Question 2. Find the general solution of the given ODE for t > 0, t²x" − t(t+2)x' + (t + 2)x = t³e¹. Note that x₁(t) = t solves the homogeneous ODE.

Show that you have reasoned about the problem a way that is correct

Transcribed Image Text:

(a) i=√1 and eit = cost + i sin t. (b) For all integer n ≥ 0 we have: cos(NT) ) = (−1)”, sin(nx) = 0, sin ((2n + 1)) = (−1)", cos ((2n + 1) -1)) = 0. (c) Integration by Parts: fudv = uv- Svdu. (d) Quadratic formula: If ar² + br + c = 0 for a 0. Then, L[sin at] (e) Laplace Transform: F(s) = fest f(t) dt. (f) Convolution: (f* g)(t) = f f (0)g(t – 0)d0. Note (ƒ * g)(t) = (g* f)(t). (g) LT of f(t) = sin at, f(t) = cos at and f(t) =t" for n ≥ 0: and = (h) Properties of LT/ILT: (1) LT/ILT are linear operators. a s² + a² r = u₁ (t) = - (k) Change of variables: -b ± √b² - 4ac 2a L[cos at] • Euler equation s = lnt or t=es, Bernoulli equation: z = x-k -k • k-homogeneous equation: z = (2) Shift/Scaling: L[eat f(t)] = F(s — a) for constant a € R and L[f(at)] = F(²) for constant a > 0. (3) LT of derivatives: L[f(n) (t)] = s¹F(s) — sn−¹ƒ(0) — sn−2 ƒ'(0) — ... — fn−¹(0) for n ≥ 1. ● LT of integrals: L [√ f (0)d0] = F(s) when ƒ(0) = 0. (4) Derivative of LT or LT of multiplication by polynomials: L[t" f(t)] = (−1)n d™ F(s) for n ≥ 1. (5) Unit Step Function: L[He(t)f(t — c)] = F(s)e-sc. (6) Convolution Property: L[(f * g)(t)] = F(s)G(s). (i) Formula for Reduction of Order: x₂(t) = x₁(t) = S s² + a² Te e-Sp(t)dt x²(t) (j) Formula for Variation of Parameters: xp (t) = x₁(t)u₁(t) + x₂(t)u₂(t) when x₂ (t)g(t) - / [ ] W(x1, x₂)(t) or x = zt. dt and and L[t"]= = dt u₂(t) = /[ W •/ n! gn+1 x₁ (t)g(t) W(x1, x₂) (t) dt

Transcribed Image Text:

Question 2. Find the general solution of the given ODE for t > 0, t²x" − t(t + 2)x' + (t + 2)x = t³et. Note that ₁ (t) = t solves the homogeneous ODE.