First some definitions: *m* is the number of make-set operations. *n* is the sum of union/find operations.

**Standard Version**

Assuming that `join(a,b)`

makes `b`

the root of `a`

.

If have a calling sequence of *0.5n* calls like `joint(1,2)`

, `joint(2,3)`

, `joint(3,4)`

you can make a chain of *0.5n* nodes with `1`

in the buttom. Then `find(1)`

will take *0.5n* time, so calling that *0.5n* times and your runtime will be *0.25n^2=O(n^2)*

As we must do *m* `makeset`

operations we end up with O(m+n^2).

**Weighted-Union**

I assume the weight the size of the set (as opposed to rank).

For a given set let *h* be the height of the tree representing it and *w* its size. `find`

takes at most *h* time in that set. By induction we can prove that the *h<=log(w)*.

For a single node which has *w=1* and *h=0* the formula trivially holds.

Now consider a join between two tree *a* and *b*, where *a* becomes the new root. Assuming *h<=log(w)* holds for *a* and *b* we will show it also holds for the union. We know that *wa>=wb => wab = wa+wb >= 2wb*. If *a* is strictly taller than *b* we have *hab = ha <= log(wa) <= log(wab)*. Otherwise (when *hb >= ha*) we have *hab = 1+hb <= 1+log(wb) = log(2wb) <= log(wab)*

This proves that *h<=log(w)* holds. In less mathematical terms we have prove that the height of any set is less than the logarithm of its size, so a find takes at most *O(log(k))* time where k is the size of the set.

Let *j* be the number of union operations. Each `union`

touches 2 elements, so the maximal size of any set is bounded by *2j*.

The runtime of the union and finds is therefore *O(j+k log(2j)) = O(n + n log(2n)) = O(n log(n))*. Again we must do *m* `makeset`

s, so in total we get *O(m + n log(n))*