**Disclaimer-** The main source of some definitions are wikipedia, any suggestion to improve my answer is welcome.

Although this post has an accepted answer and is a good one I was still in confusion and would like to add some more clarification regarding the difference between these terms.

(1)**FULL BINARY TREE-** A full binary tree is a binary tree in which every node other than the leaves has two children.This is also called *strictly binary tree*.

The above two are the examples of full or strictly binary tree.

(2)**COMPLETE BINARY TREE-** Now, the definition of complete binary tree is quite ambiguous, it states :- A complete binary tree is a binary tree in which every level, *except possibly the last*, is completely filled, and all nodes are as far left as possible. *It can have between 1 and 2h nodes, as far left as possible, at the last level h*

Notice the lines in italic.

The ambiguity lies in the lines in italics , "except possibly the last" which means that the last level may also be completely filled , i.e this exception need not always be satisfied. If the exception doesn't hold then it is exactly like the second image I posted, which can also be called as **perfect binary tree**. So, a perfect binary tree is also full and complete but not vice-versa which will be clear by one more definition I need to state:

**ALMOST COMPLETE BINARY TREE-** When the exception in the definition of complete binary tree holds then it is called almost complete binary tree or nearly complete binary tree . It is just a type of complete binary tree itself , but a separate definition is necessary to make it more unambiguous.

So an almost complete binary tree will look like this, you can see in the image the nodes are as far left as possible so it is more like a subset of complete binary tree , to say more rigorously every almost complete binary tree is a complete binary tree but not vice versa . :