Abstract
The rational choice theory is based on this idea that people rationally pursue goals for increasing their personal interests. Here, we present a new concept of rational choice as a hyperrational choice in which the actor thinks about profit or loss of other actors in addition to his personal profit or loss and then will choose an action that is desirable to him. We implement the hyperrational choice to generalize and expand the game theory. Results of this study will help to model the behavior of people considering environmental conditions, the type of behavioral interaction, valuation system of itself and others, and system of beliefs and internal values of societies. Hyperrationality helps us understand how human decisionmakers behave in interactive decisions.
Introduction
The rational choice theory is one of the theories that predicts humans’ and societies’ behaviors in the social sciences. The main hypothesis in the prediction of humans’ behavior is that these have an almost rational and targeted trend. In this theory, society is a set of the people, which has rational action. Principles and fundamentals of the rational actor are the basis of all social sciences theories, which have been explained by some theorists such as Weber (1978), Boudon (1998), and Elster (1989). This theory has been also criticized by many theorists. The theory of rational choice is a component of countless models that enhance our understanding of social phenomena. It would be easy to list many classical and modern sociological works and economic works that owe their scientific value to the fact that they use model. The works of economists and sociologists such as Olson (1965), Oberschall (1973, 1994), Kuran (1995), and Hardin (1995), among others, come to mind, as well as historians such as Root (1994) or political scientists such as Rothstein (2001). As Coleman (1986) states, “Rational actions of individuals have a unique attractiveness as the basis for social theory.” Becker states (1996) “The extension of the utilitymaximizing approach to include endogenous preferences is remarkably useful in unifying a wide class of behavior, including habitual, social, and political behavior.” There are many technical introductions to rational choice theory and the interested reader is referred to the copious literature (see, Simon, 1972; Loomes and Sugden, 1982; Tversky and Kahneman, 1986).
Harsanyi (1980) defines rational action in routine life as a behavior through which people choose the best accessible means to achieve a definite goal. The first and yet the main application of the rational choice theory beyond economics is to use it in politics (Udehn, 2002). Herbert Simon is most famous for what is known to economists as the theory of bounded rationality, bounded rationality is the idea that in decisionmaking, rationality of individuals is limited by the information they have, the cognitive limitations of their minds, and the finite amount of time they have to make a decision (Simon, 1955). The most important theories based on the rational choice theory is decisionmaking theory (Schlaifer and Raiffa, 1961; Abelson and Levi, 1985), Collective action theory (Olson, 1965) and game theory (Von Neumann and Morgenstern, 1953). The theory of rational choice is one of the most important components of many game theory models. Hence, the rationality of the players is one of the fundamental principles, which led to generalization and expansion of this theory.
A choice of behavior in a single person decisionmaking problem is called player’s action. The set of actions available is shown with A. Function \(u:A\rightarrow {\mathbb{R}}\) which relates a outcome such as u(a) with numerical to every member a in A is called payoff function. An individual’s desires lead to a ranking of value outcomes in terms of preference (Webb, 2007). If a person prefers outcome a_{1} to outcome a_{2}, we will show it as a_{1} ≻ a_{2}. If a person is indifferent between the two outcomes a_{1} and a_{2}, it will be shown as a_{1} ~ a_{2}. Showing a_{1} ≽ a_{2} means that person either prefers outcome a_{1} to outcome a_{2} or is indifferent between the two outcomes.
Definition 1(rationality) An individual will be called rational under certainty if their preferences for outcomes satisfy the following conditions:

1.
(Completeness) Either a_{1} ≽ a_{2} or a_{2} ≽ a_{1}.

2.
(Transitivity) If a_{1} ≽ a_{2} and a_{2} ≽ a_{3} then a_{1} ≽ a_{3}.
The completeness condition ensures that all outcomes can be compared with each other. The transitivity condition implies that outcomes can be listed in order of preference (Webb, 2007). One of the important problems of the rational choice theory is that it does not describe the rational behavior of human subjects as well. In the previous methods, failure to pay attention to outcome obtained for other decisionmakers is the main negligence, which can have a considerable effect on the interactive decisions. Recently Eshaghi and Askari (2018) introduced a new concept of rational choice called hyperrational choice. This study demonstrates that how human decisionmakers behave in interactive decisions.
