A simple detection with background subtraction will give a result in every sample period, however the result will be noisy (due to measurement noise and perhaps quantization) and detection errors will have a huge impact.

If you want to observe an object you usually know something about how it will move. It won't jump from one position to the next but move there in a continuous way. The Kalman filter combines the measurements from the simple detection algorithm and combines them with the model knowledge that you have about the object (position can't jump), so it filters the measurement and considers the history of the measurements. Considering a linear system, you can prove that the Kalman filter is the optimal way of filtering the data considering the measurement noise of the system.

Edit: In this tutorial, the Kalman filter is obviously used to predict the position of the ball in the next step. In the downwards motion, this works pretty well. As the filter doesn't know anything about the floor, the prediction is of course wrong when the ball hits the ground. During the upwards motion, the prediction still suffers from this error.