4.500     118.911         123.370      0.041\n",
      "    177.694        5.500     172.194         177.653      0.041\n",
      "    241.846        6.500     235.346         241.805      0.041\n",
      "    315.869        7.500     308.369         315.827      0.041\n",
      "    399.760        8.500     391.260         399.719      0.041\n",
      "    493.522        9.500     484.022         493.480      0.041\n"
     ]
    }
   ],
   "source": [
    "# Declare space for the matrix elements\n",
    "Hmat2 = np.eye(num_basis)\n",
    "\n",
    "# Loop over basis functions phi_n (the bra in the matrix element)\n",
    "for n in range(num_basis):\n",
    "    # Loop over basis functions phi_m (the ket in the matrix element)\n",
    "    for m in range(num_basis):\n",
    "        # Act with H on phi_m and store in H_phi_m\n",
    "        H_phi_m = -0.5*d2basis_array[m] \n",
    "        add_pot_on_basis(H_phi_m,VbumpQHO,basis_array[m])\n",
    "        # Create matrix element by integrating\n",
    "        Hmat2[m,n] = integrate_functions(basis_array[n],H_phi_m,num_x_points,dx)\n",
    "        # The comma at the end prints without a new line; the %8.3f formats the number\n",
    "        print \"%8.3f\" % Hmat2[m,n],\n",
    "    # This print puts in a new line when we have finished looping over m\n",
    "    print\n",
    "    \n",
    "print \"Perturbation matrix elements:\"\n",
    "# Output the matrix elements of the potential to see how large the perturbation is\n",
    "# Loop over basis functions phi_n (the bra in the matrix element)\n",
    "for n in range(num_basis):\n",
    "    # Loop over basis functions phi_m (the ket in the matrix element)\n",
    "    for m in range(num_basis):\n",
    "        # Act with H on phi_m and store in H_phi_m\n",
    "        H_phi_m = np.zeros(num_x_points)\n",
    "        add_pot_on_basis(H_phi_m,VbumpQHO,basis_array[m])\n",
    "        # Create matrix element by integrating\n",
    "        H_mn = integrate_functions(basis_array[n],H_phi_m,num_x_points,dx)\n",
    "        # The comma at the end prints without a new line; the %8.3f formats the number\n",
    "        print \"%8.3f\" % H_mn,\n",
    "    # This print puts in a new line when we have finished looping over m\n",
    "    print\n",
    "    \n",
    "# Solve using linalg module of numpy (which we've imported as la above)\n",
    "eigval, eigvec = la.eigh(Hmat2)\n",
    "# This call above does the entire solution for the eigenvalues and eigenvectors !\n",
    "# Print results roughly, though apply precision of 4 to the printing\n",
    "print\n",
    "print \"Eigenvalues and eigenvector coefficients printed roughly\"\n",
    "np.set_printoptions(precision=4)\n",
    "print eigval\n",
    "print eigvec[0]\n",
    "print eigvec[1]\n",
    "print eigvec[2]\n",
    "print\n",
    "\n",
    "print \" QHO Square  Perfect QHO  Difference  Perfect Square Difference\"\n",
    "for i in range(num_basis):\n",
    "    n = i+1\n",
    "    print \"   %8.3f     %8.3f    %8.3f        %8.3f   %8.3f\" % (eigval[i],omega*(i+0.5),eigval[i] - omega*(i+0.5),n*n*np.pi*np.pi/2.0,eigval[i] - n*n*np.pi*np.pi/2.0)"
   ]
  },
  {
   "cell_type": "markdown",
   "metadata": {},
   "source": [
    "Notice how the eigenvalues are almost the same as for the square well.  More interestingly, the change in the eigenvalues is given by the diagonal elements of the matrix of the potential - which is exactly what we would expect from first order perturbation theory.  You could explore how well this holds, by gradually increasing omega (and we could also code second order changes in the energy for greater accuracy, but we won't for now).\n",
    "\n",
    "Now we will plot the eigenvectors, and the difference between the eigenvectors with this small perturbation, and the unperturbed eigenvectors (the basis functions)."
