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Table of Laplace Transforms f(t) L[f(t)] = F(s) 1 1 s (1) eatf(t) F(s a) (2) U(t a) e as s (3) f(t a)U(t a) e asF(s) (4) (t) 1 (5) (t stt 0) e 0 (6) tnf(t) ( 1)n dnF(s) dsn (7) ... « 2011 B.E.Shapiro forintegral-table.com. This work is licensed under aCreative Commons Attribution-NonCommercial-ShareAlike 3.0 Unported License. Revised with ...
18.031 Laplace Transform Table Properties and Rules Function Transform f(t) F(s) = Z 1 0 f(t)e st dt (De nition) af(t) + bg(t) aF(s) + bG(s) (Linearity) ... Function Table Function Transform Region of convergence 1 1=s Re(s) >0 eat 1=(s a) Re(s) >Re(a) t 1=s2 Re(s) >0 tn n!=sn+1 Re(s) >0 cos(!t) s=(s2 + !2) Re(s) >0
Laplace transforms table Function Laplace transform eat 1 s−a tn n! sn+1 sin(at) a s 2+a cos(at) s s2 +a2
Table of Laplace transforms. f(t) F(s) 1. sin at. cos at. ectf(t) tnf(t) f(t − c)uc(t)
State the Laplace transforms of a few simple functions from memory. What are the steps of solving an ODE by the Laplace transform? In what cases of solving ODEs is the present method preferable to that in Chap. 2? What property of the Laplace transform is crucial in solving ODEs? = Explain. When and how do you use the unit step function and
Table of Laplace transforms f(t) L(f(t)) or F(s) 1. 1 1 s 2. eat 1 s−a 3. tn n! sn+1 n≥0 integer 4. eattn n! (s−a)n+1 n≥0 integer 5. sinkt k s2 +k2 6. coskt s s2 +k2 7. eatsinkt k (s−a)2 +k2 8. eatcoskt s−a
Table of Laplace Transforms f(t) L(f(t)) f(t) L(f(t)) 1 1 s t 1 s2 Derivatives t2 2 s3 y L(y) tn n! sn+1 y0 sL(y) y(o) eat 1 s a y00 s2L(y) sy(o) y0(0) tneat n! (s a)n+1 cos(!t) s s2 +!2 sin(!t)! s2 +!2 t-Shift cosh(at) s s2 a2 f(t) F(s) sinh(at) a s2 a2 u a(t)f(t a) e asF(s) eat cos(!t) s a (s a)2 +!2 eat sin(!t)! (s a)2 +!2 s-Shift (t a) e as ...
