Every process has file descriptor table. Basically, this is mere array of pointers of particular size (depends on the maximum value of open file descriptors the process may have). Every file descriptor is an entry in this array (think of it like an index to the array). This pointers point to the values associated with file descriptor: mainly, descriptor's flags (close on exec flag but may be more), the pointer to an internal file structure and the other values related to the current OS system you running on. The pointer to the internal file structure may be in more interest for you because it contains the pointer to v-node structure which in case contains the value of i-node. Think of the i-node as (it's rather rough similarity) the offset from the start of the partition the file resides on. I repeat - this is very vague analogy but it gives you the imagine of where the file may really be kept. So, every process opens a file, refers to the same i-node, shares the same current offset and so on. The i-node value may be thought as the value of pointer operated by the kernel in the kernel space.
The file system dependent/independent split was done just above the UNIX-kernel inode layer. This was an obvious choice, as the inode was the main object for file manipulation in the kernel. [...] The file system dependent inode was renamed vnode (virtual node). All file manipulation is done with a vnode object. Similarly, file systems are manipulated through an object called a vfs (virtual file system). The vfs is the analog to the old mount-table entry. The file system independent layer is generally referred to a the vnode layer.
Therefore, at the user space you a dealing with some internal structure which obviously contains the i-node number - the number manipulated by the kernel inside the kernel space. This structures has different memory address inside their virtual memory address space.
There is one closely related question you might be interested in.