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 10,
   "metadata": {
    "collapsed": false
   },
   "outputs": [
    {
     "data": {
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PuyBLjfdRB8DxFDcVJQVr2kByTafQGpIqDyS3GC/aBSG5Wh0eS/KwsS51f20AzDZclE4r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\n",
      "text/plain": [
       "<matplotlib.figure.Figure at 0x10c6c1e10>"
      ]
     },
     "metadata": {},
     "output_type": "display_data"
    }
   ],
   "source": [
    "from scipy.special import hermite\n",
    "from scipy.misc import factorial\n",
    "from math import pi\n",
    "root_pi = np.sqrt(pi)\n",
    "def N(n, alpha):\n",
    "    return np.sqrt(alpha / (root_pi * (2.0**n) * factorial(n)))\n",
    "def phi(x,n,alpha):\n",
    "    return N(n,alpha) * hermite(n)(alpha * x) * np.exp(-0.5 * alpha**2 * x**2)\n",
    "\n",
    "x2 = np.linspace(-width/2,width/2,num_x_points)\n",
    "#pl.plot(x,phi(x2,1,np.sqrt(np.sqrt(omega))))\n",
    "\n",
    "# Define a figure to take two plots\n",
    "fig3 = pl.figure(figsize=[12,3])\n",
    "# Add subplots: number in y, x, index number\n",
    "axb = fig3.add_subplot(121,autoscale_on=False,xlim=(0,1),ylim=(-2.1,2.1))\n",
    "axb.set_title(\"Eigenvectors for perturbed system\")\n",
    "axb2 = fig3.add_subplot(122,autoscale_on=False,xlim=(0,1),ylim=(-0.001,0.001))\n",
    "axb2.set_title(\"QHO eigenvectors\")\n",
    "#axb2.set_title(\"Difference to QHO eigenvectors\")\n",
    "for m in range(3): # Plot the first four states\n",
    "    psi = np.zeros(num_x_points)\n",
    "    for i in range(num_basis):\n",
    "        psi = psi+eigvec[i,m]*basis_array[i]\n",
    "    if 2*(m/2)!=m:  # This is just to ensure that psi and the basis function have the same phase\n",
    "        psi = -psi\n",
    "    axb.plot(x,psi)\n",
    "    psi = psi - basis_array[m]\n",
    "    #psi = psi - phi(x2,m,np.sqrt(omega))\n",
    "    axb2.plot(x,psi)"
   ]
  },
  {
   "cell_type": "markdown",
   "metadata": {},
   "source": [
    "As we would expect, the eigenvectors are almost unchanged."
   ]
  },
  {
   "cell_type": "markdown",
   "metadata": {},
   "source": [
    "### Large perturbation - approximate QHO\n",
    "\n",
    "Now we will go beyond a small perturbation, by making the QHO potential much stronger.  We have to be a little careful how we do this: we'll see the effects of making the potential *too* strong lower down."
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 19,
   "metadata": {
    "collapsed": false
   },
   "outputs": [
    {
     "name": "stdout",
     "output_type": "stream",
     "text": [
      "  45.776   -0.000   47.494    0.000    8.795    0.000    3.078   -0.000    1.425   -0.000\n",
      "  -0.000  108.074    0.000   56.290   -0.000   11.874    0.000    4.503   -0.000    2.199\n",
      "  47.494   -0.000  141.544    0.000   59.368    0.000   13.298   -0.000    5.277    0.000\n",
      "  -0.000   56.290   -0.000  179.166    0.000   60.793   -0.000   14.072   -0.000    5.744\n",
      "   8.795   -0.000   59.368   -0.000  225.004   -0.000   61.567    0.000   14.539   -0.000\n",
      "   0.000   11.874    0.000   60.793   -0.000  280.060   -0.000   62.033    0.000   14.842\n",
      "   3.078   -0.000   13.298   -0.000   61.567    0.000  344.679   -0.000   62.336   -0.000\n",
      "  -0.000    4.503   -0.000   14.072    0.000   62.033   -0.000  419.004   -0.000   62.544\n",
      "   1.425   -0.000    5.277   -0.000   14.539   -0.000   62.336   -0.000  503.104    0.000\n",
      "   0.000    2.199    0.000    5.744   -0.000   14.842   -0.000   62.544   -0.000  597.013\n",
      "Perturbation matrix elements:\n",
      "  40.841   -0.000   47.494   -0.000    8.795    0.000    3.078   -0.000    1.425    0.000\n",
      "  -0.000   88.335   -0.000   56.290   -0.000   11.874   -0.000    4.503   -0.000    2.199\n",
