Fair Cake-Cutting in Practice

Kyropoulou, Maria; Ortega, Josué; Segal-Halevi, Erel

doi:10.2139/ssrn.3269482

Cited by 3 publications

(9 citation statements)

References 45 publications

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“…between fairness and efficiency [24,26,31]. Some experiments check whether participants choose to play strategically, and how their manipulations affect the fairness of the final outcome [21,32,35,42].…”

Section: Laboratory Experimentsmentioning

confidence: 99%

“…In lab experiments, due to practical reasons, the division instances are small (e.g. [35] report a cake-cutting experiment with at most 4 participants per instance). In contrast, in our simulation experiments we could compare division procedures on much larger instances.…”

Section: Laboratory Experimentsmentioning

confidence: 99%

“…It is known that most existing cake-cutting algorithms are not strategyproof, which means that agents may gain by strategically reporting false preferences [11,40]. In theory, the gain from such manipulation can be very high: there are instances in which a truthful agent receives only 1/n of the total value, while a strategic agent receives 100% of the value [35]. However, such instances are highly artificial.…”

Section: Strategic Gainmentioning

confidence: 99%

“…On one hand, a worst-case analysis would require us to assume that the strategic agent knows the value functions of all other agents, and uses a globally-optimal strategy. On the other hand, recent evidence from a laboratory experiment [35] shows that humans are far from optimal in manipulating cake-cutting algorithms. Even in simple algorithms like cut-and-choose on a 1-dimensional cake, they often make obvious mistakes such as cutting the cake to the right of their actual half-point when they know that their partner will choose the leftmost piece.…”

Section: Strategic Gainmentioning

confidence: 99%

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Fair cake-cutting algorithms with real land-value data

Shtechman

Gonen

Segal-Halevi

2021

Auton Agent Multi-Agent Syst

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Fair division of land is an important practical problem that is commonly handled either by hiring assessors or by selling and dividing the proceeds. A third way to divide land fairly is via algorithms for fair cake-cutting. Such un-intermediated methods are not only cheaper than an assessor but also theoretically fairer since they guarantee each agent a fair share according to his/her value function. However, the current theory of fair cake-cutting is not yet ready to optimally share a plot of land, and such algorithms are seldom used in practical land division. We attempt to narrow the gap between theory and practice by presenting several heuristic adaptations of famous algorithms for one-dimensional cake-cutting to two-dimensional land-division. The heuristics are evaluated using extensive simulations on real land-value data maps from three different data sets and a fourth (control) map of random values. The simulations compare the performance of cake-cutting algorithms to sale and assessor division in various performance metrics, such as utilitarian welfare, egalitarian welfare, Nash social welfare, envy, and geometric shape. The cake-cutting algorithms perform better in most metrics. However, their performance is greatly influenced by technical implementation details and heuristics that are often overlooked by theorists. We also propose a new protocol for practical cake-cutting using a dynamic programming approach and discuss its run-time complexity versus performance trade-off. Our new protocol performs better than the examined classic cake-cutting algorithms on most metrics. Experiments to assess the amount that a strategic agent can gain from reporting false preferences are also presented. The results show that the problem of strategic manipulation is much less severe than the worst-case predicted by theory.

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Section: Laboratory Experimentsmentioning

confidence: 99%

Section: Laboratory Experimentsmentioning

confidence: 99%

Section: Strategic Gainmentioning

confidence: 99%

Section: Strategic Gainmentioning

confidence: 99%

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Fair cake-cutting algorithms with real land-value data

Shtechman

Gonen

Segal-Halevi

2021

Auton Agent Multi-Agent Syst

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“…Agent 2 is assigned the interval (c ′ll 1 , c ′ll 2 ] and so on, until the last agent who receives the interval (c ′ll n−1 , 1]. Leftmost leaves generates a Pareto optimal allocation, guaranteeing all agents at least a utility of 1/n (Kyropoulou et al, 2019;Ortega and Segal-Halevi, 2019), in contrast with the Wang-Wu mechanism which guarantees exactly a 1/n utility to all agents; thus leftmost leaves Pareto dominates the Wang-Wu mechanism. However, leftmost leaves can generate envy.…”

Section: Three Different Mechanisms That Improve On Wang-wumentioning

confidence: 99%

Fairness and efficiency in cake-cutting with single-peaked preferences

2020

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We study the cake-cutting problem where agents have single-peaked preferences over the cake. We show that a recently proposed mechanism by Wang and Wu (2019) to obtain envy-free allocations can yield large welfare losses. Using a simplifying assumption, we characterize all Pareto optimal allocations, which have a simple structure: are peak-preserving and non-wasteful. Finally, we provide simple alternative mechanisms that Pareto dominate that of Wang-Wu and achieve envy-freeness or Pareto optimality.

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Obvious Manipulations in Cake-Cutting

Ortega

Segal-Halevi

2019

SSRN Journal

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In cake-cutting, strategy-proofness is a very costly requirement in terms of fairness: for n = 2 it implies a dictatorial allocation, whereas for n ≥ 3 it requires that one agent receives no cake. We show that a weaker version of this property recently suggested by Troyan and Morril, called not-obvious manipulability, is compatible with the strong fairness property of proportionality, which guarantees that each agent receives 1/n of the cake. Both properties are satisfied by the leftmost leaves mechanism, an adaptation of the Dubins -Spanier moving knife procedure. Most other classical proportional mechanisms in literature are obviously manipulable, including the original moving knife mechanism. Not-obvious manipulability explains why leftmost leaves is manipulated less often in practice than other proportional mechanisms.

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Fair Cake-Cutting in Practice

Cited by 3 publications

References 45 publications

Fair cake-cutting algorithms with real land-value data

Fair cake-cutting algorithms with real land-value data

Fairness and efficiency in cake-cutting with single-peaked preferences

Obvious Manipulations in Cake-Cutting

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