We consider structural and algorithmic questions related to the Nash dynamics
of weighted congestion games. In weighted congestion games with linear latency
functions, the existence of (pure Nash) equilibria is guaranteed by potential
function arguments. Unfortunately, this proof of existence is inefficient and
computing equilibria is such games is a {\sf PLS}-hard problem. The situation
gets worse when superlinear latency functions come into play; in this case, the
Nash dynamics of the game may contain cycles and equilibria may not even exist.
Given these obstacles, we consider approximate equilibria as alternative
solution concepts. Do such equilibria exist? And if so, can we compute them
efficiently?
We provide positive answers to both questions for weighted congestion games
with polynomial latency functions by exploiting an "approximation" of such
games by a new class of potential games that we call Ψ-games. This allows
us to show that these games have d!-approximate equilibria, where d is the
maximum degree of the latency functions. Our main technical contribution is an
efficient algorithm for computing O(1)-approximate equilibria when d is a
constant. For games with linear latency functions, the approximation guarantee
is 23+5​​+O(γ) for arbitrarily small γ>0; for
latency functions with maximum degree d≥2, it is d2d+o(d). The
running time is polynomial in the number of bits in the representation of the
game and 1/γ. As a byproduct of our techniques, we also show the
following structural statement for weighted congestion games with polynomial
latency functions of maximum degree d≥2: polynomially-long sequences of
best-response moves from any initial state to a dO(d2)-approximate
equilibrium exist and can be efficiently identified in such games as long as
d is constant.Comment: 31 page