      "  47.494   -0.000   97.130   -0.000   59.368    0.000   13.298    0.000    5.277    0.000\n",
      "  -0.000   56.290   -0.000  100.209    0.000   60.793   -0.000   14.072   -0.000    5.744\n",
      "   8.795   -0.000   59.368   -0.000  101.634    0.000   61.567    0.000   14.539   -0.000\n",
      "   0.000   11.874    0.000   60.793    0.000  102.407   -0.000   62.033   -0.000   14.842\n",
      "   3.078   -0.000   13.298   -0.000   61.567   -0.000  102.874   -0.000   62.336   -0.000\n",
      "  -0.000    4.503    0.000   14.072    0.000   62.033   -0.000  103.177   -0.000   62.544\n",
      "   1.425   -0.000    5.277   -0.000   14.539   -0.000   62.336   -0.000  103.385   -0.000\n",
      "   0.000    2.199    0.000    5.744   -0.000   14.842   -0.000   62.544   -0.000  103.533\n",
      "\n",
      "Eigenvalues and eigenvector coefficients printed roughly\n",
      "[  25.0007   75.0161  125.1641  175.9898  228.9861  286.5714  351.5116\n",
      "  424.9498  529.4435  620.7907]\n",
      "[  9.0718e-01  -3.3793e-16   3.8803e-01  -1.6177e-16   1.5570e-01\n",
      "   1.0364e-16   4.5610e-02   4.1753e-17  -1.1746e-02  -3.7238e-17]\n",
      "[ -2.2204e-16  -8.4746e-01  -3.3307e-16  -4.9390e-01  -6.6613e-16\n",
      "   1.8744e-01  -5.5511e-17   5.0480e-02   4.1633e-16   1.3696e-02]\n",
      "[ -4.1202e-01  -3.3307e-16   7.4170e-01  -3.3307e-16   4.9802e-01\n",
      "   1.3878e-16   1.7329e-01   9.0206e-17  -4.5479e-02   1.8041e-16]\n",
      "\n",
      " QHO Square  Perfect QHO  Difference  Perfect Square Difference\n",
      "     25.001       25.000       0.001           4.935     20.066\n",
      "     75.016       75.000       0.016          19.739     55.277\n",
      "    125.164      125.000       0.164          44.413     80.751\n",
      "    175.990      175.000       0.990          78.957     97.033\n",
      "    228.986      225.000       3.986         123.370    105.616\n",
      "    286.571      275.000      11.571         177.653    108.919\n",
      "    351.512      325.000      26.512         241.805    109.706\n",
      "    424.950      375.000      49.950         315.827    109.122\n",
      "    529.443      425.000     104.443         399.719    129.724\n",
      "    620.791      475.000     145.791         493.480    127.310\n"
     ]
    },
    {
     "data": {
      "image/png": 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      "text/plain": [
       "<matplotlib.figure.Figure at 0x10b9e7b10>"
      ]
     },
     "metadata": {},
     "output_type": "display_data"
    }
   ],
   "source": [
    "# Make omega larger, so that the QHO energy dominates the square well\n",
    "omegaL = 50.0\n",
    "omegaL2 = omegaL*omegaL\n",
    "VbumpQHO2 = np.linspace(0.0,width,num_x_points)\n",
    "pot_bump = square_well_potential2(x,VbumpQHO2,omegaL2)\n",
    "\n",
    "# Declare space for the matrix elements\n",
    "Hmat3 = np.eye(num_basis)\n",
    "\n",
    "# Loop over basis functions phi_n (the bra in the matrix element)\n",
    "for n in range(num_basis):\n",
    "    # Loop over basis functions phi_m (the ket in the matrix element)\n",
    "    for m in range(num_basis):\n",
    "        # Act with H on phi_m and store in H_phi_m\n",
    "        H_phi_m = -0.5*d2basis_array[m] \n",
    "        add_pot_on_basis(H_phi_m,VbumpQHO2,basis_array[m])\n",
    "        # Create matrix element by integrating\n",
    "        Hmat3[m,n] = integrate_functions(basis_array[n],H_phi_m,num_x_points,dx)\n",
    "        # The comma at the end prints without a new line; the %8.3f formats the number\n",
    "        print \"%8.3f\" % Hmat3[m,n],\n",
    "    # This print puts in a new line when we have finished looping over m\n",
    "    print\n",
    "    \n",
    "print \"Perturbation matrix elements:\"\n",
