Let:

- y be the distance between the boat and the dock
- x be the distance between the boat and the pulley
- z be the length of the rope

Since the pulley is 6 feet above the water level and the rope is being pulled in at a rate of 2 ft/s, we have:

x^2 + 6^2 = z^2
2x(dx/dt) = 2(dz/dt)

When the boat is 3 feet from the dock (y = 3), we want to find dy/dt when y = 3. At this point, we have x = 5 (6-3-1) and z = 8 (from Pythagoras' theorem).

From the first equation:

5^2 + 6^2 = 8^2
25 + 36 = 64
61 = 64

Differentiating implicitly with respect to time t:

10x(dx/dt) = 16(dz/dt)

Solve for (dz/dt):

(dz/dt) = 5/4(dx/dt)

Substitute x = 5 and (dx/dt) = -2 into the equation:

(dz/dt) = 5/4(-2) = -5/2 ft/s

Since (dy/dt) = (dx/dt), substitute (dx/dt) = -2 and x = 5 into the equation:

(dy/dt) = -2 ft/s

Therefore, the boat is approaching the dock at a rate of 2 ft/s at the instant when the boat is 3 feet from the dock.