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"# CDS: Numerical Methods Assignments\n",
"\n",
"- See lecture notes and documentation on Brightspace for Python and Jupyter basics. If you are stuck, try to google or get in touch via Discord.\n",
"\n",
"- Solutions must be submitted via the Jupyter Hub.\n",
"\n",
"- Make sure you fill in any place that says `YOUR CODE HERE` or \"YOUR ANSWER HERE\".\n",
"\n",
"## Submission\n",
"\n",
"1. Name all team members in the the cell below\n",
"2. make sure everything runs as expected\n",
"3. **restart the kernel** (in the menubar, select Kernel$\\rightarrow$Restart)\n",
"4. **run all cells** (in the menubar, select Cell$\\rightarrow$Run All)\n",
"5. Check all outputs (Out[\\*]) for errors and **resolve them if necessary**\n",
"6. submit your solutions **in time (before the deadline)**"
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"source": [
"## Eigenvalues and Eigenvectors\n",
"\n",
"In the following you will implement your own eigenvalue / eigenvector calculation routines based on the inverse power method and the iterated QR decomposition."
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"# Import packages here ...\n",
"\n",
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"### Task 1\n",
"We start by implementing the inverse power method, which calculates the eigenvector corresponding to an eigenvalue which is closest to a given parameter $\\sigma$. In detail, you should implement a Python function $\\text{inversePower(A, sigma, eps)}$, which takes as input the $n \\times n$ square matrix $A$, the parameter $\\sigma$, as well as some accuracy $\\varepsilon$. It should return the eigenvector $\\mathbf{v}$ (corresponding to the eigenvalue which is closest to $\\sigma$) and the number of needed iteration steps.\n",
"\t\n",
"To do so, implement the following algorithm. Start by setting up the needed input:\n",
"\n",
"\\begin{align}\n",
" B &= \\left( A - \\sigma \\mathbf{1} \\right)^{-1} \\\\\n",
" \\mathbf{b}^{(0)} &= (1,1,1,...)\n",
"\\end{align}\n",
"\n",
"where $\\mathbf{b}^{(0)}$ is a vector with $n$ entries. Then repeat the following and increase $k$ each iteration until the error $e$ is smaller than $\\varepsilon$:\n",
"\n",
"\\begin{align}\n",
" \\mathbf{b}^{(k)} &= B \\cdot \\mathbf{b}^{(k-1)} \\\\\n",
" \\mathbf{b}^{(k)} &= \\frac{\\mathbf{b}^{(k)}}{|\\mathbf{b}^{(k)}|} \\\\\n",
" e &= \\sqrt{ \\sum_{i=0}^n \\left(|b_i^{(k-1)}| - |b_i^{(k)}|\\right)^2 }\n",
"\\end{align}\n",
"\n",
"Return the last vector $\\mathbf{b}^{(k)}$ and the number of needed iterations $k$. \n",
"\n",
"Verify your implementation by calculating all the eigenvectors of the matrix below and comparing them to the ones calculated by $\\text{numpy.linalg.eig()}$. Then implement a unit test for your function.\n",
"\n",
"\\begin{align*}\n",
" A = \\begin{pmatrix}\n",
" 3 & 2 & 1\\\\ \n",
" 2 & 3 & 2\\\\\n",
" 1 & 2 & 3\n",
" \\end{pmatrix}.\n",
"\\end{align*}"
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"def inversePower(A, sigma, eps):\n",
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"def test_inversePower():\n",
" # YOUR CODE HERE\n",
" raise NotImplementedError()\n",
" \n",
"test_inversePower()"
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"### Task 2 \n",
"\n",
"Next you will need to implement the tri-diagonalization scheme following Householder. To this end implement a Python function $\\text{tridiagonalize(A)}$ which takes a symmetric matrix $A$ as input and returns a tridiagonal matrix $T$ of the same dimension. Therefore, your algorithm should execute the following steps:\n",
