Laplace Transform

Definition: F(s) = L{f(t)} = ∫₀^∞ f(t)·e^(-st) dt (Re(s) > convergence abscissa)

Common Transform Pairs

f(t)	F(s) = L{f(t)}	Region of Convergence
1	1/s	Re(s) > 0
t	1/s²	Re(s) > 0
tⁿ	n!/sⁿ⁺¹	Re(s) > 0
e^(at)	1/(s-a)	Re(s) > a
t·e^(at)	1/(s-a)²	Re(s) > a
tⁿ·e^(at)	n!/(s-a)ⁿ⁺¹	Re(s) > a
sin(ωt)	ω/(s²+ω²)	Re(s) > 0
cos(ωt)	s/(s²+ω²)	Re(s) > 0
sinh(at)	a/(s²-a²)	Re(s) > \|a\|
cosh(at)	s/(s²-a²)	Re(s) > \|a\|
e^(at)·sin(ωt)	ω/((s-a)²+ω²)	Re(s) > a
e^(at)·cos(ωt)	(s-a)/((s-a)²+ω²)	Re(s) > a
δ(t) (Dirac delta)	1	All s
u(t) (unit step)	1/s	Re(s) > 0
t·sin(ωt)	2ωs/(s²+ω²)²	Re(s) > 0
t·cos(ωt)	(s²-ω²)/(s²+ω²)²	Re(s) > 0

Properties

Property	Time Domain	s-Domain
Linearity	af(t) + bg(t)	aF(s) + bG(s)
Time Shift	f(t-a)·u(t-a)	e^(-as)·F(s)
Frequency Shift	e^(at)·f(t)	F(s-a)
Scaling	f(at)	(1/a)·F(s/a)
1st Derivative	f'(t)	sF(s) - f(0)
2nd Derivative	f''(t)	s²F(s) - sf(0) - f'(0)
Integration	∫₀ᵗ f(τ) dτ	F(s)/s
Multiplication by t	t·f(t)	-F'(s)
Convolution	f(t) * g(t)	F(s)·G(s)
Initial Value Theorem	f(0⁺)	lim(s→∞) sF(s)
Final Value Theorem	f(∞)	lim(s→0) sF(s)