A stable set is defined mathematically by essentiality of the projection map from a closed connected neighborhood in the graph of the Nash equilibria over the space of perturbed games obtained by perturbing players' strategies toward completely mixed strategies. This definition requires more than every nearby game having a nearby equilibrium. Essentiality requires further that no deformation of the projection maps to the boundary, which ensures that perturbations of the fixed point problem defining Nash equilibria have nearby solutions. This is apparently necessary to obtain all the desirable properties listed above. Mertens provided several formal definitions depending on the coefficient module used for homology or
cohomology. A formal definition requires some notation. For a given game G let \Sigma be product of the simplices of the players' of mixed strategies. For each 0 , let P_\delta = \{\,\epsilon\tau \mid 0 \le \epsilon \le \delta,\tau \in \Sigma\,\} and let \partial P_\delta be its
topological boundary. For \eta \in P_{1} let \bar{\eta} be the minimum probability of any pure strategy. For any \eta \in P_1 define the perturbed game G(\eta) as the game where the strategy set of each player n is the same as in G, but where the payoff from a strategy profile \tau is the payoff in G from the profile \sigma = (1-\bar{\eta})\tau + \eta. Say that \sigma is a perturbed equilibrium of G(\eta) if \tau is an equilibrium of G(\eta). Let \mathcal{E} be the graph of the perturbed equilibrium correspondence over P_1, viz., the graph \mathcal{E} is the set of those pairs (\eta,\sigma) \in P_1 \times \Sigma such that \sigma is a perturbed equilibrium of G(\eta). For (\eta,\sigma) \in \mathcal{E}, \tau(\eta,\sigma) \equiv (\sigma - \eta)/(1-\bar{\eta}) is the corresponding equilibrium of G(\eta). Denote by p the natural projection map from \mathcal{E} to P_1. For E \subseteq \mathcal{E}, let E_0 = \{\, (0, \sigma) \in E \, \}, and for 0 let (E_\delta,\partial E_\delta) = p^{-1}(P_\delta,\partial P_\delta) \cap E. Finally, \check{H} refers to
Čech cohomology with integer coefficients. The following is a version of the most inclusive of Mertens' definitions, called *-stability.
Definition of a *-stable set: S \subseteq \Sigma is a *-stable set if for some closed subset E of \mathcal{E} with E_0 = \{\, 0 \,\} \times S it has the following two properties: •
Connectedness: For every neighborhood V of E_0 in E, the set V \setminus \partial E_1 has a connected component whose
closure is a neighborhood of E_0 in E. •
Cohomological Essentiality: p^*: \check{H}^*(P_\delta,\partial P_\delta) \to \check{H}^*(E_\delta, \partial E_\delta) is nonzero for some \delta > 0. If essentiality in cohomology or homology is relaxed to
homotopy, then a weaker definition is obtained, which differs chiefly in a weaker form of the decomposition property.{{cite journal == References ==