In this paper, in addition to the individual profit (individual preferences), which has been mentioned in the rational choice theory, we focused on profit or loss of other players, which led to the division of persons’ preferences into two classes. The first class is the individual preferences to maximize his benefit or minimize his loss and the second class is preferences of the individual to maximize profit or loss of others (The person’s preferences for others). The individual’s choice among his preferences: individual preferences, preference for others and both of them at the same time, makes his hyperpreferences. Based on the idea, in most conditions, the hyperrationality behavior of an actor is dependent on the person and others’ behavior. Therefore, we present the unified approaches to analysis and cognition of humans and societies’ behavior in social sciences. We implement the hyperrational choice for interpretation strategic interaction between players. For this purpose, we will examine Prisoner’s Dilemma.
The purpose of this paper is to describe a new concept of rationality for determining the importance of outcomes of other players in the game, which is designed to use in the game theory. The assumption of rational behavior is based on the fact that each player seeks the maximum benefit, but in assumption of hyperrational behavior, each player thinks about profit or loss of other actors in addition to his personal profit or loss and then will choose an action, which is desirable to him. One of the most important advantages of this concept emphasizes the importance of the outcomes of other actors in the game. Based on the concept of hyperrationality, a player may not recognize that what action is the most beneficial to him but can choose an action, which causes the maximum loss or benefit for other players. With help of hyperrational concept, we turn a rational individual into a hyperrational individual. The aim is to explain the behavior of agents in a framework better and provide comprehensible understanding in human society. For this end, in the prisoner’s dilemma game, various situations will be considered. Therefore, we achieve an equilibrium, which is not considered as game equilibrium based on the classical concept of rationality.
The outline of the paper is as follows: In section “Hyperrational Choice”, we introduce a new concept of rationality as the hyperrationality concept. In section “Hyperrational Choice as the basis for game theory”, we implement the hyperrational choice as the basis for game theory to generalize and expand this theory. In section “Behavior of individuals in human societies”, we model the behavior of players based on the hyperrationality concept in human societies. We evaluate the proposed model with the prisoner’s dilemma game. “Conclusion” section concludes.
Hyperrational choice
Numerous results from experimental economics have shown that classic rationality assumptions do not describe the behavior of real human subjects. For example, it is not uncommon for people, in experimental situations, to indicate that they prefer A to B, B to C, and C to A (Alexander, 2002). If we consider profit or loss of other persons given rational behavior of the persons, which is based on individual benefit, some of the human behaviors may be described. In 1926 Ragnar Frisch developed for the first time a mathematical model of preferences in the context of economic demand and utility functions (Barten and Böhm 1982; Arrow et al., 1991). In 1944, Von Neumann and Morgenstern introduced the preferences as a formal relation (Von Neumann and Morgenstern, 1953).
Here, we divide preferences of people into two classes. The first class is a set of individual preferences (his or her profit, loss and indifferent between profit and loss) of the person, which seek to maximize his profit or minimize his loss. The second class is a set of preferences for others (profit for other, loss for other and indifferent between profit or loss for others) of the person, which seek to maximize profit or loss of other actors. Based on the second class of preferences (The person’s preferences for others), assumption about profit or loss of other actors can be added in the form of human behaviors such as altruism, devotion, fraud, jealousy, and mistrust to the concept of rationality. As a result, the person has three choices about his preferences: individual preferences, preferences for other actors, and both of them simultaneously. Therefore, an individual’s attitudes to other players’ outcomes in a multiplayer game lead to different type of ranking of preferences socalled hyperpreferences. Hence, the hyperpreferences for each individual specifies six behavioral options. Here, we consider four main behavioral options: individual profit, individual loss, profit for others, and loss for others. In the following, we want to turn a rational individual into a hyperrational individual.
Now consider a rational individual. The set of possible choices of rational individual i ∈ {1,2,…,n} is shown with A_{i} = {a_{1},a_{2},…,a_{n}}. Given hyperpreferences, how will a hyperrational individual behave? We assume that given a set of choices \(B \subseteq {\cal{A}} = A_1 \times A_2 \times \ldots \times A_n\). We define the weak hyperpreferences of actor i ʹ over the set B as follows:
where relation ≽ is complete and transitive and (a_{1},a_{2},…,a_{n}), (b_{1},b_{2},…,b_{n}) ∈ B. We say that (a_{1},a_{2},…,a_{n}) is strictly preferred to (b_{1},b_{2},…b_{n}), or (a_{1},a_{2},…,a_{n}) ≻′ (b_{1},b_{2},…,b_{n}), if (a_{1},a_{2},…,a_{n}) ≽′ (b_{1},b_{2},…,b_{n}) but not (b_{1},b_{2},…,b_{n}) ≽′ (a_{1},a_{2},…,a_{n}). We say the actor is indifferent between (a_{1},a_{2},…,a_{n}) and (b_{1},b_{2},…,b_{n}), or (a_{1},a_{2},…,a_{n}) ~′ (b_{1},b_{2},…,b_{n}), if (a_{1},a_{2},…,a_{n}) ≽′ (b_{1},b_{2},…,b_{n}) and (b_{1},b_{2},…,b_{n}) ≽′ (a_{1},a_{2},…,a_{n}). So, we defined set of hyperpreference over set of preferences.
