Precommitment and the macroeconomic policy game

Cubitt, Robin P.

January 1989

No description available.

330

Game theory

Computational complexity, bounded rationality and the theory of games

Smith, Justin N.

January 2000

No description available.

519.5

Game; Memory; Algorithms

The politics and micropolitics of secondary school reorganisation : context, games and outcomes

Welsh, Paul John

January 1997

No description available.

370

Reorganisation; Game theory

Price formation within the UK electricity industry and the application of auction theory

Turner, Peter Robert

January 2003

No description available.

338

Game theory

The ontogeny of anti-predator behaviour in game bird chicks

Dowell, Simon Derek

January 1990

No description available.

590

Game bird rearing

The evolution of biological signals

Johnstone, Rufus A.

January 1993

No description available.

519.5

Game theory

The cardiac stress of badminton participation

Huntington, George Edward

03 June 2011

There is no abstract available for this thesis.

Stress (Physiology)

Badminton (Game)

AI in computer games : generating interesting interactive opponents by the use of evolutionary computation

Yannakakis, Georgios N.

January 2005

Which features of a computer game contribute to the player’s enjoyment of it? How can we automatically generate interesting and satisfying playing experiences for a given game? These are the two key questions addressed in this dissertation. Player satisfaction in computer games depends on a variety of factors; here the focus is on the contribution of the behaviour and strategy of game opponents in predator/prey games. A quantitative metric of the ‘interestingness’ of opponent behaviours is defined based on qualitative considerations of what is enjoyable in such games, and a mathematical formulation grounded in observable data is derived. Using this metric, neural-network opponent controllers are evolved for dynamic game environments where limited inter-agent communication is used to drive spatial coordination of opponent teams. Given the complexity of the predator task, cooperative team behaviours are investigated. Initial candidates are generated using off-line learning procedures operating on minimal neural controllers with the aim of maximising opponent performance. These example controllers are then adapted using on-line (i.e. during play) learning techniques to yield opponents that provide games of high interest. The on-line learning methodology is evaluated using two dissimilar predator/prey games with a number of different computer player strategies. It exhibits generality across the two game test-beds and robustness to changes of player, initial opponent controller selected, and complexity of the game field. The interest metric is also evaluated by comparison with human judgement of game satisfaction in an experimental survey. A statistically significant number of players were asked to rank game experiences with a test-bed game using perceived interestingness and their ranking was compared with that of the proposed interest metric. The results show that the interest metric is consistent with human judgement of game satisfaction. Finally, the generality, limitations and potential of the proposed methodology and techniques are discussed, and other factors affecting the player’s satisfaction, such as the player’s own strategy, are briefly considered. Future directions building on the work described herein are presented and discussed.

006.3

AI ; computer game

Classical and parameterized complexity of cliques and games

Scott, Allan Edward Jolicoeur

10 April 2008

No description available.

Game theory

Algorithms

A game-theoretic model for repeated helicopter allocation between two squads

McGowan, Jason M.

06 1900

A platoon commander has a helicopter to support two squads, which encounter two types of missions -- critical or routine --on a daily basis. During a mission, a squad always benefits from having the helicopter, but the benefit is greater during a critical mission than during a routine mission. Because the commander cannot verify the mission type beforehand, a selfish squad would always claim a critical mission to compete for the helicopterâ which leaves the commander no choice but to assign the helicopter at random. In order to encourage truthful reports from the squads, we design a token system that works as follows. Each squad keeps a token bank, with tokens deposited at a certain frequency. A squad must spend either 1 or 2 tokens to request the helicopter, while the commander assigns the helicopter to the squad who spends more tokens, or breaks a tie at random. The two selfish squads become players in a two-person non-zero-sum game. We find the Nash Equilibrium of this game, and use numerical examples to illustrate the benefit of the token system. / US Navy (USN) author.

Game theory

Markov processes