The optimal method doesn't need logn time for inserting a node.

The optimal method starts by arbitrarily putting the elements on a
binary tree, respecting the shape property (as the tree could be
represented by an array). Then starting from the lowest level and
moving upwards, shift the root of each subtree downward as in the
deletion algorithm until the heap property is restored. More
specifically if all the subtrees starting at some height `h`

(measured
from the bottom) have already been "heapified", the trees at height
`h+1`

can be heapified by sending their root down along the path of
maximum valued children when building a `max-heap`

, or minimum valued
children when building a `min-heap`

. This process takes `O(h)`

swap
operations per node. In this method most of the heapification takes
place in the lower levels. Since the height of the heap is `logn`

,
the number of nodes at height is `h`

. Therefore, the cost of
heapifying all subtrees is:

_{h=0}∑^{logn} n/2^{h+1} = O(n *
_{h=0}∑^{logn}h/2^{h} ) which is less than

O(n * _{h=0}∑^{∞}h/2^{h} )

```
since h / 2h converges to 2 as it is an infinite series
```

it is equal to `O(n)`

Source: http://en.wikipedia.org/wiki/Binary_heap#Building_a_heap