Definition 2. The relation ≽ ′on B is complete if for all (a_{1},a_{2},…,a_{n}), (b_{1},b_{2},…,b_{n}) ∈ B either (a_{1},a_{2},…,a_{n}) ≽′ (b_{1},b_{2},…,b_{n}) or (b_{1},b_{2},…,b_{n}) ≽′ (a_{1},a_{2},…,a_{n}), or both.
The completeness condition ensures that all action profiles can be compared with each other. Hyperpreferences help the person to consider more realistic conditions for decisionmaking and specify his objectives. Hyperpreferences of an individual have taxonomy characteristic. Taxonomy of hyperpreference means that if we face an actor with two choices of hyperpreferences, she will necessarily have an opinion on which she likes more. Taxonomy of actor’s hyperpreferences depends on environmental condition, the type of behavioral interaction, beliefs system of itself and others and valuation system of itself and others. Taxonomy of hyperpreferences helps to a person to retrieve his/her preferences and reduces the rate of computation. Let \(B \subseteq {\cal{A}} = {A_1} \times {A_2} \times \ldots \times {A_n}\) be a nonempty set and ≽′ is a relation on B. Based on definition of the weak hyperpreferences of actor i, for all (a_{1},a_{2},…,a_{n}), (b_{1},b_{2},…,b_{n}) and (c_{1},c_{2},…,c_{n}) in B we have:

1.
(reflexivity) (a_{1},a_{2},…,a_{n}) ≽′ (a_{1},a_{2},…,a_{n}),

2.
(antisymmetry) if (a_{1},a_{2},…,a_{n}) ≽′ (b_{1},b_{2},…,b_{n}) and (b_{1},b_{2},…,b_{n}) ≽′ (a_{1},a_{2},…,a_{n}) then (a_{1},a_{2},…,a_{n}) = (b_{1},b_{2},…,b_{n}).
Depending on the person’s hyperpreferences on the component of an action profile, transitivity property may exist or may not exist. In other words, based on definition of the weak hyperpreferences of actor i for other actors, if (a_{1},a_{2},…,a_{n}) ≽′ (b_{1},b_{2},…,b_{n}) and (b_{1},b_{2},…,b_{n}) ≽′ (c_{1},c_{2},…,c_{n}) then it can not be concluded (a_{1},a_{2},…,a_{n}) ≽′ (c_{1},c_{2},…,c_{n}).
For example, because of the environmental condition, the type of behavioral interaction and valuation system of actor i and 1, actor i prefer a_{1} to b_{1}, to c_{1}, and c_{1} to a_{1} for actors 1. That is, if an individual simultaneously considers two classes of preferences, transitivity property of outcomes may do not exist. In section “Prisoner's Dilemma”, based on collective profit or collective loss, transitivity property hyperpreferences do not exist. Considering situations, which the individual faces, we define hyperrationality as follows:
Definition 3. (Hyperrational) An individual will be called hyperrational under certainty if is a rational (see Definition 1) and their hyperpreferences (individual or for others) satisfy at least one of the following conditions:

1.
The actor chooses from the set of available alternatives (actions) based on individual preferences;

2.
The actor chooses from the set of available alternatives (actions) based on preferences for other actors.
It can be concluded that each hyperrational actor is a rational actor, but each rational actor is not a hyperrational actor. In this concept, we call a person hyperrational if he considers profit or loss of others in his interaction with other people in society in addition to individual profit or loss. Based on the concept of hyperrationality, an actor may not identify an action, which has the maximum benefit for him but may be able to choose an action, which has the maximum profit or loss for other actors. So, attention to the emphasis on the importance of the outcome of other actors in the game is among the advantage of this concept. Hyperrationality doesnot simplify decisionmaking but specifies how to make a decision. Hyperrational actor removes information cognitive and processing constraints based on the taxonomy of hyperpreferences. The hyperrational actor makes a decision based on his hyperpreferences and chooses an action, which is based on his targets despite knowing no access to full information. The number of decisionmaking stages is different among persons considering prioritization of hyperpreferences; therefore, hyperrational doesn’t mean limited searching.