    "# Loop over basis functions phi_n (the bra in the matrix element)\n",
    "for n in range(num_basis):\n",
    "    # Loop over basis functions phi_m (the ket in the matrix element)\n",
    "    for m in range(num_basis):\n",
    "        # Act with H on phi_m and store in H_phi_m\n",
    "        H_phi_m = np.zeros(num_x_points)\n",
    "        add_pot_on_basis(H_phi_m,VbumpQHO2,basis_array[m])\n",
    "        # Create matrix element by integrating\n",
    "        H_mn = integrate_functions(basis_array[n],H_phi_m,num_x_points,dx)\n",
    "        # The comma at the end prints without a new line; the %8.3f formats the number\n",
    "        print \"%8.3f\" % H_mn,\n",
    "    # This print puts in a new line when we have finished looping over m\n",
    "    print\n",
    "    \n",
    "# Solve using linalg module of numpy (which we've imported as la above)\n",
    "eigval, eigvec = la.eigh(Hmat3)\n",
    "# This call above does the entire solution for the eigenvalues and eigenvectors !\n",
    "# Print results roughly, though apply precision of 4 to the printing\n",
    "print\n",
    "print \"Eigenvalues and eigenvector coefficients printed roughly\"\n",
    "np.set_printoptions(precision=4)\n",
    "print eigval\n",
    "print eigvec[0]\n",
    "print eigvec[1]\n",
    "print eigvec[2]\n",
    "print\n",
    "\n",
    "print \" QHO Square  Perfect QHO  Difference  Perfect Square Difference\"\n",
    "for i in range(num_basis):\n",
    "    n = i+1\n",
    "    print \"   %8.3f     %8.3f    %8.3f        %8.3f   %8.3f\" % (eigval[i],omegaL*(i+0.5),eigval[i] - omegaL*(i+0.5),n*n*np.pi*np.pi/2.0,eigval[i] - n*n*np.pi*np.pi/2.0)"
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 12,
   "metadata": {
    "collapsed": false
   },
   "outputs": [
    {
     "data": {
      "image/png": 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sCMIAt5a4lV/6/cJDcx5i88nN2UrjGsqUkdGMkSPFj57BYDAYDLkUoxn2BCdP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\n/weDA9JKPufdzgAAAABJRU5ErkJggg==\n",
      "text/plain": [
       "<matplotlib.figure.Figure at 0x10bc58b10>"
      ]
     },
     "metadata": {},
     "output_type": "display_data"
    }
   ],
   "source": [
    "# Define a figure to take two plots\n",
    "fig4 = pl.figure(figsize=[12,3])\n",
    "# Add subplots: number in y, x, index number\n",
    "axc = fig4.add_subplot(121,autoscale_on=False,xlim=(0,1),ylim=(-2.1,2.1))\n",
    "axc.set_title(\"Eigenvectors for perturbed system\")\n",
    "axc2 = fig4.add_subplot(122,autoscale_on=False,xlim=(0,1),ylim=(-0.1,0.1))\n",
    "#axc2.set_title(\"QHO eigenvectors\")\n",
    "axc2.set_title(\"Difference to QHO eigenvectors\")\n",
    "for m in range(3): # Plot the first four states\n",
    "    psi = np.zeros(num_x_points)\n",
    "    for i in range(num_basis):\n",
    "        psi = psi+eigvec[i,m]*basis_array[i]\n",
    "    #if 2*(m/2)!=m:  # This is just to ensure that psi and the basis function have the same phase\n",
    "    #    psi = -psi\n",
    "    axc.plot(x,psi)\n",
    "    psi = psi - phi(x2,m,np.sqrt(omegaL))\n",
    "    axc2.plot(x,psi)"
   ]
  },
  {
   "cell_type": "markdown",
   "metadata": {
    "collapsed": true
   },
   "source": [
    "Now we can see two things:\n",
    "\n",
    "* For the lower eigenvalues, the energy is almost a perfect match to the QHO, and the eigenvectors are also an excellent match (except at the edges, where the hard walls of the square well will have an effect)\n",
    "* For the higher eigenvalues, once the energy is within 10-20% of the energy at the top of the QHO potential, the eigenvalues diverge strongly \n",
    "\n",
    "This second result comes about when the perturbation (the QHO well) becomes comparable to the square well energy.  If we went higher in energy, we'd gradually recover the square well eigenvalues."
