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author | samuel niederer <samuel.niederer@ost.ch> | 2022-07-24 12:03:25 +0200 |
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committer | samuel niederer <samuel.niederer@ost.ch> | 2022-07-24 12:03:25 +0200 |
commit | 5e25727877da020b0b23132fec8c0ea70288a18b (patch) | |
tree | c827e261e5a3d94ad2f48f8fea98cecb8722a112 /buch | |
parent | add phase space plot (diff) | |
download | SeminarSpezielleFunktionen-5e25727877da020b0b23132fec8c0ea70288a18b.tar.gz SeminarSpezielleFunktionen-5e25727877da020b0b23132fec8c0ea70288a18b.zip |
add presentation files
Diffstat (limited to '')
-rw-r--r-- | buch/papers/kra/images/simple_mass_spring.tex | 2 | ||||
-rw-r--r-- | buch/papers/kra/presentation/presentation.tex | 491 | ||||
-rw-r--r-- | buch/papers/kra/scripts/animation.py | 243 | ||||
-rw-r--r-- | buch/papers/kra/scripts/simulation.py | 40 |
4 files changed, 775 insertions, 1 deletions
diff --git a/buch/papers/kra/images/simple_mass_spring.tex b/buch/papers/kra/images/simple_mass_spring.tex index 207f1e0..e0e869a 100644 --- a/buch/papers/kra/images/simple_mass_spring.tex +++ b/buch/papers/kra/images/simple_mass_spring.tex @@ -14,7 +14,7 @@ } \tikzmath{ - \hWall = 1.5; + \hWall = 1.2; \wWall = 0.3; \lWall = 3.5; \hMass = 0.6; diff --git a/buch/papers/kra/presentation/presentation.tex b/buch/papers/kra/presentation/presentation.tex new file mode 100644 index 0000000..eb6541b --- /dev/null +++ b/buch/papers/kra/presentation/presentation.tex @@ -0,0 +1,491 @@ +\documentclass[ngerman, aspectratio=169, xcolor={rgb}]{beamer} + +% style +\mode<presentation>{ + \usetheme{Frankfurt} +} +%packages +\usepackage[utf8]{inputenc}\DeclareUnicodeCharacter{2212}{-} +\usepackage[english]{babel} +\usepackage{graphicx} +\usepackage{array} + +\newcolumntype{L}[1]{>{\raggedright\let\newline\\\arraybackslash\hspace{0pt}}m{#1}} +\usepackage{ragged2e} + +\usepackage{bm} % bold math +\usepackage{amsfonts} +\usepackage{amssymb} +\usepackage{mathtools} +\usepackage{amsmath} +\usepackage{multirow} % multi row in tables +\usepackage{booktabs} %toprule midrule bottomrue in tables +\usepackage{scrextend} +\usepackage{textgreek} +\usepackage[rgb]{xcolor} + +\usepackage[normalem]{ulem} % \sout + +\usepackage{ marvosym } % \Lightning + +\usepackage{multimedia} % embedded videos + +\usepackage{tikz} +\usepackage{pgf} +\usepackage{pgfplots} + +\usepackage{algorithmic} + +%citations +\usepackage[style=verbose,backend=biber]{biblatex} +\addbibresource{references.bib} + + +%math font +\usefonttheme[onlymath]{serif} + +%Beamer Template modifications +%\definecolor{mainColor}{HTML}{0065A3} % HSR blue +\definecolor{mainColor}{HTML}{D72864} % OST pink +\definecolor{invColor}{HTML}{28d79b} % OST pink +\definecolor{dgreen}{HTML}{38ad36} % Dark green + +%\definecolor{mainColor}{HTML}{000000} % HSR blue +\setbeamercolor{palette primary}{bg=white,fg=mainColor} +\setbeamercolor{palette secondary}{bg=orange,fg=mainColor} +\setbeamercolor{palette tertiary}{bg=yellow,fg=red} +\setbeamercolor{palette quaternary}{bg=mainColor,fg=white} %bg = Top bar, fg = active top bar topic +\setbeamercolor{structure}{fg=black} % itemize, enumerate, etc (bullet points) +\setbeamercolor{section in toc}{fg=black} % TOC sections +\setbeamertemplate{section in toc}[sections numbered] +\setbeamertemplate{subsection in toc}{% + \hspace{1.2em}{$\bullet$}~\inserttocsubsection\par} + +\setbeamertemplate{itemize items}[circle] +\setbeamertemplate{description item}[circle] +\setbeamertemplate{title page}[default][colsep=-4bp,rounded=true] +\beamertemplatenavigationsymbolsempty + +\setbeamercolor{footline}{fg=gray} +\setbeamertemplate{footline}{% + \hfill\usebeamertemplate***{navigation symbols} + \hspace{0.5cm} + \insertframenumber{}\hspace{0.2cm}\vspace{0.2cm} +} + +\usepackage{caption} +\captionsetup{labelformat=empty} + +%Title Page +\title{KRA} +\subtitle{Kalman Riccati Abel} +\author{Samuel Niederer} +% \institute{OST Ostschweizer Fachhochschule} +% \institute{\includegraphics[scale=0.3]{../img/ost_logo.png}} +\date{\today} + +\input{../packages.tex} + +\newcommand*{\QED}{\hfill\ensuremath{\blacksquare}}% + +\newcommand*{\HL}{\textcolor{mainColor}} +\newcommand*{\RD}{\textcolor{red}} +\newcommand*{\BL}{\textcolor{blue}} +\newcommand*{\GN}{\textcolor{dgreen}} +\newcommand{\dt}[0]{\frac{d}{dt}} + +\definecolor{darkgreen}{rgb}{0,0.6,0} + + +\makeatletter +\newcount\my@repeat@count +\newcommand{\myrepeat}[2]{% + \begingroup + \my@repeat@count=\z@ + \@whilenum\my@repeat@count<#1\do{#2\advance\my@repeat@count\@ne}% + \endgroup +} +\makeatother + +\usetikzlibrary{automata,arrows,positioning,calc,shapes.geometric, fadings} + +\begin{document} + +\begin{frame} + \titlepage +\end{frame} + +\begin{frame} + \frametitle{Content} + \tableofcontents +\end{frame} + +\section{Einführung} + +\begin{frame} + \begin{itemize} + \item<1|only@1> \textbf{K}alman + \item<1|only@1> \textbf{R}iccati + \item<1|only@1> \textbf{A}bel + + \item<2|only@2> \textcolor{red}{\sout{\textbf{K}alman}} + \item<2|only@2> \textbf{R}iccati + \item<2|only@2> \textbf{A}bel + + \item<3|only@3> \textcolor{red}{\sout{\textbf{K}alman}} \textcolor{green}{Federmassesytem} + \item<3|only@3> \textbf{R}iccati + \item<3|only@3> \textbf{A}bel + + \item<4|only@4> \textcolor{red}{\sout{\textbf{K}alman}} \textcolor{green}{Federmassesytem} + \item<4|only@4> \textbf{R}iccati + \item<4|only@4> \uwave{\textbf{A}bel} + \end{itemize} +\end{frame} + +\section{Riccati} + +\begin{frame} + \frametitle{Riccatische Differentialgleichung} + \begin{equation*} + % y'(x) = f(x)y^2(x) + g(x)y(x) + h(x) + x'(t) = f(t)x^2(t) + g(t)x(t) + h(t) + \end{equation*} + + \pause + + \begin{equation*} + \dot{X}(t) = - X(t)BX(t) - X(t)A + DX(t) + C + \end{equation*} + + % \pause + % Anwendungen + % \begin{itemize} + % \item Zeitkontinuierlicher Kalmanfilter + % \item Regelungstechnik LQ-Regler + % \item Federmassesyteme + % \end{itemize} +\end{frame} + +\begin{frame} + \frametitle{Auftreten der Gleichung} + \begin{columns} + \column{0.4 \textwidth} + \begin{equation*} + \dt + \begin{pmatrix} + X \\ + Y + \end{pmatrix} + = + \underbrace{ + \begin{pmatrix} + A & B \\ + C & D + \end{pmatrix} + }_{H} + \begin{pmatrix} + X \\ + Y + \end{pmatrix} + \end{equation*} + + \pause + + \column{0.4 \textwidth} + \begin{equation*} + U = YX^{-1} \qquad \dt U = ? + \end{equation*} + \end{columns} + + \pause + + \begin{align*} + \dt U & = \dot{Y} X^{-1} + Y \dt X^{-1} \\ + \uncover<4->{ & = (CX + DY) X^{-1} - Y (X^{-1} \dot{X} X^{-1})\\} + \uncover<5->{ & = C\underbrace{XX^{-1}}_\text{I} + D\underbrace{YX^{-1}}_\text{U} - Y(X^{-1} (AX + BY) X^{-1})\\} + \uncover<6->{ & = C + DU - \underbrace{YX^{-1}}_\text{U}(A\underbrace{XX^{-1}}_\text{I} + B\underbrace{YX^{-1}}_\text{U})\\} + \uncover<7->{ & = C + DU - UA - UBU} + \end{align*} +\end{frame} + +\begin{frame} + \frametitle{Lösen der Gleichung} + \begin{equation*} + \begin{pmatrix} + X(t) \\ + Y(t) + \end{pmatrix} + = + \Phi(t_0, t) + \begin{pmatrix} + I(t) \\ + U_0(t) + \end{pmatrix} + = + \begin{pmatrix} + \Phi_{11}(t_0, t) & \Phi_{12}(t_0, t) \\ + \Phi_{21}(t_0, t) & \Phi_{22}(t_0, t) + \end{pmatrix} + \begin{pmatrix} + I(t) \\ + U_0(t) + \end{pmatrix} + \end{equation*} + + \pause + + \begin{equation*} + U(t) = + \begin{pmatrix} + \Phi_{21}(t_0, t) + \Phi_{22}(t_0, t) U_0(t) + \end{pmatrix} + \begin{pmatrix} + \Phi_{11}(t_0, t) + \Phi_{12}(t_0, t) U_0(t) + \end{pmatrix} + ^{-1} + \end{equation*} + + \pause + + % wobei $\Phi(t, t_0)$ die sogennante Zustandsübergangsmatrix ist. + + \begin{equation*} + \Phi(t_0, t) = e^{H(t - t_0)} + \end{equation*} +\end{frame} + +\section{Federmassystem} +\begin{frame} + \frametitle{Federmassesystem} + \begin{columns} + \column{0.5 \textwidth} + \input{../images/simple_mass_spring.tex} + + \column{0.5 \textwidth} + \begin{align*} + \uncover<2->{F_R & = k \Delta_x \\} + \uncover<3->{F_a & = am = \ddot{x} m \\} + \uncover<4->{F_R & = F_a \Leftrightarrow k \Delta_x = \ddot{x} m\\} + \uncover<5->{\ddot{x} & = \frac{k \Delta_x}{m} \\} + \uncover<6->{x(t) & = A \cos(\omega_0 + \Phi), \quad \omega_0 = \sqrt{\frac{k}{m}}} + \end{align*} + \end{columns} +\end{frame} + +\begin{frame} + \frametitle{Phasenraum} + \begin{columns} + \column{0.3 \textwidth} + \begin{tikzpicture}[scale=3] + \draw[->, thick] (0, 0) -- (1,0) node[right] {$q$}; + \draw[->, thick] (0.5, -0.5) -- (0.5,0.5) node[above]{$p$}; + \end{tikzpicture} + \column{0.7 \textwidth} + Impulskoordinaten $p = (p_{1}, p_{2}, ..., p_{n}), \quad p=mv$ \\ + Ortskoordinaten $q = (q_{1}, q_{2}, ..., q_{n})$ \\ + + + + \begin{align*} + \uncover<2->{\mathcal{H}(q, p) & = \underbrace{T(p)}_{E_{kin}} + \underbrace{V(q)}_{E_{pot}} = E_{tot} \\} + \uncover<3->{ & = \frac{p^2}{2m}+ \frac{k q^2}{2}} + \end{align*} + + + + \begin{equation*} + \uncover<4->{ + \dot{q_{k}} = \frac{\partial \mathcal{H}}{\partial p_k} + \qquad + \dot{p_{k}} = -\frac{\partial \mathcal{H}}{\partial q_k} + } + \end{equation*} + + \pause + + \begin{equation*} + \uncover<5->{ + \begin{pmatrix} + \dot{q} \\ + \dot{p} + \end{pmatrix} + = + \begin{pmatrix} + 0 & \frac{1}{m} \\ + -k & 0 + \end{pmatrix} + \begin{pmatrix} + q \\ + p + \end{pmatrix} + } + \end{equation*} + + \end{columns} +\end{frame} + +\begin{frame} + \frametitle{Phasenraum} + \input{../images/phase_space.tex} +\end{frame} + +\begin{frame} + \frametitle{Federmassesystem} + \begin{columns} + \column{0.6 \textwidth} + \scalebox{0.8}{\input{../images/multi_mass_spring.tex}} + \begin{align*} + \uncover<2->{\mathcal{H} & = T + V \\} + \uncover<7->{ & = \frac{p_1^2}{2m_1} + \frac{p_2^2}{2m_2} + \frac{k_1 q_1^2}{2} + \frac{k_c (q_2 - q_1)^2}{2} + \frac{k_2 q_2^2}{2}} + \end{align*} + + \column{0.4 \textwidth} + \begin{align*} + \uncover<3->{T & = T_1 + T_2} \\ + \uncover<5->{ & = \frac{p_1^2}{2m_1} + \frac{p_2^2}{2m_2} } \\ + \uncover<4->{V & = V_1 + V_c + V_2 } \\ + \uncover<6->{ & = \frac{k_1 q_1^2}{2} + \frac{k_c (q_2 - q_1)^2}{2} + \frac{k_2 q_2^2}{2}} + \end{align*} + \end{columns} +\end{frame} + +\begin{frame} + \frametitle{Federmassesystem} + \begin{equation*} + \begin{pmatrix} + \dot{q_1} \\ + \dot{q_2} \\ + \dot{p_1} \\ + \dot{p_2} \\ + \end{pmatrix} + = + \begin{pmatrix} + 0 & 0 & \frac{1}{2m_1} & 0 \\ + 0 & 0 & 0 & \frac{1}{2m_2} \\ + -(k_1 + k_c) & k_c & 0 & 0 \\ + k_c & -(k_c + k_2) & 0 & 0 \\ + \end{pmatrix} + \begin{pmatrix} + q_1 \\ + q_2 \\ + p_1 \\ + p_2 \\ + \end{pmatrix} + \Leftrightarrow + \dt + \begin{pmatrix} + Q \\ + P \\ + \end{pmatrix} + \underbrace{ + \begin{pmatrix} + 0 & M \\ + K & 0 + \end{pmatrix} + }_{H} + \begin{pmatrix} + Q \\ + P \\ + \end{pmatrix} + \end{equation*} + + \pause + + $U = PQ^{-1} \qquad \dt U = ?$ + + \pause + + \begin{align*} + \dt U & = C + DU - UA - UBU \\ + & = K - UMU + \end{align*} + +\end{frame} + +\begin{frame} + \frametitle{Einfluss der Anfangsbedingung:} + \begin{columns} + \column{0.4 \textwidth} + \begin{equation*} + \uncover<2->{q_0 = + \begin{pmatrix} + q_{10} \\ + q_{20} + \end{pmatrix} + = + \begin{pmatrix} + 3 \\ + 1 + \end{pmatrix} + } + \end{equation*} + \begin{equation*} + \uncover<3->{q_0 = + \begin{pmatrix} + q_{10} \\ + q_{20} + \end{pmatrix} + = + \begin{pmatrix} + 3 \\ + 3 + \end{pmatrix} + } + \end{equation*} + \begin{equation*} + \uncover<4->{q_0 = + \begin{pmatrix} + q_{10} \\ + q_{20} + \end{pmatrix} + = + \begin{pmatrix} + 2 \\ + -2 + \end{pmatrix} + } + \end{equation*} + \column{0.6 \textwidth} + \scalebox{0.8}{\input{../images/multi_mass_spring.tex}} + \end{columns} +\end{frame} + +\section{Schlussteil} +\begin{frame} + \frametitle{Zusammenfassung} + \begin{itemize} + \pause + \item{Riccatische Differentialgleichung} + \pause + \begin{itemize} + \item{Ausgansgleichung} + \pause + \item{Lösung} + \end{itemize} + \pause + \item{Harmonischer Ozillator} + \pause + \begin{itemize} + \item{Hamiltonfunktion} + \pause + \item{Phasenraum} + \end{itemize} + \pause + \item{Gekoppelter harmonischer Ozillator} + \pause + \begin{itemize} + \item{Riccatische Differentialgleichung} + \pause + \item{Einfluss der Anfangsbedingungen} + \end{itemize} + \pause + \item{\uwave{Abel}} + \begin{itemize} + \pause + \item{Nichtlineare Federkonstante} + \end{itemize} + + \end{itemize} +\end{frame} + +\end{document} diff --git a/buch/papers/kra/scripts/animation.py b/buch/papers/kra/scripts/animation.py new file mode 100644 index 0000000..5e805ae --- /dev/null +++ b/buch/papers/kra/scripts/animation.py @@ -0,0 +1,243 @@ +import numpy as np
+import matplotlib.pyplot as plt
+import matplotlib.patches
+import matplotlib.transforms
+import matplotlib.text
