--- title: Homework 5 -- Optimization Methods author: Claudio Maggioni header-includes: - \usepackage{amsmath} - \usepackage{hyperref} - \usepackage[utf8]{inputenc} - \usepackage[margin=2.5cm]{geometry} - \usepackage[ruled,vlined]{algorithm2e} - \usepackage{float} - \floatplacement{figure}{H} - \hypersetup{colorlinks=true,linkcolor=blue} --- \maketitle # Excecise 1 ## Exercise 1.1 ### The Simplex method The simplex method solves constrained minimization problems with a linear cost function and linearly-defined equality and inequality constraints. The main approach used by the simplex method is to consider only basic feasible points along the feasible region polytope and to iteratively navigate between them hopping through neighbours and trying to find the point that minimizes the cost function. Although the Simplex method is relatively efficient for most in-practice applications, it has exponential complexity, since it has been proven that a carefully crafted $n$-dimensional problem can have up to $2^n$ polytope vertices, thus making the method inefficient for complex problems. ### Interior-point method The interior point method aims to have a better worst-case complexity than the simplex method but still retain an in-practice acceptable performance. Instead of performing many inexpensive iterations walking along the polytope boundary, the interior point takes Newton-like steps travelling along "interior" points in the feasible region (hence the name of the method), thus reaching the constrained minimizer in fewer iterations. Additionally, the interior-point method is easier to be implemented in a parallelized fashion. ### Penalty method The penalty method allows for a linear constrained minimization problem with equality constraints to be converted in an unconstrained minimization problem, and to allow the use of conventional unconstrained minimization algorithms to solve the problem. Namely, the penalty method builds a new uncostrained objective function with is the summation of: - The original objective function; - An additional term for each constraint, which is positive when the current point $x$ violates that constraint and zero otherwise. With some fine tuning of the coefficients for these new "penalty" terms, it is possible to build an equivalend unconstrained minimization problem whose minimizer is also constrained minimizer for the original problem. ## Exercise 1.2 ## Exercise 1.3 # Exercise 2 ## Exercise 2.1 The resulting MATLAB plot of each constraint and of the feasible region is shown below: ![Plot of feasible region and constraints\label{fig:a}](./ex2-1.png) ## Exercise 2.2 According to Nocedal, a vector $x$ is a basic feasible point if it is in the feasible region and if there exists a subset $\beta$ of the index set $1, 2, \ldots, n$ such that: - $\beta$ contains exactly $m$ indices, where $m$ is the number of rows of $A$; - For any $i \notin \beta$, $x_i = 0$, meaning the bound $x_i \geq 0$ can be inactive only if $i \in \beta$; - The $m$ x $m$ matrix $B$ defined by $B = [A_i]_{i \in \beta}$ (where $A_i$ is the i-th column of A) is non-singular, i.e. all columns corresponding to the indices in $\beta$ are linearly independent from each other. The geometric interpretation of basic feasible points is that all of them are vertices of the polytope that bounds the feasible region. We will use this proven property to manually solve the constrained minimization problem presented in this section by aiding us with the graphical plot of the feasible region in figure \ref{fig:a}. ## Exercise 2.3 Since the geometrical interpretation of the definition of basic feasible point states that these point are non-other than the vertices of the feasible region, we first look at the plot above and to these points (i.e. the vertices of the bright green non-trasparent region). Then, we look which constraint boundaries cross these edges, and we formulate