   ]
  },
  {
   "cell_type": "markdown",
   "metadata": {},
   "source": [
    "## Basis set size\n",
    "\n",
    "We'll now see the problem with using a finite basis set (we defined `num_basis`, the number of basis functions to include, as 10 above, to make matrices a sensible size).  If we make the QHO potential *huge* compared to the square well eigenvalues, we'll find that the resulting eigenfunctions are very compressed, and that our ten square well eigenstates are not enough to properly represent them.  \n",
    "\n",
    "The calculation takes the usual form: define a potential; form a Hamiltonian matrix (we won't print the potential matrix this time); diagonalise; analyse the results."
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 23,
   "metadata": {
    "collapsed": false
   },
   "outputs": [
    {
     "name": "stdout",
     "output_type": "stream",
     "text": [
      "4089.027    0.000 4749.429   -0.000  879.522    0.000  307.831   -0.000  142.479    0.000\n",
      "  -0.000 8853.261   -0.000 5628.951   -0.000 1187.353   -0.000  450.310   -0.000  219.873\n",
      "4749.429   -0.000 9757.457    0.000 5936.782    0.000 1329.832    0.000  527.703    0.000\n",
      "  -0.000 5628.951   -0.000 10099.831   -0.000 6079.261   -0.000 1407.225   -0.000  574.367\n",
      " 879.522   -0.000 5936.782    0.000 10286.723   -0.000 6156.655   -0.000 1453.889   -0.000\n",
      "   0.000 1187.353    0.000 6079.261   -0.000 10418.400   -0.000 6203.318   -0.000 1484.172\n",
      " 307.831   -0.000 1329.832   -0.000 6156.655   -0.000 10529.215   -0.000 6233.601   -0.000\n",
      "  -0.000  450.310    0.000 1407.225   -0.000 6203.318   -0.000 10633.521   -0.000 6254.361\n",
      " 142.479   -0.000  527.703   -0.000 1453.889   -0.000 6233.601   -0.000 10738.172   -0.000\n",
      "   0.000  219.873    0.000  574.367   -0.000 1484.172   -0.000 6254.361   -0.000 10846.779\n",
      " QHO Square  Perfect QHO  Difference\n",
      "    341.200      250.000      91.200\n",
      "   1091.149      750.000     341.149\n",
      "   2607.504     1250.000    1357.504\n",
      "   3836.361     1750.000    2086.361\n",
      "   6937.708     2250.000    4687.708\n",
      "   8364.067     2750.000    5614.067\n",
      "   13428.721     3250.000    10178.721\n",
      "   14703.795     3750.000    10953.795\n",
      "   22085.462     4250.000    17835.462\n",
      "   22856.419     4750.000    18106.419\n"
     ]
    },
    {
     "data": {
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PBWSbbUKb7VFHwX77wZVXxh2RyCYPPhgmsL3+OtTWJ1OsdPkLzE47wfPPwy9/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\n",
      "text/plain": [
       "<matplotlib.figure.Figure at 0x10d5a3c50>"
      ]
     },
     "metadata": {},
     "output_type": "display_data"
    }
   ],
   "source": [
    "# Make omega larger, so that the QHO energy dominates the square well\n",
    "omegaH = 500.0\n",
    "omegaH2 = omegaH*omegaH\n",
    "VbumpQHO3 = np.linspace(0.0,width,num_x_points)\n",
    "pot_bump = square_well_potential2(x,VbumpQHO3,omegaH2)\n",
    "\n",
    "# Declare space for the matrix elements\n",
    "Hmat4 = np.eye(num_basis)\n",
    "\n",
    "# Loop over basis functions phi_n (the bra in the matrix element)\n",
    "for n in range(num_basis):\n",
    "    # Loop over basis functions phi_m (the ket in the matrix element)\n",
    "    for m in range(num_basis):\n",
    "        # Act with H on phi_m and store in H_phi_m\n",
    "        H_phi_m = -0.5*d2basis_array[m] \n",
    "        add_pot_on_basis(H_phi_m,VbumpQHO3,basis_array[m])\n",
    "        # Create matrix element by integrating\n",
    "        Hmat4[m,n] = integrate_functions(basis_array[n],H_phi_m,num_x_points,dx)\n",
    "        # The comma at the end prints without a new line; the %8.3f formats the number\n",
    "        print \"%8.3f\" % Hmat4[m,n],\n",
    "    # This print puts in a new line when we have finished looping over m\n",
    "    print\n",
    "    \n",
    "# Solve using linalg module of numpy (which we've imported as la above)\n",
    "eigval, eigvec = la.eigh(Hmat4)\n",
    "print \" QHO Square  Perfect QHO  Difference\"\n",
    "for i in range(num_basis):\n",
    "    n = i+1\n",
    "    print \"   %8.3f     %8.3f    %8.3f\" % (eigval[i],omegaH*(i+0.5),eigval[i] - omegaH*(i+0.5))"
   ]
  },
  {
   "cell_type": "markdown",
   "metadata": {},
   "source": [
    "Here's the first clue that we have a problem: the eigenvalues from the matrix using the limited square well basis set are too high.  They are in significant error.  Let's plot the resulting eigenfunctions, along with the perfect eigenfunctions, to compare.  (As before, don't worry about the minus sign in the functions - this is just a phase.)"