Some human behaviors can be expressed with help of hyperrationality concept. The emergence of behavior such as jealousy in a person is due to the fact that since the person cannot increase his benefit and is unhappy of that, he prefers not to give more benefit to others. Also, a benevolent player can choose an action based on his hyperrationality, which will bring more benefits to others. In contrast to a rational player with a hyperrational player, the hyperrational player has more chance of winning. Therefore, the concept of hyperrationality can give a new concept of rationality called hyperrational choice theory. Based on the new concept of hyperrational choice, some of the human behaviors can be modeled with help of game theory.
Hyperrational choice as the basis for game theory
Game theory aims to help us understand situations in which decisionmakers interact. Like other sciences, game theory consists of a collection of models. A model is an abstraction that we use to understand our observations and experiences (Osborne, 2004). In order to describe a game, the set of possible choices of rational individual i ∈ {1,2,…,n} is shown with A_{i} = {a_{1},a_{2},…,a_{n}}. So, each individual player i has a set of actions A_{i} available to him and a particular element in the set of actions is denoted by a_{i} ∈ A_{i}. A profile of actions for the players is given by
or alternatively by separating the action of player i from all other players, denoted by −i:
Finally there are payoff functions for each player i:
The concept of “game” indicates interactions between players as well but it has not been clarified in the mathematical modeling. In other words, mathematical modeling is unable to express dependency of strategy choice of a player on the decision made by other players. In the mathematical modeling, the dependency of decision choice by players has been expressed only based on the individual benefit of the players and no discussion has been made about player’s preferences of loss or profit of other players.
Now, we apply hyperrational choice theory as a basis and main element of modeling in game theory. With help of hyperrationality, we analyze conditions of a strategic game. In the concept of hyperrationality, the player thinks about profit or loss of other players in addition to his personal profit or loss and then will choose an action, which is desirable to him. In order to describe a game based on concept of hyperrational choice, the payoff functions for each player i is given by:
where \(U_i^j\) shows that if player i considers profit (loss) of player j, he will choose an action from a set of available actions, which will benefit (lose) player j, for every i,j∈{1,2,…,n}. In other words, based on player i’ preferences for player j, he thinks about profit or loss of player j in addition to his personal profit or loss and then will choose an action from a set of available actions, which is desirable to him. For more information, see the Prisoner’s Dilemma in Table 1.
In the theory of the game, different methods are used for finding equilibrium with help of rationality concept and one of these methods is the best response function (McCarty and Meirowitz, 2007; Bu et al., 2017). Based on the definition of the best response function, equilibrium is a point in which strategy chosen by each individual is the best response to the strategies chosen by other players and maximize personal profit (Harsanyi, 1986; Eshaghi and Askari, 2017; Xia et al., 2019; Huang et al., 2018a, 2018b).
Hyperrationality in game theory helps the player choose successful strategies of the game in interactive conditions and reproduce them. The concept of hyperrationality helps the game theory enter other fields of sciences with more logical power. We assume that each player in the game is hyperrational (for example twoplayer strategic 2 × 2 games with perfect information). Thus, a hyperrational player will renormalize her opinion based on the common knowledge that each player is hyperrational. Below, we show the best response functions based on hyperpreferences of players with B, P, and L. Precisely, we define the best response function B_{i} based on individual benefit by
any action in B_{i}(a_{−i}) is at least as good based on individual benefit for player i as every other action of player i when the other players’ actions are given by a_{−i}. We call B_{i} the best response function of player i based on individual benefit. Precisely, we define the best response function P_{i} based on profit for other players by
any action in P_{i}(a_{−i}) for player i relative to every other action of player i is at least the best based on profit for other players when the other players’ actions are given by a_{−i}. We call P_{i} the best response function of player i based on profit for other players. Precisely, we define the best response function L_{i} based on the loss of other players by
any action in L_{i}(a−_{i}) for player i relative to every other action of player i is at least as good based on the loss for other players when the other players’ actions are given by a_{−i}. We call L_{i} the best response function of player i based on the loss of other players. From relations (1), (2), and (3) we have,
In competitive interactions, we define strictly dominant action and weakly dominant action based on the loss of other players.
