Price of fairness

In the theory of fair division, the price of fairness (POF) is the ratio of the largest economic welfare attainable by a division to the economic welfare attained by a fair division. The POF is a quantitative measure of the loss of welfare that society has to take in order to guarantee fairness.

In general, the POF is defined by the following formula:

The exact price varies greatly based on the kind of division, the kind of fairness and the kind of social welfare we are interested in.

The most well-studied type of social welfare is utilitarian social welfare, defined as the sum of the (normalized) utilities of all agents. Another type is egalitarian social welfare, defined as the minimum (normalized) utility per agent.

Numeric example

In this example we focus on the utilitiarian price of proportionality, or UPOP.

Consider a heterogeneous land-estate that has to be divided among 100 partners, all of whom value it as 100 (or the value is normalized to 100). First, let's look at some extreme cases.

Upper bound

The extreme cases described above already give us a trivial upper bound: UPOP ≤ 10000/100 = 100. But we can get a tighter upper bound.

Assume that we have an efficient division of a land-estate to 100 partners, with a utilitarian welfare U. We want to convert it to a proportional division. To do this, we group the partners according to their current value:

There are two cases:

To summarize: the UPOP is always less than 20, regardless of the value measures of the partners.

Lower bound

The UPOP can be as low as 1. For example, if all partners have the same value measure, then in any division, regardless of fairness, the utilitarian welfare is 100. Hence, UPOP=100/100=1.

However, we are interested on a worst-case UPOP, i.e., an combination of value measures in which the UPOP is large. Here is such an example.

Assume there are two types of partners:

Consider the two following partitions:

In this example, the UPOP is 1000/190=5.26. Thus 5.26 is a lower bound on the worst-case UPOP (where the "worst-case" is taken over all possible combinations of value measures).

Combined

Combining all the results, we get that the worst-case UPOP is bounded between 5 and 20.

This example is typical of the arguments used to bound the POF. To prove a lower bound, it is sufficient to describe a single example; to prove an upper bound, an algorithm or another sophisticated argument should be presented.

Cake-cutting with general pieces

Utilitarian price of proportionality

The numeric example described above can be generalized from 100 to n partners, giving the following bounds for the worst-case UPOP:

n/2 ≤ UPOP ≤ 2√n-1
UPOP = Θ(√n)

For two partners, a more detailed calculation gives a bound of: 8-4*√3 ≅ 1.07.[1]

Utilitarian price of envy

When the entire cake is divided, an envy-free division is always proportional. Hence the lower bound on the worst-case UPOP (√n/2) applies here too. On the other hand, as an upper bound we only have a weak bound of n-1/2.[1] Hence:

n/2 ≤ UPOV ≤ n-1/2
Ω(√n) ≤ UPOV ≤ O(n)

For two partners, a more detailed calculation gives a bound of: 8-4*√3 ≅ 1.07.[1]

Utilitarian price of equitability

For two partners, a more detailed calculation gives a bound of: 9/8=1.125.[1]

Indivisible item assignment

A brief summary of the results:[1]

UPOP = n - 1 + 1/n; for two people: 3/2.
(3n+7)/9-O(1/n) ≤ UPOV ≤ n-1/2; for two people: 3/2
UPOQ=Infinity; for two people: 2

Divisible chore division

For the problem of cake-cutting when the "cake" is undesirable (e.g. lawn-mowing), we have the following results:[1]

(n+1)^2/4n ≤ UPOP ≤ n; for two people: 9/8
(n+1)^2/4n ≤ UPOV ≤ infinity; for two people: 9/8
UPOQ=n

Indivisible chore assignment

UPOP = n
UPOV = infinity
UPOQ = infinity

Cake-cutting with connected pieces

The problem of fair cake-cutting has a variation in which the pieces must be connected. In this variation, both the nominator and the denominator in the POF formula are smaller (since the maximum is taken over a smaller set), so apriori it is not clear whether the POF should be smaller or larger than in the disconnected case.

Utilitarian price of fairness

We have the following results for utilitarian welfare:[2]

UPOP = Θ(√n)
UPOV = Θ(√n)
n-1+1/n ≤ EPOQ ≤ n
EPOQ = Θ(n)

Egalitarian price of fairness

In a proportional division, the value of each partner is at least 1/n of the total. In particular, the value of the least fortunate agent (which is called the egalitarian welfare of the division) is at least 1/n. This means that in an egalitarian-optimal division, the egalitarian welfare is at least 1/n, and so an egalitarian-optimal division is always proportional. Hence, the egalitarian price of proportionality (EPOP) is 1:

EPOP = 1

Similar considerations apply to the egalitarian price of equitability (EPOQ):

EPOQ = 1

The egalitarian price of envy-freeness is much larger:[2]

EPOV = n/2

This is an interesting result, as it implies that insistence on the criterion of envy-freeness increases the social gaps and harms the most unfortunate citizens. The criterion of proportionality is much less harmful.

Price of welfare-maximization

Instead of calculating the loss of welfare due to fairness, we can calculate the loss of fairness due to welfare optimization. We get the following results:[2]

proportional-price-of-egalitarianism = 1
envy-price-of-egalitarianism = n-1
proportional-price-of-utilitarianism = infinity
envy-price-of-egalitarianism = infinity

Other results

The price of fairness has also been studied in the contest of resource allocation.[3][4]

When the value measures are non-additive, Mirchandani[5] shows that the prices of envy-freeness and equitability are both unbounded.

See also

References

  1. 1 2 3 4 5 6 Caragiannis, I.; Kaklamanis, C.; Kanellopoulos, P.; Kyropoulou, M. (2011). "The Efficiency of Fair Division". Theory of Computing Systems. 50 (4): 589. doi:10.1007/s00224-011-9359-y.
  2. 1 2 3 Aumann, Y.; Dombb, Y. (2010). "The Efficiency of Fair Division with Connected Pieces". Internet and Network Economics. Lecture Notes in Computer Science. 6484. p. 26. doi:10.1007/978-3-642-17572-5_3. ISBN 978-3-642-17571-8.
  3. Bertsimas, D.; Farias, V. F.; Trichakis, N. (2011). "The Price of Fairness". Operations Research. 59: 17. doi:10.1287/opre.1100.0865.
  4. Bertsimas, D.; Farias, V. F.; Trichakis, N. (2012). "On the Efficiency-Fairness Trade-off". Management Science. 58 (12): 2234. doi:10.1287/mnsc.1120.1549.
  5. Mirchandani, R. S. (2013). "Superadditivity and Subadditivity in Fair Division". Journal of Mathematics Research. 5 (3). doi:10.5539/jmr.v5n3p78.
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