I worked in an office summers after high school when I started college. I had studied in AP Computer Science, among other things, **sorting and searching**.

I applied this knowledge in several physical systems that I can recall:

## Natural merge sort to start…

A system printed multipart forms including a file-card-sized tear off, which needed to be filed in a bank of drawers.

I started with a pile of them and sorted the pile to begin with. The first step is picking up 5 or so, few enough to be easily placed in order in your hand. Place the sorted packet down, criss-crossing each stack to keep them separate.

Then, *merge* each pair of stacks, producing a larger stack. Repeat until there is only one stack.

## …Insertion sort to complete

It is easier to file the sorted cards, as each next one is a little farther down the same open drawer.

## Radix sort

This one nobody else understood how I did it so fast, despite repeated tries to teach it.

A large box of check stubs (the size of punch cards) needs to be sorted. It looks like playing solitaire on a large table—deal out, stack up, repeat.

# In general

30 years ago, I did notice what you’re asking about: the ideas transfer to physical systems quite directly because there are relative costs of **comparisons** and **handling records**, and levels of caching.

# Going beyond well-understood equivalents

I recall an essay about your topic, and it brought up the **spaghetti sort**. You trim a length of dried noodle to indicate the key value, and label it with the record ID. This is O(n), simply processing each item once.

Then you grab the bundle and tap one end on the table. They align on the bottom edges, and they are now sorted. You can trivially take off the longest one, and repeat. The read-out is also O(n).

There are two things going on here in the “real world” that don’t correspond to algorithms. First, aligning the edges is a parallel operation. Every data item is also a processor (the laws of physics apply to it). So, in general, you scale the available processing with n, essentially dividing your classic complexity by a factor on n.

Second, how does aligning the edges accomplish a sort? The real sorting is in the read-out which lets you find the longest in one step, even though you *did* compare all of them to find the longest. Again, divide by a factor of n, so finding the largest is now O(1).

Another example is using analog computing: a physical model solves the problem “instantly” and the prep work is O(n). In principle the computation is scaling with the number of interacting components, not the number of prepped items. So the computation scales with n². The example I'm thinking of is a weighted multi-factor computation, which was done by drilling holes in a map, hanging weights from strings passing through the holes, and gathering all the strings on a ring.

`n`

processors (cores) to sort out an array of just`n`

items you can easily achieve`O(n)`

complexity. A bitter truth is we usually have to sort long arrays (thousands and millions of items) on CPU with 2..10 cores only.comparisonsthat must be made in a sort thatcompares pairs of items. There is no requirement that a sort algorithmcompare pairs of items; if you can come up with a sort that does not do pairwise comparisons, you can make it faster than n log n.`O(n)`

on its own tells younothing- it's only useful for comparing algorithms with similar constraints and running on similar architectures; in introductory courses for algorithmic complexity we use a very simplified model "computer" that has little to do with centrifuges or real computers :)19more comments