Definition 4. (Strict domination of loss) In a strategic game for player i, action a_{i}" is strictly dominant on her action a_{i}′ based on loss for player −i, if we have:
where u_{−i} is a payoff function that represents player −iʹ preferences. It is defined as strictly dominant action based on benefit for other players similar, but the difference is that direction of the relation < is changed.
Definition 5. (Weak domination of loss) In a strategic game for player i, action a_{i}" is weakly dominant on her action a_{i}′ based on loss for player −i, if we have:
and
where u_{−i} is a payoff function that represents player −i′ preferences. It is defined as weakly dominant action based on benefit for other players similar, but the difference is that direction of relations ≤ and < is changed.
The actions, which are chosen based on the concept of hyperrationality (hyperpreferences) and rationality of the players, may be similar or different. According to the concept of hyperrationality, we divide actions of players into three classes: (1) strictly dominant action and weakly dominant action based on individual profit; (2) strictly dominant action and weakly dominant action based on profit for other players; (3) strictly dominant action and weakly dominant action based on the loss for others. The following proposition shows a method for finding equilibrium in the game.
Proposition 6. The action profile a* is a equilibrium point of strategic game if and only if hold true in at least one of the following conditions:

Each action of the player is the best response to actions of other players based on personal benefit:
$$a^ \ast \,{\mathrm{is}}\,{\mathrm{in}}\,B_i\left( {a_{  i}^ \ast } \right)\,{\mathrm{for}}\,{\mathrm{every}}\,{\mathrm{player}}\,i$$ 
Each action of the player is the best response to actions of other players based on the benefit of other players:
$$a^ \ast \,{\mathrm{is}}\,{\mathrm{in}}\,P_i\left( {a_{  i}^ \ast } \right)\,{\mathrm{for}}\,{\mathrm{every}}\,{\mathrm{player}}\,i,$$ 
Each action of the player is the best response to actions of other players based on loss of other players:
We consider equilibrium based on concept of Nash (Nash, 1950, 1951). Based on the concept of hyperrationality, equilibria can be divided into three classes. The first class is the equilibria, which are considered based on personal benefit. The second class is the equilibria, which are selected based on profit or loss of other players. The third class is the equilibria, which are considered based on individual benefit and loss or profit of other players at the same time. An action profile may be selected, which is the equilibrium point of the game based on hyperpreference of the maximum loss for other players and also has the maximum loss for all players, but it is not Nash equilibrium based on the classic concept of rationality. In addition, based on this concept, games may have one (Second Best game), two (Prisoner’s Dilemma), three (Trickery game) and four (Chicken game) equilibrium or without an equilibrium. For example, the Matching pennies is not in equilibrium and Missile crisis game has two equilibria. Hyperrationality helps the analyst to interpret every cell of the game table and have more accurate analysis.
Behavior of individuals in human societies
In a social dilemma game, there are different behavioral options, for cooperation and competition (Hertel and Fiedler, 1994; Huang et al., 2018a, 2018b; Li et al., 2018a, 2018b). There are several studies, which provide the main theoretical insights of the general psychological game framework (Geanakoplos et al., 1989; Attanasi and Rosemarie Nagel, 2008; Li et al., 2016). The classical theory of game relies on assumptions of perfect rationality and full common knowledge that are far removed from the cognitive capacities of human players and of limited use in explaining human strategic behavior. On the other hand, blind experimentation is also unhelpful, because the proper use of experiments is to test hypotheses, and without good hypotheses, no useful progress can be made (Colman and Pulford, 2015). Interactions between psychologists and economists have been marked more by conflict than by collaboration and the absence of a common research language impedes communication between this the disciplines (Manski, 2017). Some of the studies describe the relationship between psychologists and economists (Croson and Miller, 2004; Attanasi and Rosemarie Nagel, 2008; Schotter and Trevin, 2014; De Bruin and Fischhoff, 2017; Xia et al., 2018). In this section, we review and interpret Prisoner’s Dilemma with the help of the concept of hyperrationality.
Prisoner’s Dilemma
The prisoner’s dilemma (PD) game can be used as a model for many real world situations involving cooperative behavior. The players in PD have two options. They must either cooperate or defect. In the simultaneous PD all players make their decisions or moves at once. Mathematical models have further established the prisoner’s dilemma as foundational lore in fields as diverse as economics, political science, environmental studies, psychology, and evolutionary biology. Advertising is sometimes cited as a realexample of the prisoner’s dilemma (Moorthy, 1985). In environmental studies, the PD is evident in crises such as global climatechange (Osang and Nandy, 2013). Cooperative behavior of many animals can be modeled as iterated the prisoner’s dilemma. Interest in the iterated prisoner’s dilemma (IPD) was kindled by Robert Axelrod (1984) in his book The Evolution of Cooperation. The essence of cooperation is described by the Prisoner’s Dilemma (Dreber et al., 2008). Cooperation is a hallmark of human society (Trivers, 1971; Hamilton and Axelrod, 1981; Rockenbach and Milinski, 2006; Nowak, 2006; Rand et al., 2009, 2011, 2012, 2014; Li and Daniels, 2015). In theory of games, there has been much interest in exploring the Prisoner’s Dilemma.
