Merge operation of two arrays, is scanning arrays and picking the lowest/highest of two.

so you have

```
a: [1, 3, 6, 7]
b: [4, 5, 7, 8]
```

you compare like this (sort of pseudo code)

```
indexA = 0;
indexB = 0;
auxilaryArray = [];
indexAux = 0;
while true
if indexA > len(a)-1 or indexb > len(b) -1
break
# you are cherry picking one from the two array which is lesser
# until any one of these array exausts
if(a[indexA] > b[indexB])
auxilaryArray[indexAux++] = b[indexB++]
else
auxilaryArray[indexAux++] = a[indexA++]
#append the remaining array
while indexA < len(a)
auxilaryArray[indexAux++] = a[indexA++]
#appends the remaining array
while indexB < len(b)
auxilaryArray[indexAux++] = b[indexB++]
```

you see if array `a[k]`

, and `b[m]`

the *sum of iterations by the three loops* will be `k+m`

.

In case

```
a: [1, 3, 6, 7]
b: [4, 5, 7, 8]
```

Here is the first loop for this:

```
(0, 0), (1, 0), (2, 0), (2, 1), (2, 2), (3, 2) # 6 iterations; array a exhausted
```

The second loop does not run since `a`

is already scanned.

The third loop appends

```
b[2], b[3] # 2 iterations; b exhaused
```

You see `8 = 4 + 4`

loops running? What's the order `O(n)`

.

In Mergesort the divide operation is logarithmic, `ln n`

-- the merge part is linear. Since you divide and merge back the order becomes multiplicative so Mergesort is `O(nln(n))`

.

Unlike Bubble, Selection, Insertion sort where you scan left to right (O(n)) and then fit the right candidate by consecutive swaps (bubble), or by scanning the minimum in rest of the the unsorted array (selection), or by inserting at right place in sorted part of the array (insertion) -- these operations are O(n)... so the overall order of these algos becomes O(n^{2})