I need a general formula to calculate the minimum height of the binary tree and the maximum height of the binary tree. (not the binary search tree)
If you have N elements, the minimum height of a binary tree will be log2(N)+1.
For a full binary tree, the maximum height will be N/2.
For a non-full binary tree, the maximum height will be N.
First there may be some difference as to how computer science calculates the height of a tree, versus the way height is determined in discrete mathematics (graph theory), this may be due to the existence of data at any one node (or vertice), while in mathematics, its a pure theory approach.
So maybe its best you clarify which one you need.
In discrete mathematics, trees are classified as m-ary trees, so a bin-ary tree is a 2-ary tree. Also at any given height, there can be at most 2^h = L (leaves). This is important to notice, since it confirms that the root is at height zero, hence 2^0 = 1 leaf...1 vertice...the root.
So given n vertices, the height of a tree is given by the formula n = 2^( h + 1 ) - 1
Since you are looking for h, you have to take the log2 of both sides of the formula n = 2^( h + 1 ) - 1
For a full binary tree, the max height is log2( n + 1 ) = log2( 2^( h + 1 ) ) this equals ceiling( log2( n + 1 ) - 1 ) = h
For a non-full binary tree, the max height = ( n - 1 ) therefore if you have n vertices, the root must be subtracted to get the max height, because of the previous formula above (2^h = L)
For min heights, extrapolate from the above rules.
Think about how the structure of the tree can change.
For example, if the tree is completely unbalanced then this is the worst case - each node will have exactly one child. In the best case, the tree is completed balanced, and each node has two children.
Since it sounds like homework, I'll leave it there.
The max height is n and the min height (IE a perfect binary tree) is the (log base 2( n + 1)) - 1