Here, we claim that based on the hyperrationality concept each player in the Prisoner’s Dilemma is hyperrational. In Table 1 based on definitions of hyperrationality we have;
1. Each player is thinking of making a profit to another player
In game G, for player 1 we have: based on concept of hyperrationality, given fixed C for player 2, we can see that if player 1, seeks to incur profit to his opponent, he will choose C (player 2, earns a reward 4), it can conclude that pair of action (C,C) is chosen. By choosing D for player 2, we can see that if player 1, seeks to incur profit to his opponent, he will choose C (player 2, earns a reward 4), it can conclude that pair of action (C,D) is chosen. Therefore, for the player 1, based on the profit of another player, C is a strictly dominant action.
In game G, for player 2 we have: based on concept of hyperrationality, given fixed C for player 1, we can see that if player 2, seeks to incur profit to his opponent, he will choose C (player 1, earns a reward 4), it can conclude that pair of action (C,C) is chosen. By choosing D for player 1, we can see that if player 2, seeks to incur profit to his opponent, he will choose C (player 1, earns a reward 4), it can conclude that pair of action (D,C) is chosen. So, for the player 2, based on the profit of another player, C is a strictly dominant action.
2. Player 1 is looking to profit for player 2 and player 2 seeks to lose of player 1
In game G, for player 1 we have: based on concept of hyperrationality, given fixed C for player 2, we can see that if player 1, seeks to incur profit to his opponent, he will choose C (player 2, earns a reward 4), it can conclude that pair of action (C,C) is chosen. By choosing D for player 2, we can see that if player 1, seeks to incur profit to his opponent, he will choose C (player 2, earns a reward 4), it can conclude that pair of action (C,D) is chosen. Therefore, for the player 1, based on the profit of another player, C is a strictly dominant action.
In game G, for player 2 we have: based on concept of hyperrationality, given fixed C for player 1, we can see that if player 2, seeks to incur loss to his opponent, he will choose D (player 1, earns a reward 1), it can conclude that pair of action (C,D) is chosen. By choosing D for player 1, we can see that if player 2, seeks to incur loss to his opponent, he will choose D (player 1, earns a reward 2), it can conclude that pair of action (D,D) is chosen. So, for players 2, based on the loss of another player, D is a strictly dominant action.
3. Each player is thinking of making a loss to another player
In game G, for player 1 we have: based on concept of hyperrationality, given fixed C for player 2, we can see that if player 1, seeks to incur loss to his opponent, he will choose D (player 2, earns a reward 1), it can conclude that pair of action (D,C) is chosen. By choosing D for player 2, we can see that if player 1, seeks to incur loss to his opponent, he will choose D (player 2, earns a reward 2), it can conclude that pair of action (D,D) is chosen. Therefore, for the player 1, based on the loss of another player, D is a strictly dominant action.
In game G, for player 2 we have: based on concept of hyperrationality, given fixed C for player 1, we can see that if player 2, seeks to incur loss to his opponent, he will choose D (player 1, earns a reward 1), it can conclude that pair of action (C,D) is chosen. By choosing D for player 1, we can see that if player 2, seeks to incur loss to his opponent, he will choose D (player 1, earns a reward 2), it can conclude that pair of action (D,D) is chosen. So, for players 2, based on the loss of another player, D is a strictly dominant action.
4. Player 1 is looking to loss to player 2 and player 2 seeks to profit for player 1
In game G, for player 1 we have: based on concept of hyperrationality, given fixed C for player 2, we can see that if player 1, seeks to incur loss to his opponent, he will choose D (player 2, earns a reward 1), it can conclude that pair of action (D,C) is chosen. By choosing D for player 2, we can see that if player 1, seeks to incur loss to his opponent, he will choose D (player 2, earns a reward 2), it can conclude that pair of action (D,D) is chosen. Therefore, for the player 1, based on the loss of another player, D is a strictly dominant action.
