Solve the following ODE proble using Laplace. [Ignoring units for simplicity] The average electromagnetic railgun on a Gundam consists of a frictionless, open-to-the-environment, rail in which a projectile of mass m is imparted a force F from time t=0 to time t = t₁. Before and after the bullet exits the railgun, it experiences the normal resistance due to its environment, i.e. FR = n(t), where v(t) is the instanteneous speed of the bullet. The one-dimensional trajectory of the bullet is then described by the differential equation my"(t) = F÷(t)¤(−t+t₁)-ny' (t), with y(0) = 0 = y'(0). We would like to use this to see if the Gundam can hit a moving target. a) Apply the Lapalce transform on both sides and obtain the corresponding equation for L[y(t)](s). Fill in the gaps below to give your answer, i.e., Ly(t)](s) = F(1-e-¹²) P() where P(s) - Xs+

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Solve the following ODE proble using Laplace. [Ignoring units for simplicity] The average electromagnetic railgun on a Gundam consists of a frictionless, open-to-the-environment, rail in which a projectile of mass m is imparted a force F from time t = 0 to time t = t₁. Before and after the bullet exits the railgun, it experiences the normal resistance due to its environment, i.e. FR = n(t), where v(t) is the instanteneous speed of the bullet. The one-dimensional trajectory of the bullet is then described by the differential equation my" (t) = F(t) (-t+t₁)-ny' (t), with y(0) = 0 = y'(0). We would like to use this to see if the Gundam can hit a moving target. a) Apply the Lapalce transform on both sides and obtain the corresponding equation for Lly(t)](s). Fill in the gaps below to give your answer, i.e., F(1-¹) Ly(t)](s) = P(s) where P(s): X8³+ X8² + X8+