So, if within δ * 2δ rectangle R, we only need to compare one point from the left side to 7 points on the right side. What I don't understand is, despite reading the proof, inside R we can fill as many points as we want inside the rectangle which may exceed the total number of 7. Imagine if we have δ = 2, a point p(1.2, 1.1) on the left side, and on the right side, we have a whole bunch of q, such as q(1.5, 1.7) , q(1.4, 1.3),.....how can only comparing 7 points detects the closest pair? I thought that we must compare every points within rectangle R if it is the case. Please help me.
There may only be 6 points inside your rectangle, since that's the maximum number of points that you can put in a rectangle with sides \delta and 2 * \delta maintaining the property that they are at least \delta distant from each other. The way to lay those 6 points is shown in the figure below: You can check for yourself that there's way of putting another point inside the rectangle without violating the distance property. If you add more than 6 points, they would be less than \delta apart, which is a contradiction, since \delta is supposed to be the distance between the closest pair. Since there may be a maximum of 6 points, testing 7 will guarantee that you find the solution. I got figure 1 from these UCSB slides, which may be useful to you. 


q(1.5,1.7)
andq(1.4,1.3)
is less thanδ
, which is impossible by construction ofδ
. – n.m. Mar 22 '12 at 20:10