In game G, for player 2 we have: based on concept of hyperrationality, given fixed C for player 1, we can see that if player 2, seeks to incur profit to his opponent, he will choose C (player 1, earns a reward 4), it can conclude that pair of action (C,C) is chosen. By choosing D for player 1, we can see that if player 2, seeks to incur profit to his opponent, he will choose C (player 1, earns a reward 4), it can conclude that pair of action (D,C) is chosen. So, for the player 2, based on the profit of another player, C is a strictly dominant action.
Therefore, in Prisoner’s Dilemma G for both players based on loss of other players, defect D is a strictly dominant action of loss and cooperate C is a strictly dominated action of loss. In this game, equilibrium point (D,D) is an equilibrium, which the players selected based on loss of the opponent. For both players, based on the benefit of other players, cooperate is a strictly dominant action of profit and defect is a strictly dominated action for profit. So, equilibrium point (C,C) is an equilibrium, which the players selected based on the benefit of the opponent. Therefore, based on the hyperrationality concept, prisoner’s dilemma has two equilibria (C,C) and (D,D). Hofstadter claims that for the superrational it is evident that universal cooperation is the best option (Poston, 2012; Hofstadter, 2008). We state that either cooperation or defection is the best option for the hyperrational player depending on environmental conditions (competitive, peace, war,…) and the type of behavioral interaction (friend, enemy,…) in game. One can almost be claimed that the cooperation and the defection are two hyperrational options. On the other hand, when players cannot guarantee their profit, they can optimize the situation by defection. As a result, cooperation is not always the best option.
Cooperation leads to a tension between what is best for the individual and what is best for the group (Dreber et al., 2008). How can the cooperation be promoted in the repeated prisoner’s dilemma? In some experimental papers to promote cooperation from complicated laboratory conditions or add strategy to the Prisoner’s Dilemma is used (Sigmund et al., 2008; Fehr and Gachter, 2002; Ohtsuki et al., 2009; Traulsen and Nowak, 2006; Mathew and Boyd, 2011; Gallo and Yan, 2015; Jordan et al., 2016; Bear and Rand, 2016; Li et al., 2018a, 2018b). We want to answer the above question using the concept of hyperrationality. In classical game theory, all the variety of 2 × 2 symmetric games rests in the relative values of the four payoffs (C,C), (D,D), (D,C), and (C,D). There are 24 possible rankings of four payoffs, and thus 24 symmetric 2 × 2 games (Poundstone, 1993). In Prisoner’s Dilemma based on classical rationality, row player prefers (D,C) to (C,C) to (D,D) to (C,D) ((D,C) ≽ (C,C) ≽ (D,D) ≽ (C,D)). The hyperrationality of player thinks about profit or loss of other players in addition to his personal profit or loss and then will choose an action, which is desirable to him. As mentioned above, taxonomy of player’s hyperpreferences depends on environmental condition, the type of behavioral interaction, selfevaluation system and evaluation system of other interacting persons. Taxonomy of player’s hyperpreferences has four main behavioral options: individual profit, individual loss, profit for others, and loss for others. Hence, in Prisoner’s Dilemma row player take taxonomy of hyperpreferences considering four main behavioral options: based on individual profit: (D,C) ≽′ (C,C) ≽′ (D,D) ≽′ (C,D), based on individual loss: (C,D) ≽′ (D,D) ≽′ (C,C) ≽′ (D,C), based on profit for others: (C,D) ≽′ (C,C) ≽′ (D,D) ≽′ (D,C), based on loss for others: (D,C) ≽′ (D,D) ≽′ (C,C) ≽′ (C,D).
Hyperpreferences taxonomy helps that players consider simultaneously two main behavioral options such as collective profit or collective loss (Eshaghi Gordji et al. 2018). If interaction between players is based on collective benefit thinking, both player prefers: either (C,C) ≽′ (D,D) ≽′ (D,C) ≽′ (C,D) or (C,C) ≽′ (D,D) ≽′ (C,D) ≽′ (D,C). On the other hand, the concept of hyperrationality explains that, based on the profit of other players, cooperation is a strictly dominant action. Taxonomy of hyperpreferences helps to players consider two principles simultaneously in interactions: first, treat others as we ourselves would like to be treated and second, not treat others as we ourselves would not like to be treated. According to the second principle, the profiles strategy (C,D) and (D,C) is not selected. Based on collective benefit thinking (C,C) is preferred to (D,D) by two players. So, according to the first principle, the profiles strategy (C,C) is selected. If the Prisoner’s Dilemma is repeated, the taxonomy of two principles are likely to lead to this mechanism for the promotion of cooperation. Hence, this study with the help of the concept of hyperrationality in game theory, seeks to the promotion of cooperation between the players, which is a sign of the power of this concept. Therefore, the concept of hyperrationality helps to understand the evolution of cooperation.
