The unit impulse response of a linear time invariant system is the unit step function u(t). For t > 0, the response of the system to an excitation e-at u(t), a > 0 will be

ae-at
$$left( {{1 over a}} ight)left( {1 - {e^{ - at}}} ight)$$
a(1 - e-at)
1 - e-at

The correct answer is $\boxed{\left( {{1 \over a}} \right)\left( {1 – {e^{ – at}}} \right)}$.

The unit impulse response of a linear time invariant system is the unit step function $u(t)$. This means that if the system is excited with a unit impulse, $u(t)$, the output will be a unit step function, $u(t)$.

The excitation in this question is $e^{-at}u(t)$. This is a decaying exponential function that is multiplied by a unit step function. The output of the system to this excitation can be found using the convolution integral:

$$y(t) = \int_{-\infty}^t h(t-\tau)e^{-a\tau}d\tau$$

where $h(t)$ is the unit impulse response of the system.

The unit impulse response of the system is given as $h(t) = u(t)$. Substituting this into the convolution integral gives:

$$y(t) = \int_{-\infty}^t u(t-\tau)e^{-a\tau}d\tau$$

The convolution of $u(t)$ and $e^{-at}u(t)$ can be found using the following formula:

$$\int_{-\infty}^t u(t-\tau)e^{-a\tau}d\tau = \left( {{1 \over a}} \right)\left( {1 – {e^{ – at}}} \right)$$

Substituting this into the convolution integral gives:

$$y(t) = \left( {{1 \over a}} \right)\left( {1 – {e^{ – at}}} \right)$$

Therefore, the response of the system to an excitation $e^{-at}u(t)$, $a > 0$ will be $\left( {{1 \over a}} \right)\left( {1 – {e^{ – at}}} \right)$.