In this example, there is a normal force so you know something must be on a floor, table, or other large surface. Also, there is no applied or friction force, like there would be if you were dragging an object.

Since the car is accelerating, the applied force must be larger than the frictional force!

Since the ball is moving on a "frictionless" surface, there is no force of friction. However, it is also moving at a constant speed, which means that all the forces must be balanced. Therefore there is also no applied force.

Careful--just because something is moving doesn't mean there's a force in that direction! If something is accelerating then it must have a force in that direction.

If the skydiver is falling at a constant speed, the two forces must be the same length. Otherwise the skydiver would be accelerating.

In this case, there must be air resistance because otherwise, the skydiver would be accelerating due to gravity since nothing would balance the gravity.

In this case, there is a net force in the x direction, so the object must be accelerating. It can either be speeding up or slowing down. The only scenario where that is happening is the one where the box is sliding to a stop due to friction.

There is only a force of gravity in this example, so the forces are not balanced. That means that the scenario must include acceleration. The elevator example includes a tension force, so that leaves us with the ball after it has been thrown.

Remember, once you let go of a ball, there is no longer an applied force!

Since it's being held up by a rope, the upward force is tension.