As usual your questions go to the very bone. I shall try to articulate an answer (or at least a sketch thereof), knowing all too well that this is impossible in full.
The two terms, Analysis and Synthesis, go well before Kant, to the very beginning of western thought ( they somehow appeared in Aristoteles, for instance in his **Analytica Priora**, but he probably incorporated previous knowledge).
From the etimolopgical dictionary .
Analysis, circa 1580s, "resolution of anything complex into simple elements" (opposite of synthesis), from Medieval Latin analysis (15c.), from Greek analysis "solution of a problem by analysis," literally "a breaking up, a loosening, releasing," noun of action from analyein "unloose, release, set free; to loose a ship from its moorings," in Aristotle, "**to analyze," from ana "up, back, throughout" (see ana-) + lysis "a loosening," from lyein "to unfasten"** (from PIE root *leu- "to loosen, divide, cut apart").
**So, Analysis basically means to solve some concept into its simpler
constituents, whereas Synthesis is the opposite direction.**
In modern day we could say that math is divided into two (and entwined) camps, analytics, and synthetic (in Lawvere's terminology the second one is called **CONCEPTUAL**). One would be tempted to replace them with constructive vs platonic, and perhaps one would not go too far off, but with many caveats.
The examples abound: for instance, one can define a smooth manifold intrinsecally, or present it with charts.
Now, what is interesting is the interplay between these two sides: how to pass from the synthetic to the analytic viewpoint and conversely?
*I believe the method is universal: suppose you have several analytic expressions and you surmise they are the same, then IF you can prove explicitly that this is indeed the case, you form an equivalence class, and you say that these two versions are different instances of presentation of one "conceptual" object.*
In other words, the manifold is the concept which admits several chart presentations.
PS Descartes is the official father of analytic geometry, even though some Greek anticipated him.
What is intriguing is that Descartes is in a way the father of both modern philosophy and mathematics. In his **Discourse of the Method** he elaborated his universal way of reasoning, which distinguished 4 phases, 2 of them being Analysis and Synthesis. It is not too much of a stretch thinking that his analytic geometry is an application of his own method (of which he was very proud, and rightly so)
PPS it is not by chance that Lawvere has written (with Schanuel) Conceptual Mathematics. Category Theory (including higher cats) is so far perhaps the best tool we have to treat Synthetic Math, though by no means the only one. That is both its greatness and its limit: it captures the invariant side of math, but of course it hides the other one (think of groups for instance: to study the cat of Groups tells you all you need to know of general groups, but if I want to study say SU(5) I need to calculate....