The Knaster-Tarski fixed point theorem says the following:
Let L be a complete lattice and let f : L → L be an order-preserving function. Then the set of fixed points of f in L is also a complete lattice.
Because the set of fixed points of f in L are a complete lattice, there exists a least fixed point of f in L. Additionally, there are potentially an infinite number of other fixed points.
Why do fixed points matter for program analysis? If the lattice L is over abstract program states, a fixed point of the semantics of the loop, f, logically represents an inductive invariant or, in sets, represents a set of program states at a particular program location such that executing the program from that program location back to that same location starting from a state in that set of states, will produce a state within that set of states. These state sets (or inductive invariants) are what abstract interpretation attempts to find.
For an intuitive description of abstract interpretation, I highly recommend the paper, Cousot, P. and Cousot, R.: Static Determination of Dynamic Properties of Programs; ISOP 1976. It predates the "famous" Cousot and Cousot '77 paper, but is somewhat less mired in advanced mathematics.