See here: 8*n*^{2} = 64*n* log_{2} *n*. Just put both things in a single equation.

I.e., roughly *n* = 43 is the limit of insertion sort's usefulness here.

Usually you would solve this by solving above equation *f*(*n*) = *g*(*n*) by solving *f*(*n*) − *g*(*n*) = 0, however, the analytical result in this case isn't pretty as you're mixing a polynomial with a logarithm function. I'd just try out a few values and see where the result flips from positive to negative. Once you have one positive and one negative point you can use bisection to narrow it down.

The brute-force way would be to simply try out all *n* up to a certain point. You already know that O(*n*^{2}) algorithms aren't suitable for large datasets, so the *n* has to be quite small. For my testing it looked like this:

```
PS Home:\> function lb($n){[math]::Log($n)/[math]::Log(2)} # binary logarithm
PS Home:\> 1..80 | %{,($_,(8*$_*$_),(64*$_*(lb $_)))} | %{"{0}: delta={3}, I={1}, M={2}" -f $_[0],$_[1],$_[2],($_[2]-$_[1])}
...
38: delta=1210,9597126948, I=11552, M=12762,9597126948
39: delta=1024,36393828017, I=12168, M=13192,3639382802
40: delta=824,135922911648, I=12800, M=13624,1359229116
41: delta=610,216460117852, I=13448, M=14058,2164601179
42: delta=382,549232429308, I=14112, M=14494,5492324293
43: delta=141,080604940173, I=14792, M=14933,0806049402
44: delta=−114,240561917371, I=15488, M=15373,7594380826
45: delta=−383,463082570537, I=16200, M=15816,5369174295
46: delta=−666,633601368154, I=16928, M=16261,3663986318
47: delta=−963,796734153668, I=17672, M=16708,2032658463
48: delta=−1274,99519778461, I=18432, M=17157,0048022154
...
```

(Excuse the horrible code; this was just a very quick doodle.)