I've never found the definitions of the term "denotational semantics" useful for understanding the concept and its significance. Rather, I think it's best approached instead by considering the forms of reasoning that denotational semantics enables.

Specifically, denotational semantics enables **equational reasoning** with **referentially transparent** programs. Wikipedia gives this introductory definition of referential transparency:

An expression is said to be referentially transparent if it can be replaced with its value without changing the behavior of a program (in other words, yielding a program that has the same effects and output on the same input).

But a more precise definition wouldn't talk about replacing an expression with a "value", but rather replacing it with *another expression*. Then, referential transparency is the property where, if your replace *parts* with replacements that have **the same denotation**, then the resulting wholes *also* have the same denotation.

So IMHO, as a programmer, that's the key thing to understand: denotational semantics is about how to give mathematical "teeth" to the concept of referential transparency, so we can give principled answers to claims about correctness of substitution. In the context of functional programming, for example, one of the key applications is: when can we say that two function-valued expressions actually denote "the same" function, and thus either can safely substitute for the other? The classic denotational answer is extensional equality: two functions are equal if and only if they map the same inputs to the same outputs, so we just have to prove whether the expressions in question denote extensionally equivalent functions. So for example, Quicksort and Bubblesort are notably different arguments, but denotationally they are the same function.

In the context of reactive programming, the big question would be: when can we say that two different expressions nevertheless denote the same event stream or time-dependent value?