Final answer:
To find the velocity of the boat at time t, we set up and solve the differential equation 40 - 2v = 200a. However, without additional information about the initial conditions, we cannot determine the exact values of v and a at any given time t. The limiting velocity of the boat is found by setting a = 0 in the equation, which gives v = 20 m/s.
Step-by-step explanation:
To set up the differential equation, we start with Newton's second law: F = ma, where F is the net force acting on the boat, m is the mass of the boat, and a is the acceleration of the boat.
The net force is the difference between the thrust force and the resistive force: F = 40 - 2v, where v is the velocity of the boat.
Plugging in the values, we get: 40 - 2v = ma.
Since the mass of the boat is given as 200.0 kg, the differential equation becomes: 40 - 2v = 200a.
To solve for v, we can rearrange the equation as: 2v + 200a = 40.
Now, we can use calculus to solve this differential equation. However, without additional information about the initial conditions, it is not possible to determine the exact values of v and a at any given time t. Therefore, we cannot determine the velocity of the boat at time t. However, we can solve for the limiting velocity by setting a = 0. From the equation 2v + 200(0) = 40, we find that the limiting velocity is v = 20 m/s.