+from matplotlib.animation import FuncAnimation
+import imageio
+
+from simulation import Simulation
+
+
+class Mass:
+ def __init__(self, x_0, width, height, **kwargs):
+ self._x_0 = x_0
+ xy = (x_0, 0)
+ self._rect = matplotlib.patches.Rectangle(xy, width, height, **kwargs)
+
+ @property
+ def patch(self):
+ return self._rect
+
+ @property
+ def x(self):
+ return self._rect.get_x()
+
+ @property
+ def width(self):
+ return self._rect.get_width()
+
+ def move(self, x):
+ self._rect.set_x(self._x_0 + x)
+
+
+class Spring:
+ def __init__(self, n, height, ax, resolution=1000, **kwargs):
+ self._n = n
+ self._height = height
+ self._N = resolution
+ (self._line,) = ax.plot([], [], "-", **kwargs)
+
+ def set(self, x_0, x_1):
+ T = (x_1 - x_0) / self._n
+ x = np.linspace(x_0, x_1, self._N, endpoint=True)
+ t = np.linspace(0, x_1 - x_0, self._N)
+ y = (np.sin(2 * np.pi * t / T) + 1.5) * self._height / 2
+ self.line.set_data(x, y)
+
+ @property
+ def line(self):
+ return self._line
+
+
+class LinePlot:
+ def __init__(self, ax, **kwargs):
+ (self._line,) = ax.plot([], [], "-", **kwargs)
+ self._x = []
+ self._y = []
+
+ @property
+ def line(self):
+ return self._line
+
+ def update(self, x, y):
+ self._x.append(x)
+ self._y.append(y)
+ self._line.set_data(self._x, self._y)
+
+
+class ScatterPlot:
+ def __init__(self, ax, **kwargs):
+ self._color = kwargs.get("color", "tab:green")
+ self._line = ax.scatter([], [], **kwargs)
+ self._ax = ax
+ self._x = []
+ self._y = []
+
+ @property
+ def line(self):
+ return self._line
+
+ def update(self, x, y, **kwargs):
+ self._x.append(x)
+ self._y.append(y)
+ self._line.remove()
+ self._line = self._ax.scatter(self._x, self._y, color=self._color, **kwargs)
+
+
+class QuiverPlot:
+ def __init__(self, ax, **kwargs):
+ self.x = []
+ self.y = []
+ self.u = []
+ self.v = []
+ self.ax = ax
+ self.ln = self.ax.quiver([], [], [], [])
+
+ def update(self, x, y, u, v):
+ self.x.append(x)
+ self.y.append(y)
+ self.u.append(u)
+ self.v.append(v)
+ self.ln.remove()
+ self.ln = self.ax.quiver(self.x, self.y, self.u, self.v)
+
+ @property
+ def line(self):
+ return self.ln
+
+
+anim_folder = "anim_0"
+img_counter = 0
+
+sim = Simulation()
+params = {
+ "x_0": [2, -2],
+ "k_1": 1,
+ "k_c": 2,
+ "k_2": 1,
+ "m_1": 0.5,
+ "m_2": 0.5,
+}
+
+time = 2.1
+
+
+# create axis
+fig = plt.figure(figsize=(20, 15), constrained_layout=True)
+fig.suptitle(
+ " ,".join([f"${key} = {val}$" for (key, val) in params.items()]), fontsize=20
+)
+spec = fig.add_gridspec(3, 4)
+ax0 = fig.add_subplot(spec[-1, :])
+ax1 = fig.add_subplot(spec[:-1, :2])
+ax2 = fig.add_subplot(spec[:-1, 2:])
+
+ax0.set_yticks([])
+
+mass_height = 0.5
+spring_height = 0.6 * mass_height
+x_max = 21
+y_max = 2 * mass_height
+
+mass_1 = Mass(
+ 7,
+ 2,
+ mass_height,
+ color="tab:red",
+)
+mass_2 = Mass(14, 2, mass_height, color="tab:blue")
+masses = [mass_1, mass_2]
+patches = [mass.patch for mass in masses]
+
+spring_1 = Spring(4, spring_height, ax0, color="tab:red", linewidth=10)
+spring_2 = Spring(4, spring_height, ax0, color="tab:gray", linewidth=10)
+spring_3 = Spring(4, spring_height, ax0, color="tab:blue", linewidth=10)
