(Some parts of your question (ease of use, simplicity, etc.) are a bit subjective and I'll answer them at the end of this post.)

Let's look at space usage. First, let's suppose that you have a binary search tree with n nodes. What's the total space usage required? Well, each node stores some data plus two pointers. You might also need some amount of information to maintain balance information. This means that the total space usage is

n * (2 * sizeof(pointer) + sizeof(data) + sizeof(balance information))

So let's think about an equivalent skiplist. You are absolutely right that the real amount of memory used by a skiplist depends on the heights of the nodes, but we can talk about the *expected* amount of space used by a skiplist. Typically, you pick the height of a node in a skiplist by starting at 1, then repeatedly flipping a fair coin, incrementing the height as long as you flip heads and stopping as soon as you flip tails. Given this setup, what is the expected number of pointers inside a skiplist?

An interesting result from probability theory is that if you have a series of independent events with probability p, you need approximately 1 / p trials (on expectation) before that event will occur. In our coin-flipping example, we're flipping a coin until it comes up tails, and since the coin is a fair coin (comes up heads with probability 50%), the expected number of trials necessary before we flip tails is 2. Since that last flip ends the growth, the expected number of times a node grows in a skiplist is 1. Therefore, on expectation, we would expect an average node to have only two pointers in it - one initial pointer and one added pointer. This means that the *expected* total space usage is

n * (2 * sizeof(pointer) + sizeof(data))

Compare this to the size of a node in a balanced binary search tree. If there is a nonzero amount of space required to store balance information, the skiplist will indeed use (on expectation) less memory than the balanced BST. Note that many types of balanced BSTs (e.g. treaps) require a lot of balance information, while others (red/black trees, AVL trees) have balance information but can hide that information in the low-order bits of its pointers, while others (splay trees) don't have any balance information at all. Therefore, this isn't a *guaranteed* win, but in many cases it will use space.

As to your other questions about simplicity, ease, etc: that really depends. I personally find the code to look up an element in a BST far easier than the code to do lookups in a skiplist. However, the rotation logic in balanced BSTs is often substantially more complicated than the insertion/deletion logic in a skiplist; try seeing if you can rattle off all possible rotation cases in a red/black tree without consulting a reference, or see if you can remember all the zig/zag versus zag/zag cases from a splay tree. In that sense, it can be a bit easier to memorize the logic for inserting or deleting from a skiplist.

Hope this helps!