"\t\n",
"First use an assertion to make sure $A$ is symmetric. Then let $k$ run from $0$ to $n-1$ and repeat the following:\n",
"\n",
"\\begin{align}\n",
" q &= \\sqrt{ \\sum_{j=k+1}^n \\left(A_{j,k}\\right)^2 } \\\\\n",
" \\alpha &= -\\operatorname{sgn}(A_{k+1,k}) \\cdot q \\\\\n",
" r &= \\sqrt{ \\frac{ \\alpha^2 - A_{k+1,k} \\cdot \\alpha }{2} } \\\\\n",
" \\mathbf{v} &= \\mathbf{0} \\qquad \\text{... vector of dimension } n \\\\\n",
" v_{k+1} &= \\frac{A_{k+1,k} - \\alpha}{2r} \\\\\n",
" v_{k+j} &= \\frac{A_{k+j,k}}{2r} \\quad \\text{for } j=2,3,\\dots,n \\\\\n",
" P &= \\mathbf{1} - 2 \\mathbf{v}\\mathbf{v}^T \\\\\n",
" A &= P \\cdot A \\cdot P\n",
"\\end{align}\n",
"\n",
"At the end return $A$ as $T$.\n",
"\n",
"Apply your routine to the matrix $A$ defined in task 1 as well as to a few random (but symmetric) matrices of different dimension $n$.\n",
"\n",
"Hint: Use $\\text{np.outer()}$ to calculate the *matrix* $\\mathbf{v}\\mathbf{v}^T$ needed in the definition of the Housholder transformation matrix $P$. "
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" raise NotImplementedError()"
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"# Apply your routine here ...\n",
"\n",
"# YOUR CODE HERE\n",
"raise NotImplementedError()"
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"source": [
"### Task 3\n",
"\n",
"Implement the $QR$ decomposition based diagonalization routine for tri-diagonal matrices $T$ in Python as a function $\\text{QREig(T, eps)}$. It should take a tri-diagonal matrix $T$ and some accuracy $\\varepsilon$ as inputs and should return all eigenvalues in the form of a vector $\\mathbf{d}$. By making use of the $QR$ decomposition as implemented in Numpy's $\\text{numpy.linalg.qr()}$ the algorithm is very simple and reads:\n",
"\n",
"Repeat the following until the error $e$ is smaller than $\\varepsilon$:\n",
"\n",
"\\begin{align}\n",
" Q \\cdot R &= T^{(k)} \\qquad \\text{... do this decomposition with the help of Numpy!} \\\\\n",
" T^{(k+1)} &= R \\cdot Q \\\\\n",
" e &= |\\mathbf{d_1}| \n",
"\\end{align}\n",
"\n",
"where $T^{(0)} = T$ and $\\mathbf{d_1}$ is the first sub-diagonal of $T^{(k+1)}$ at each iteration step $k$. At the end return the main-diagonal of $T^{(k+1)}$ as $\\mathbf{d}$. \n",
"\n",
"Implement a unit test for your function based on the matrix $A$ defined in task 1. You will need to tri-diagonalize it first."
]
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"\n",
"# YOUR CODE HERE\n",
"raise NotImplementedError()"
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"def test_QREig():\n",
" # YOUR CODE HERE\n",
" raise NotImplementedError()\n",
" \n",
"test_QREig()"
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"source": [
"### Task 4\n",
"\n",
"With the help of $\\text{QREig(T, eps)}$ you can now calculate all eigenvalues. Then you can calculate all corresponding eigenvectors with the help of $\\text{inversePower(A, sigma, eps)}$, by setting $\\sigma$ to approximately the eigenvalues you found (you should add some small random noise to $\\sigma$ in order to avoid singularity issues in the inversion needed for the inverse power method). \n",
"\n",
"Apply this combination of functions to calculate all eigenvalues and eigenvectors of the matrix $A$ defined in task 1."
]
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"source": [
"### Task 5\n",
"\n",
"Test your eigenvalue / eigenvector algorithm for larger random (but symmetric) matrices."
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