+springs = [spring_1, spring_2, spring_3]
+
+linePlot_1 = LinePlot(ax1, color="tab:red", label="$m_1$", alpha=1)
+linePlot_2 = LinePlot(ax1, color="tab:blue", label="$m_2$", alpha=1)
+linePlots = [linePlot_1, linePlot_2]
+
+# quiverPlot = QuiverPlot(ax2)
+scatterPlot = ScatterPlot(ax2)
+
+lines = [spring.line for spring in springs]
+lines.extend([plot.line for plot in linePlots])
+# lines.append(quiverPlot.line)
+lines.append(scatterPlot.line)
+
+objects = lines + patches
+
+ax0.plot(
+ np.repeat(mass_1.x, 2),
+ [0, y_max],
+ "--",
+ color="tab:red",
+ label="Ruhezustand $m_1$",
+)
+ax0.plot(
+ np.repeat(mass_2.x, 2),
+ [0, y_max],
+ "--",
+ color="tab:blue",
+ label="Ruhezustand $m_2$",
+)
+
+
+def init():
+ ax0.set_xlim(0, x_max)
+ ax0.set_ylim(0, y_max)
+
+ ax1.set_xlim(0, time)
+ ax1.set_ylim(-4, 4)
+ ax1.set_xlabel("time", fontsize=20)
+ ax1.set_ylabel("$q$", fontsize=20)
+
+ ax2.set_xlim(-4, 4)
+ ax2.set_ylim(-4, 4)
+ ax2.set_xlabel("$q_1$", fontsize=20)
+ ax2.set_ylabel("$q_2$", fontsize=20)
+
+ for patch in patches:
+ ax0.add_patch(patch)
+
+ spring_1.set(0, mass_1.x)
+ spring_2.set(mass_1.x + mass_1.width, mass_2.x)
+ spring_2.set(mass_2.x + mass_2.width, x_max)
+
+ return objects
+
+
+def update(frame):
+ global img_counter
+ x_1, x_2 = sim(frame, **params)
+
+ mass_1.move(x_1)
+ mass_2.move(x_2)
+
+ spring_1.set(0, mass_1.x)
+ spring_2.set(mass_1.x + mass_1.width, mass_2.x)
+ spring_3.set(mass_2.x + mass_2.width, x_max)
+
+ linePlot_1.update(frame, x_1)
+ linePlot_2.update(frame, x_2)
+
+ scatterPlot.update(x_1, x_2, alpha=0.25)
+
+ img_counter += 1
+ return objects
+
+
+anim = FuncAnimation(
+ fig,
+ update,
+ frames=np.linspace(0, time, int(time * 30)),
+ init_func=init,
+ blit=False,
+)
+
+ax0.legend(fontsize=20)
+ax1.legend(fontsize=20)
+FFwriter = matplotlib.animation.FFMpegWriter(fps=30)
+anim.save("animation.mp4", writer=FFwriter)
diff --git a/buch/papers/kra/scripts/simulation.py b/buch/papers/kra/scripts/simulation.py new file mode 100644 index 0000000..8bccb6a --- /dev/null +++ b/buch/papers/kra/scripts/simulation.py @@ -0,0 +1,40 @@ +import sympy as sp
+
+
+class Simulation:
+ def __init__(self):
+ self.k_1, self.k_2, self.k_c = sp.symbols("k_1 k_2 k_c")
+ self.m_1, self.m_2 = sp.symbols("m_1 m_2")
+ self.t = sp.symbols("t")
+ K = sp.Matrix(
+ [[-(self.k_1 + self.k_c), self.k_c], [self.k_c, -(self.k_2 + self.k_c)]]
+ )
+ M = sp.Matrix([[1 / self.m_1, 0], [0, 1 / self.m_2]])
+ A = M * K
+
+ self.eigenvecs = []
+ self.eigenvals = []
+ for ev, mult, vecs in A.eigenvects():
+ self.eigenvecs.append(sp.Matrix(vecs))
+ self.eigenvals.extend([ev] * mult)
+
+ def __call__(self, t, x_0, k_1, k_c, k_2, m_1, m_2):
+ params = {
+ self.k_1: k_1,
+ self.k_c: k_c,
+ self.k_2: k_2,
+ self.m_1: m_1,
+ self.m_2: m_2,
+ }
+ x_0 = sp.Matrix(x_0)
+ eig_mat = sp.Matrix.hstack(*self.eigenvecs).subs(params)
+ g = eig_mat.inv() * x_0
+ L = sp.Matrix(
+ [
+ g[0] * sp.cos(self.eigenvals[0].subs(params) * self.t),
+ g[1] * sp.cos(self.eigenvals[1].subs(params) * self.t),
+ ]
+ )
+ x = eig_mat * L
+ f = sp.lambdify(self.t, x, "numpy")
+ return f(t).squeeze()
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