MinHeaps are designed to give you the minimum element very quickly. Just peeking at the minimum element (without removing) takes O(1) (constant) time. Usually, you will remove the minimum element, which will force you to re-heapify the heap, which takes log(n) time. The wikipedia article drawing shows a MaxHeap, but implementing a MinHeap is almost identical.

To find the minimum element in a (single) Stack takes **n** time (and log(n) < n), since you'll have to search all the elements in the Stack to find the minimum. So you'll need to `pop()`

each element off, check if it is smaller than the minimum you remembered, and push() it onto an auxiliary stack until you went through the entire stack. Therefore, you will generally want to use a MinHeap if getting the minimum element is the main purpose of your data structure.

On the other hand, the two-stack solution referred to by others has O(1) complexity for operations (add, remove, and getMin), but O(n) time for removeMin. It also has 2N space requirements in the worst case.

To summarize:

```
add/push 1 remove/pop 1 peekMin removeMin space
========== ============ ======= ========= =====
one stack O(1) O(1) O(n) O(n) n
two stacks O(1) O(1) O(1) O(n) 2n
minHeap O(log(n) N/A O(1) O(log n) n
```

As @rici points out minHeap, supports removeMin operation in O(log n) i.e, faster than the stacks, however, for add/remove and peekMin, two-stack solution is faster. minHeap also does not maintain order, outside of relations "greater than" and "less than".

systemstack andsystemheap for memory allocation, or are you referring to using stack and heap data structures? – mbeckish Mar 15 '13 at 18:17