1. What is the Transfer Function of this Differential Equation?

2. Find the solution to the dierential equation in the time domain when f (t) = 9tu(t), using an assumed solution of the form y (t) = Ae^st (you are not allowed to use Laplace transforms). Use the initial conditions y (0) = 6 and y'(0) = 16.

Transcribed Image Text:

The image shows a second-order linear differential equation expressed as: \[ \frac{d^2 v}{dt^2} + 6 \frac{dv}{dt} + 9v = f(t). \] This equation is commonly found in the context of mechanical vibrations, electrical circuits, or systems dynamics, where \(v\) might represent a variable such as velocity or voltage as a function of time \(t\). The term \(\frac{d^2 v}{dt^2}\) represents the acceleration (or second derivative of \(v\) with respect to time), \(\frac{dv}{dt}\) is the velocity (or first derivative), and \(v\) is the position or state. The function \(f(t)\) signifies an external force or input to the system. This differential equation could describe systems that are subject to damping and external forces, allowing for analysis of behavior such as oscillations, decay, or stability, depending on the characteristics of \(f(t)\).