So they solve for the problem in Many dimensions using a divide-and-conquer approach. Binary search or divide-and-conquer is mega fast. Basically, if you can split a dataset into two halves, and keep doing that until you find some info you want, you are doing it as fast as humanly and computerly possible most of the time.

For this question, it means that we divide the data set of points into two sets, S1 and S2.

All the points are numerical, right? So we have to pick some number where to divide the dataset.

So we pick some number *m* and say it is the median.

So let's take a look at an example:

(14, 2)

(11, 2)

(5, 2)

(15, 2)

(0, 2)

What's the closest pair?

Well, they all have the same Y coordinate, so we can look at Xs only... X shortest distance is 14 to 15, a distance of 1.

How can we figure that out using divide-and-conquer?

We look at the greatest value of X and the smallest value of X and we choose the *median* as a dividing line to make our two sets.

Our median is 7.5 in this example.

We then make 2 sets

S1: (0, 2) and (5, 2)

S2: (11, 2) and (14, 2) and (15, 2)

Median: 7.5

We must keep track of the median for every split, because that is actually a vital piece of knowledge in this algorithm. They don't show it very clearly on the slides, but knowing the median value (where you split a set to make two sets) is essential to solving this question quickly.

We keep track of a value they call *delta* in the algorithm. Ugh I don't know why most computer scientists absolutely suck at naming variables, you need to have descriptive names when you code so you don't forget what the f000 you coded 10 years ago, so instead of delta let's call this value *our-shortest-twig-from-the-median-so-far*

Since we have the median value of 7.5 let's go and see what *our-shortest-twig-from-the-median-so-far* is for Set1 and Set2, respectively:

Set1 : *shortest-twig-from-the-median-so-far* 2.5 (5 to *m* where *m* is 7.5)

Set 2: *shortest-twig-from-the-median-so-far* 3.5 (looking at 11 to *m*)

So I think the key take-away from the algorithm is that this *shortest-twig-from-the-median-so-far* is something that you're trying to improve upon every time you divide a set.

Since S1 in our case has 2 elements only, we are done with the left set, and we have 3 in the right set, so we continue dividing:

S2 = { (11,2) (14,2) (15,2) }

What do you do? You make a new median, call it *S2-median*

*S2-median* is halfway between 15 and 11... or 13, right? My math may be fuzzy, but I think that's right so far.

So let's look at the *shortest-twig-so-far-for-our-right-side-with-median-thirteen* ...

15 to 13 is... 2

11 to 13 is .... 2

14 to 13 is ... 1 (!!!)

So our *m* value or *shortest-twig-from-the-median-so-far* is improved (where we updated our median from before because we're in a new chunk or Set...)

Now that we've found it we know that `(14, 2)`

is one of the points that satisfies the shortest pair equation. You can then check exhaustively against the points in this subset (15, 11, 14) to see which one is the closer one.

Clearly, `(15,2) and (14,2)`

are the winning pair in this case.

Does that make sense? You must keep track of the median when you cut the set, and keep a new median for everytime you cut the set until you have only 2 elements remaining on each side (or in our case 3)

The magic is in the median or *shortest-twig-from-the-median-so-far*

Thanks for asking this question, I went in not knowing how this algorithm worked but found the right highlighted bullet point on the slide and rolled with it. Do you get it now? I don't know how to explain the median magic other than binary search is f000ing awesome.