The max-heap can have many ways, a better case is a complete sorted array, and in other extremely case, the heap can have a total asymmetric structure.

Here can see this:

In the first case, the kth lagest element is in the kth position, you can compute in O(1) with a array representation of heap.
But, in generally, you'll need to check between (k, 2k) elements, and sort them (or partial sort with another heap). As far as I know, it's O(K·log(k))

And the algorithm:

```
Input:
Integer kth <- 8
Heap heap <- {19,18,10,17,14,9,4,16,15,13,12}
BEGIN
Heap positionHeap <- Heap with comparation: ((n0,n1)->compare(heap[n1], heap[n0]))
Integer childPosition
Integer candidatePosition <- 0
Integer count <- 0
positionHeap.push(candidate)
WHILE (count < kth) DO
candidatePosition <- positionHeap.pop();
childPosition <- candidatePosition * 2 + 1
IF (childPosition < size(heap)) THEN
positionHeap.push(childPosition)
childPosition <- childPosition + 1
IF (childPosition < size(heap)) THEN
positionHeap.push(childPosition)
END-IF
END-IF
count <- count + 1
END-WHILE
print heap[candidate]
END-BEGIN
```

EDITED

I found "Optimal Algorithm of Selection in a min-heap" by Frederickson here:
ftp://paranoidbits.com/ebooks/An%20Optimal%20Algorithm%20for%20Selection%20in%20a%20Min-Heap.pdf

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