There are two competing classes of theories that investigate the relationship between actions and beliefs. The first class of theories, coming from economics, suggests that beliefs cause actions. The second class of theories, proposed by psychologist, suggest that actions cause beliefs (Croson and Miller, 2004; Attanasi and Rosemarie Nagel, 2008). Interactions between psychologists and economists have been marked more by conflict than by collaboration (Manski, 2017). Bruine de Bruin and Fischhoff describe four conditions that promoted transdisciplinary collaborations between psychologists and economists (De Bruin and Fischhoff, 2017). We explore the players’ behavior with the help of the concept of hyperrationality. This concept explains that, based on the loss of other players, defection is a strictly dominant action. If interaction between players is based on collective loss thinking, both player prefers: either (D,D) ≽′ (C,C) ≽′ (D,C) ≽′ (C,D), or (D,D) ≽′ (C,C) ≽′ (C,D) ≽′ (D,C). These interpretations help to enlarge our understanding of psychological aspects of strategy choices in games and also provide an analysis of the decisionmaking process with cognitive economics approach at the same time. For example, based on collective thinking and two principles mentioned above if players have hostile thoughts that only cause loss to another player then they prefer (D, D) to (C, C). In other words, the hyperpreferences indicate that the type of behavioral interaction, environmental conditions, and valuation system are based on hostility and players at this point have considered the maximum loss to other, which this is a common research language between psychologists and economists.
Computational complexity
In general, the hyperrationality concept can be used as a compatible model for many real world situations. The individual’s choice among his preferences: (i) individual preferences, to maximize his benefit or minimize his loss; (ii) preference for others, to maximize profit or loss of other players, and (iii) both of them at the same time, makes his hyperpreferences. The computational complexity of our method depends on the number of players and actions and these three steps. In other words, the more the number of players and actions, the higher the computational complexity. Obviously, part (iii) is of the highest complexity, while the complexity of the other two parts is rather low. Our method is very easy to implement and suitable for a lot of largescale real networks.
Conclusion
The theory of rational choice seeks to explain the behavior of the person who behaves wisely and look for to maximize his benefits. The theory of hyperrational choice seeks to explain the behavior of the person who behaves wisely and considers benefit or loss of others in addition to the individual benefit. The theory of hyperrational choice can be applied instead of the theory of rational choice in social sciences and society can be analyzed based on two methodological individualistic and methodological collective approaches so that human society can be understood easily and predicted more fluently. In this theory, the hyperrational actor thinks about the benefit (collective benefit) and loss (collective loss) of other actors beside his own benefit and then chooses an action. Based on this concept, we call a person hyperrational if results of choosing any action are comparable with other actions for the person and also the person can recognize what action is the most beneficial to him among the accessible actions and what action causes loss or benefit of other players. According to the concept of hyperrationality, a player may not recognize that what action is the most beneficial to him but can choose an action, which causes the maximum loss or benefit for other players. Based on this concept, assumption about profit or loss to other actors can be added in the form of human behaviors such as altruism, devotion, fraud, jealousy, and mistrust to the concept of rationality. This new concept can describe some of the human behaviors well.
Moreover, we presented new definitions such as the best response functions, strictly dominant action and weakly dominant action based on loss of other players. With the help of these definitions, we have introduced a method for finding equilibrium in the game and classified the equilibria. In some of these games, we achieved equilibria, which are not considered as game equilibrium based on the classic concept of rationality. The theory of hyperrational choice can be applied as a basis for the theory of decisionmaking, the theory of collective action and social sciences issues and new results can be obtained in this way. Hyperrationality can be mentioned and investigated as uncertainty. We also believe that our current design has some additional advantages over previous ones. The hyperpreferences indicate that if the type of behavioral interaction, environmental conditions, and valuation system are based on hostility, then players have considered the maximum loss to other, which can be a common research language between psychologists and economists.
Data availability
Data sharing is not applicable to this paper as no datasets were analysed or generated.
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This research is supported by Iran National Science Foundation (No. 96002125).
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Askari, G., Gordji, M.E. & Park, C. The behavioral model and game theory. Palgrave Commun 5, 57 (2019). https://doi.org/10.1057/s4159901902652
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