
# 8.8: A Brief Table of Laplace Transforms


Table $$\PageIndex{1}$$
$$\displaystyle f(t)$$ $$\displaystyle F(s)$$
1 $$\displaystyle 1\over s$$ $$\displaystyle (s > 0)$$
$$\displaystyle t^n$$ $$\displaystyle n!\over s^{n+1}$$ $$\displaystyle (s > 0)$$
($$\displaystyle n = \mbox{ integer } > 0$$)
$$\displaystyle t^p,\; p > -1$$ $$\displaystyle \Gamma (p+1) \over s^{(p+1)}$$ $$\displaystyle (s>0)$$
$$\displaystyle e^{at}$$ $$\displaystyle 1 \over s-a$$ $$\displaystyle (s > a)$$
$$\displaystyle t^ne^{at}$$ $$\displaystyle n! \over (s-a)^{n+1}$$ $$\displaystyle (s > 0)$$
($$\displaystyle n= \text{ integer } > 0$$)
$$\displaystyle \cos \omega t$$ $$\displaystyle \frac{s}{s^{2}+\omega ^{2}}$$ $$\displaystyle (s > 0)$$
$$\displaystyle \sin \omega t$$ $$\displaystyle \omega \over s^2+\omega^2$$ $$\displaystyle (s > 0)$$
$$\displaystyle e^{\lambda t} \cos \omega t$$ $$\displaystyle s - \lambda \over (s-\lambda)^2+\omega^2$$ $$\displaystyle (s > \lambda)$$
$$\displaystyle e^{\lambda t} \sin \omega t$$ $$\displaystyle \omega \over (s-\lambda)^2+\omega^2$$ $$\displaystyle (s > \lambda)$$
$$\displaystyle \cosh bt$$ $$\displaystyle s \over s^2-b^2$$ $$\displaystyle (s > |b|)$$
$$\displaystyle \sinh bt$$ $$\displaystyle b \over s^2-b^2$$ $$\displaystyle (s > |b|)$$
$$\displaystyle t \cos \omega t$$ $$\displaystyle s^2-\omega^2 \over (s^2+\omega^2)^2$$ $$\displaystyle (s>0)$$
$$\displaystyle t \sin \omega t$$ $$\displaystyle 2\omega s \over (s^2+\omega^2)^2$$ $$\displaystyle (s>0)$$
$$\displaystyle \sin \omega t -\omega t\cos \omega t$$ $$\displaystyle 2\omega^3\over (s^2+\omega^2)^2$$ $$\displaystyle (s>0)$$
$$\displaystyle \omega t - \sin \omega t$$ $$\displaystyle \omega^3 \over s^2(s^2+\omega^2)^2$$ $$\displaystyle (s>0)$$
$$\displaystyle \frac{1}{t}\sin\omega t$$ $$\displaystyle \arctan \left({\omega \over s}\right)$$ $$\displaystyle (s>0)$$
$$\displaystyle e^{at}f(t)$$ $$\displaystyle F(s-a)$$
$$\displaystyle t^kf(t)$$ $$\displaystyle (-1)^{k}F^{(k)}(s)$$
$$\displaystyle f(\omega t)$$ $$\displaystyle \frac{1}{\omega}F\left(\frac{s}{\omega } \right), \quad \omega >0$$
$$\displaystyle u(t-\tau)$$ $$\displaystyle e^{-\tau s} \over s$$ $$\displaystyle (s>0)$$
$$\displaystyle u(t-\tau)f(t-\tau)\, (\tau > 0)$$ $$\displaystyle e^{-\tau s}F(s)$$
$$\displaystyle \displaystyle {\int^t_o f(\tau)g(t-\tau)\, d\tau}$$ $$\displaystyle F(s) \cdot G(s)$$
$$\displaystyle \delta(t-a)$$ $$\displaystyle e^{-as}$$ $$\displaystyle (s>0)$$