an algebraic expression to find these points. In clockwise order, we have: - The lower-left point at the origin, given by the boundaries of the constraints $x_1 \geq 0$ and $x_2 \geq 0$: $$x^*_1 = \begin{bmatrix}0\\0\end{bmatrix}$$ - The top-left point, at the intersection of constraint boundaries $x_1 \geq 0$ and $-3x_1 + 2x_2 \leq 3$: $$x_1 = 0 \;\;\; 2x_2 = 3 \Leftrightarrow x_2 = \frac32 \;\;\; x^*_2 = \frac12 \cdot \begin{bmatrix}0\\3\end{bmatrix}$$ - The top-center-left point at the intersection of constraint boundaries $-3x_1 + 2x_2 \leq 3$ and $2x_1 + 3x_2 \leq 6$: $$-3x_1 + 2x_2 + 3x_1 + \frac92 x_2 = \frac{13}{2} x_2 = 3 + 9 = 12 \Leftrightarrow x_2 = 12 \cdot \frac2{13} = \frac{24}{13}$$$$ -3x_1 + 2 \cdot \frac{24}{13} = 3 \Leftrightarrow x_1 = \frac{39 - 48}{13} \cdot \frac{1}{-3} = \frac{3}{13} \;\;\; x^*_3 = \frac{1}{13} \cdot \begin{bmatrix}3\\24\end{bmatrix}$$ - The top-center-right point at the intersection of constraint boundaries $2x_1 + 3x_2 \leq 6$ and $2x_1 + x_2 \leq 4$: $$2x_1 + 3x_2 - 2x_1 - x_2 = 2x_2 = 6 - 4 = 2 \Leftrightarrow x_2 = 1 \;\;\; 2x_1 + 1 = 4 \Leftrightarrow x_1 = \frac32 \;\;\; x^*_4 = \frac12 \cdot \begin{bmatrix}3\\2\end{bmatrix}$$ - The right point at the intersection of $2x_1 + x_2 \leq 4$ and $x_2 \geq 0$: $$x_2 = 0 \;\;\; 2x_1 + 0 = 4 \Leftrightarrow x_1 = 2 \;\;\; x^*_5 = \begin{bmatrix}2\\0\end{bmatrix}$$ Therefore, $x^*_1$ to $x^*_5$ are all of the basic feasible points for this constrained minimization problem. We then compute the objective function value for each basic feasible point found, The smallest objective value will correspond with the constrained minimizer problem solution. $$ x^*_1 = \begin{bmatrix}0\\0\end{bmatrix} \;\;\; f(x^*_1) = 4 \cdot 0 + 3 \cdot 0 = 0$$$$ x^*_2 = \frac12 \cdot \begin{bmatrix}0\\3\end{bmatrix} \;\;\; f(x^*_2) = 4 \cdot 0 + 3 \cdot \frac{3}{2} = \frac92$$$$ x^*_3 = \frac{1}{13} \cdot \begin{bmatrix}3\\24\end{bmatrix} \;\;\; f(x^*_3) = 4 \cdot \frac{3}{13} + 3 \cdot \frac{24}{13} = \frac{84}{13}$$$$ x^*_4 = \frac12 \cdot \begin{bmatrix}3\\2\end{bmatrix} \;\;\; f(x^*_4) = 4 \cdot \frac32 + 3 \cdot 1 = 9$$$$ x^*_5 = \begin{bmatrix}2\\0\end{bmatrix} \;\;\; f(x^*_5) = 4 \cdot 2 + 1 \cdot 0 = 8$$ Therefore, $x^* = x^*_1 = \begin{bmatrix}0 & 0\end{bmatrix}^T$ is the global constrained minimizer. # Exercise 3 ## Exercise 3.1 Yes, the problem can be solved with _Uzzawa_'s method since the problem can be reformulated as a saddle point system. The KKT conditions of the problem can be reformulated as a matrix-vector to vector equality in the following way: $$\begin{bmatrix}G & -A^T\\A & 0 \end{bmatrix} \begin{bmatrix} x^*\\\lambda^* \end{bmatrix} = \begin{bmatrix} -c\\b \end{bmatrix}.$$ If we then express the minimizer $x^*$ in terms of $x$, an approximation of it, and $p$, a search step (i.e. $x^* = x + p$), we obtain the following system. $$\begin{bmatrix} G & A^T\\ A & 0 \end{bmatrix} \begin{bmatrix} -p\\ \lambda^* \end{bmatrix} = \begin{bmatrix} g\\ h \end{bmatrix}$$ This is the system the _Uzzawa_ method will solve. Therefore, we need to check if the matrix: $$K = \begin{bmatrix}G & A^T \\ A& 0\end{bmatrix} = \begin{bmatrix} 6 & 2 & 1 & 1 & 0 \\ 2 & 5 & 2 & 0 & 1 \\ 1 & 2 & 4 & 1 & 1 \\ 1 & 0 & 1 & 0 & 0 \\ 0 & 1 & 1 & 0 & 0 \\ \end{bmatrix}\text{ recalling the computed values of }A\text{ and }G\text{ from the previous assignment}$$ Has non-zero positive and negative eigenvalues. We compute the eigenvalues of this matrix with MATLAB, and we find: $$\begin{bmatrix} -0.4818\\ -0.2685\\ 2.6378\\ 4.3462\\ 8.7663\end{bmatrix}$$ Therefore, the system is indeed a saddle point system and it can be solved with _Uzzawa_'s method. ## Exercise 3.2 The MATLAB code used to find the solution can be found under section 3.2 of the `main.m` script. The solution is: $$x=\begin{bmatrix}0.7692\\-2.2308\\2.2308\end{bmatrix} \;\;\; \lambda= \begin{bmatrix}-10.3846\\2.1538\end{bmatrix}$$