Groups like SO$(2,1)$ have been studied in several frameworks: geometry and generation of classical groups over various ground fields, where unipotent elements tend to appear as transvections; real Lie groups, where the structure theory of groups like this is well developed (as in Helgason's old book, for example, republished by AMS); real points of (almost) simple algebraic groups, where papers by Borel and Tits have worked out the abstract group structure and generation in considerable generality.    From the last point of view, I guess the crucial point about your question is that the group is *isotropic* over $\mathbb{R}$ and thus noncompact as a Lie group unlike SO(3).   In particular, it has nontrivial unipotent elements (here of infinite order as group elements); the subgroup they generate in the algebraic group setting is closed and normal as
well as defined over $\mathbb{R}$.   

Your example is old and references can be quoted, but you need to keep in mind the different approaches possible.   What is simplest here depends a lot on your viewpoint.