**Short version for general approach.**

There's an algo out there called the Thompson-McNaughton-Yamada Construction Algorithm or sometimes just "Thompson Construction." One builds intermediate NFAs, filling in the pieces along the way, while respecting operator precedence: first parentheses, then Kleene Star (e.g., a*), then concatenation (e.g., ab), followed by alternation (e.g., a|b).

**Here's an in-depth walkthrough for building (b|a)*b(a|b)'s NFA**

*Building the top level*

Handle parentheses. Note: In actual implementation, it can make sense to handling parentheses via a recursive call on their contents. For the sake of clarity, I'll defer evaluation of anything inside of parens.

Kleene Stars: only one * there, so we build a placeholder Kleene Star machine called P (which will later contain b|a).
Intermediate result:

Concatenation: Attach P to b, and attach b to a placeholder machine called Q (which will contain (a|b). Intermediate result:

There's no alternation outside of parentheses, so we skip it.

Now we're sitting on a P*bQ machine. (Note that our placeholders P and Q are just concatenation machines.) We replace the P edge with the NFA for b|a, and replace the Q edge with the NFA for a|b via recursive application of the above steps.

*Building P*

Skip. No parens.

Skip. No Kleene stars.

Skip. No contatenation.

Build the alternation machine for b|a. Intermediate result:

*Integrating P*

Next, we go back to that P*bQ machine and we tear out the P edge. We have the *source of the P edge* serve as the starting state for the P machine, and the *destination of the P edge* serve as the destination state for the P machine. We also make that state reject (take away its property of being an accept state). The result looks like this:

*Building Q*

Skip. No parens.

Skip. No Kleene stars.

Skip. No contatenation.

Build the alternation machine for a|b. Incidentally, alternation is commutative, so a|b is logically equivalent to b|a. (Read: skipping this minor footnote diagram out of laziness.)

*Integrating Q*

We do what we did with P above, except replacing the Q edge with the intermedtae b|a machine we constructed. This is the result:

Tada! Er, I mean, QED.

**Want to know more?**

All the images above were generated using an online tool for automatically converting regular expressions to non-deterministic finite automata. You can find its source code for the Thompson-McNaughton-Yamada Construction algorithm online.

The algorithm is also addressed in Aho's Compilers: Principles, Techniques, and Tools, though its explanation is sparse on implementation details. You can also learn from an implementation of the Thompson Construction in C by the excellent Russ Cox, who described it some detail in a popular article about regular expression matching.