Introduction

In our previous exploration, we defined genuine agency through embeddedness, predictive modeling, and intentional biasing. Here, we illustrate these principles concretely using the Matching Pennies game, a classical binary decision scenario, and discuss how a Quantum-Branching Universe (QBU) perspective might deepen our understanding of agency.

The Matching Pennies Game

Matching Pennies is a simple yet profound example where two agents simultaneously choose heads or tails:

• One agent (the Matcher) wins if both pennies match.

• The other agent (the Mismatcher) wins if the pennies differ.

This game encapsulates fundamental decision-making dynamics relevant to agency.

Agency Illustrated through the Game

• Embeddedness: Agents continuously interact, dynamically adjusting their strategies to each other's moves.

• Predictive Modeling: Agents forecast opponents' choices using internal representations to guide their decisions.

• Intentional Biasing: Agents deliberately choose moves to skew outcomes toward their preferred states.

Building a Predictive Model

An agent constructs a predictive model through several steps:

1. Observation and Data Collection: Recording historical choices and outcomes.

2. Pattern Recognition: Identifying statistical trends or biases in opponent behavior.

3. Probabilistic Forecasting: Creating probability distributions for future opponent choices.

4. Simulation of Counterfactual Scenarios: Evaluating potential outcomes of each choice through mental simulations.

5. Decision-making and Adjustment: Selecting strategies that maximize expected outcomes and refining the model with new information.

Detailed Analysis of Strategies

• Optimal play typically involves mixed strategies, maintaining unpredictability to achieve equilibrium.

• Predictive modeling accuracy directly correlates with strategic advantage, highlighting internal modeling's critical role.

Implications of True Randomness

If the opponent's behavior is genuinely random:

• Predictive modeling provides no advantage, as no reliable patterns exist.

• Optimal strategy reverts to pure randomization, highlighting fundamental limits to agency.

Playing Against the Environment

When the opponent is the environment, behavior typically follows structured probabilistic rules rather than true randomness:

• Effective modeling becomes theoretically feasible.

• Agents can exploit predictable structures or consistent patterns in environmental interactions, gaining strategic advantage.

The Role of the Quantum-Branching Universe (QBU)

The QBU framework suggests a richer interpretive lens:

• Each decision represents a branching point, generating multiple potential futures.

• Agents navigate uncertainty by simulating outcomes across these branches.

• Agency thus involves not only predicting probable outcomes but actively shaping probabilities across multiple possible timelines.

Insights and Implications

This analysis demonstrates:

• Practical pathways for testing and observing agency principles.

• How minimal agency emerges from simple interactions, providing insights for broader theories.

• Implications for decision theory, quantum interpretations, and AI alignment.

This foundational example offers clarity and practical understanding, connecting abstract concepts of agency with tangible, testable scenarios.