Question 4. Apply Laplace Transform to solve the following Integro-Differential Equation when x(0) = 1 and - 1/2 √² (1 - 0) ² x (0) do = t 0 x' (t) -

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Question 4. Apply Laplace Transform to solve the following Integro-Differential Equation when x(0) = 1 and 1 x' (t) — ½ √ √ ² (t – 0)²³x(0) d0 = −t 2

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Some (not necessarily all) of the following formulas and definitions might be helpful for the final. (a) i=√1 and eit = cost + i sin t. (b) For all integer n ≥ 0 we have: cos(NT) = (-1)", sin(n) = 0, sin ((2n +1) (c) Integration by Parts: fudv=uv - fvdu. (d) Quadratic formula: If ar² + br + c = 0 for a 0. Then, a s² + a² (1) LT/ILT are linear operators. (e) Laplace Transform: F(s) = f est f(t)dt. (f) Convolution: (f * g) (t) = f f(0)g(t – 0)d0. Note (f * g)(t) = (g* f) (t). (g) LT of f(t) = sin at, f(t) = cos at and f(t) = tn for n ≥ 0: L[sin at] and L[cos at] (h) Properties of LT/ILT: r = 1)) = (-1)", cos((2n + 1) == -S[W -b ± √b² - 4ac 2a x₂ (t) = x₁(t) 1/[² S s² + a² (2) Shift/Scaling: L[eat f(t)] = F(s − a) for constant a R and L[ƒ(at)] = ¹ F(2) for constant a > 0. (3) LT of derivatives: L[f(n) (t)] = snF(s) — sn-¹f(0) — sn-2 f'(0) fn-1 (0) for n ≥ 1. ● LT of integrals: L [ f(0)d0] = F(s) when f(0) = 0. S (4) Derivative of LT or LT of multiplication by polynomials: L[t" f(t)] = (−1)nd 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: • Euler equation s = lnt or t= es, • Bernoulli equation: z = x-k, • k-homogeneous equation: z = ½ or x = zt. and L[t"] e-S p(t)dt x²(t) dt - ¹977) · = 0. -- = (j) Formula for Variation of Parameters: xp(t) = x₁(t)u₁(t) + x₂(t)u₂ (t) when x₂(t)g(t) x₁ (t)g(t) u₁(t): dt and W(x₁, x₂)(t)] * u₂(t) = = 7(x1, x2)(t)] (k) Change of variables: n! gn+1 dt