The assumptions of necessary rationality and necessary knowledge of
strategies, also known as perfect prediction, lead to at most one surviving
outcome, immune to the knowledge that the players have of them. Solutions
concepts implementing this approach have been defined on both dynamic games
with perfect information and no ties, the Perfect Prediction Equilibrium, and
strategic games with no ties, the Perfectly Transparent Equilibrium.
In this paper, we generalize the Perfectly Transparent Equilibrium to games
in extensive form with imperfect information and no ties. Both the Perfect
Prediction Equilibrium and the Perfectly Transparent Equilibrium for strategic
games become special cases of this generalized equilibrium concept. The
generalized equilibrium, if there are no ties in the payoffs, is at most
unique, and is Pareto-optimal.
We also contribute a special-relativistic interpretation of a subclass of the
games in extensive form with imperfect information as a directed acyclic graph
of decisions made by any number of agents, each decision being located at a
specific position in Minkowski spacetime, and the information sets and game
structure being derived from the causal structure. Strategic games correspond
to a setup with only spacelike-separated decisions, and dynamic games to one
with only timelike-separated decisions.
The generalized Perfectly Transparent Equilibrium thus characterizes the
outcome and payoffs reached in a general setup where decisions can be located
in any generic positions in Minkowski spacetime, under necessary rationality
and necessary knowledge of strategies. We also argue that this provides a
directly usable mathematical framework for the design of extension theories of
quantum physics with a weakened free choice assumption.Comment: 25 pages, updated technical repor