   ]
  },
  {
   "cell_type": "code",
   "execution_count": 32,
   "metadata": {
    "collapsed": false
   },
   "outputs": [
    {
     "data": {
      "image/png": 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IGJ1tvtuFeMwTJwqPPebe2M6dhX/+KX3HXJJf5fGY3cHjmGFrxYTN6Jp9n4rIBk/nNBgM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\natECmjZ1pvMGqVuDbnz67aeezBvOzIT334c77gjtvrfWvaW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LPvoIFixwCuDMTOje3SmM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\nB7RucC1NBKUwAAAAAElFTkSuQmCC\n",
      "text/plain": [
       "<matplotlib.figure.Figure at 0x10bdb7e90>"
      ]
     },
     "metadata": {},
     "output_type": "display_data"
    }
   ],
   "source": [
    "# Define a figure to take two plots\n",
    "fig5 = pl.figure(figsize=[12,3])\n",
    "# Add subplots: number in y, x, index number\n",
    "axd = fig5.add_subplot(121,autoscale_on=False,xlim=(0,1),ylim=(-3.1,3.1))\n",
    "axd.set_title(\"Eigenvectors for perturbed system\")\n",
    "axd2 = fig5.add_subplot(122,autoscale_on=False,xlim=(0,1),ylim=(-3.1,3.1))\n",
    "#axc2.set_title(\"QHO eigenvectors\")\n",
    "axd2.set_title(\"QHO eigenvectors\")\n",
    "for m in range(3): # Plot the first four states\n",
    "    psi = np.zeros(num_x_points)\n",
    "    for i in range(num_basis):\n",
    "        psi = psi+eigvec[i,m]*basis_array[i]\n",
    "    if 2*(m/2)!=m:  # This is just to ensure that psi and the basis function have the same phase\n",
    "        psi = -psi\n",
    "    axd.plot(x,psi)\n",
    "    #psi = psi - phi(x2,m,np.sqrt(omegaH))\n",
    "    #axd2.plot(x,psi)\n",
    "    axd2.plot(x,phi(x2,m,np.sqrt(omegaH)))"
   ]
  },
  {
   "cell_type": "markdown",
   "metadata": {},
   "source": [
    "Here we see the problem: the sum over the basis functions (left graph) contains ringing.  We would need to include many more basis functions to correctly represent these rapidly varying functions (if you remember Fourier analysis, you might like to think about what this means in terms of Fourier analysis).\n",
    "\n",
    "Feel free to play with `num_basis` and see how the agreement improves with basis size."
   ]
  },
  {
   "cell_type": "code",
   "execution_count": null,
   "metadata": {
    "collapsed": true
   },
   "outputs": [],
   "source": []
  }
 ],
 "metadata": {
  "kernelspec": {
   "display_name": "Python 2",
   "language": "python",
   "name": "python2"
  },
  "language_info": {
   "codemirror_mode": {
    "name": "ipython",
    "version": 2
   },
   "file_extension": ".py",
   "mimetype": "text/x-python",
   "name": "python",
   "nbconvert_exporter": "python",
   "pygments_lexer": "ipython2",
   "version": "2.7.10"
  }
 },
 "nbformat": 4,
 "nbformat_minor": 0
}