\magnification 2200 \parindent 0pt \parskip 10pt \pageno=1 \hsize 7truein \vsize 9.2truein \def\u{\vskip -10pt} \def\v{\vskip -6pt} Thm: Suppose $c_1 \phi_1(t) + c_2 \phi_2(t)$ is a general solution to \centerline{$ay'' + by' + cy = 0$,} If $\psi$ is a solution to \centerline{$ay'' + by' + cy = g(t)$ [*],} Then $\psi + c_1 \phi_1(t) + c_2 \phi_2(t)$ is also a solution to [*]. Moreover if $\gamma$ is also a solution to [*], then there exist constants $c_1, c_2$ such that \centerline{$\gamma = \psi + c_1 \phi_1(t) + c_2 \phi_2(t)$} Or in other words, $\psi + c_1 \phi_1(t) + c_2 \phi_2(t)$ is a general solution to [*]. Proof: Let $h = c_1 \phi_1(t) + c_2 \phi_2(t)$. Since $h$ is a solution to the differential equation, $ay'' + by' + cy = 0$, \vskip 0.5in Since $\psi$ is a solution to $ay'' + by' + cy = g(t)$, \vskip 1in We will now show that $\psi + c_1 \phi_1(t) + c_2 \phi_2(t) = \psi + h$ is also a solution to [*]. \vskip 2in \eject Since $\gamma$ a solution to $ay'' + by' + cy = g(t)$, \vskip 0.5in We will first show that $\gamma - \psi$ is a solution to the differential equation $ay'' + by' + cy = 0$. \vskip 1in \vfill Since $\gamma - \psi$ is a solution to $ay'' + by' + cy = 0$ and $c_1 \phi_1(t) + c_2 \phi_2(t)$ is a general solution to \centerline{$ay'' + by' + cy = 0$,} there exist constants $c_1, c_2$ such that \vskip 10pt \centerline{$\gamma - \psi =\underline{\hskip 2in}$} Thus $\gamma = \psi + c_1 \phi_1(t) + c_2 \phi_2(t)$. \eject Thm: Suppose that $f_1$ is a a solution to $ay'' + by' + cy = g_1(t)$ and $f_2$ is a a solution to $ay'' + by' + cy = g_2(t)$, then $f_1 + f_2$ is a solution to $ay'' + by' + cy = g_1(t) + g_2(t)$ Proof: Since $f_1$ is a solution to $ay'' + by' + cy = g_1(t)$, \vskip 0.5in Since $f_2$ is a solution to $ay'' + by' + cy = g_2(t)$, \vskip 0.5in We will now show that $f_1 + f_2$ is a solution to $ay'' + by' + cy = g_1(t) + g_2(t)$. \vskip 0.65in \vfill \vfill Sidenote: The proofs above work even if $a, b, c$ are functions of $t$ instead of constants. Examples: Find a suitable form for $\psi$ for the following differential equations: 1.) $y'' - 4y' - 5y = 4e^{2t}$ \vskip 0.3in 2.) $y'' - 4y' - 5y = 4sin(3t)$ \vskip 0.3in 3.) $y'' - 4y' - 5y = t^2 - 2t + 1$ \vskip 0.3in 4.) $y'' - 5y = 4sin(3t)$ \vskip 0.3in 5.) $y'' - 4y' = t^2 - 2t + 1$ \vskip 0.3in 6.) $y'' - 4y' - 5y = 4(t^2 - 2t - 1)e^{2t}$ \vskip 0.3in 7.) $y'' - 4y' - 5y = 4 sin(3t) e^{2t}$ \vskip 0.3in 8.) $y'' - 4y' - 5y = 4 (t^2 - 2t - 1)sin(3t) e^{2t}$ \vskip 0.3in 9.) $y'' - 4y' - 5y =4sin(3t) + 4 sin(3t) e^{2t}$ \vskip 0.3in 10.) $y'' - 4y' - 5y$ \rightline{ $= 4 sin(3t) e^{2t} + 4(t^2 - 2t - 1)e^{2t} + t^2 - 2t - 1$} \vskip 0.85in \vfill 11.) $y'' - 4y' - 5y =4sin(3t) + 5cos(3t)$ \vskip 0.3in 12.) $y'' - 4y' - 5y = 4e^{-t}$ \eject To solve $ay'' + by' + cy = g_1(t) + g_2(t) + ... g_n(t)$ [**] 1.) Find the general solution to $ay'' + by' + cy = 0$: \centerline{$c_1\phi_1 + c_2\phi_2$} 2.) For each $g_i$, find a solution to $ay'' + by' + cy = g_i$: \centerline{$\psi_i$} The general solution to [**] is \vskip 10pt \centerline{$c_1\phi_1 + c_2\phi_2 + \psi_1 + \psi_2 + ... \psi_n$} \end