Leximin order

Not to be confused with Lexis minima.

In mathematics, leximin order is a total preorder on finite-dimensional vectors. A more accurate, but less common term is leximin preorder. The leximin order is particularly important in social choice theory and fair division.^[1][2][3]

Definition

A vector x = (x₁, ..., x_n) is leximin-larger than a vector y = (y₁, ..., y_n) if one of the following holds:

• The smallest element of x is larger than the smallest element of y;
• The smallest elements of both vectors are equal, and the second-smallest element of x is larger than the second-smallest element of y;
• ...
• The k smallest elements of both vectors are equal, and the (k+1)-smallest element of x is larger than the (k+1)-smallest element of y.

Examples

The vector (3,5,3) is leximin-larger than (4,2,4), since the smallest element in the former is 3 and in the latter is 2. The vector (4,2,4) is leximin-larger than (5,3,2), since the smallest elements in both are 2, but the second-smallest element in the former is 4 and in the latter is 3.

Vectors with the same multiset of elements are equivalent w.r.t. the leximin preorder, since they have the same smallest element, the same second-smallest element, etc. For example, the vectors (4,2,4) and (2,4,4) are leximin-equivalent (but both are leximin-larger than (2,4,2)).

Related order relations

In the lexicographic order, the first comparison is between x₁ and y₁, regardless of whether they are smallest in their vectors. The second comparison is between x₂ and y₂, and so on.

For example, the vector (3,5,3) is lexicographically smaller than (4,2,4), since the first element in the former is 3 and in the latter it is 4. Similarly, (4,2,4) is lexicographically larger than (2,4,4).

The following algorithm can be used to compute whether x is leximin-larger than y:

• Let x' be a vector containing the same elements of x but in ascending order;
• Let y' be a vector containing the same elements of y but in ascending order;
• Return "true" iff x' is lexicographically-larger than y'.

The leximax order is similar to the leximin order except that the first comparison is between the largest elements; the second comparison is between the second-largest elements; and so on.

Applications

In social choice

In social choice theory,^[4] particularly in fair division,^[1] the leximin order is one of the orders used to choose between alternatives. In a typical social choice problem, society has to choose among several alternatives (for example: several ways to allocate a set of resources). Each alternative induces a utility profile - a vector in which element i is the utility of agent i in the allocation. An alternative is called leximin-optimal if its utility-profile is (weakly) leximin-larger than the utility profile of all other alternatives.

For example, suppose there are three alternatives: x gives a utility of 2 to Alice and 4 to George; y gives a utility of 9 to Alice and 1 to George; and z gives a utility of 1 to Alice and 8 to George. Then alternative x is leximin-optimal, since its utility profile is (2,4) which is leximin-larger than that of y (9,1) and z (1,8). The leximin-optimal solution is always Pareto-efficient.

The leximin rule selects, from among all possible allocations, the leximin-optimal ones. It is often called the egalitarian rule; see that page for more information on its computation and applications. For particular applications of the leximin rule in fair division, see:

• Leximin cake-cutting
• Leximin item allocation

In multicriteria decision

In Multiple-criteria decision analysis a decision has to be made, and there are several criteria on which the decision should be based (for example: cost, quality, speed, etc.). One way to decide is to assign, to each alternative, a vector of numbers representing its value in each of the criteria, and chooses the alternative whose vector is leximin-optimal.^[5]

The leximin-order is also used for Multi-objective optimization,^[6] for example, in optimal resource allocation,^[7] location problems,^[8] and matrix games.^[9]

It is also studied in the context of fuzzy constraint solving problems.^[10][11]

In flow networks

The leximin order can be used as a rule for solving network flow problems. Given a flow network, a source s, a sink t, and a specified subset E of edges, a flow is called leximin-optimal (or decreasingly minimal) on E if it minimizes the largest flow on an edge of E, subject to this minimizes the second-largest flow, and so on. There is a polynomial-time algorithm for computing a cheapest leximin-optimal integer-valued flow of a given flow amount. It is a possible way to define a fair flow.^[12]

In game theory

Main article: Nucleolus (game theory)

One kind of a solution to a cooperative game is the payoff-vector that minimizes the leximin vector of excess-values of coalitions, among all payoff-vectors that are efficient and individually-rational. This solution is called the nucleolus.

Representation

A representation of an ordering on a set of vectors is a function f that assigns a single number to each vector, such that the ordering between the numbers is identical to the ordering between the vectors. That is, f(x) ≥ f(y) iff x is larger than y by that ordering. When the number of possible vectors is countable (e.g. when all vectors are integral and bounded), the leximin order can be represented by various functions, for example:

• ${\displaystyle f(\mathbf {x} )=-\sum _{i=1}^{n}n^{-x_{i}}}$ ; ^[13]
• ${\displaystyle f(\mathbf {x} )=-\sum _{i=1}^{n}x_{i}^{-q}}$ , where q is a sufficiently large constant;^[14]
• ${\displaystyle f(\mathbf {x} )=\sum _{i=1}^{n}w_{i}\cdot (x^{\uparrow })_{i}}$ , where ${\displaystyle \mathbf {x^{\uparrow }} }$  is vector x sorted in ascending order, and ${\displaystyle w_{1}\gg w_{2}\gg \cdots \gg w_{n}}$ .^[15][16]

However, when the set of possible vectors is uncountable (e.g. real vectors), no function (whether contiuous or not) can represent the leximin order.^[14]: 34 The same is true for the lexicographic order.

See also

• Lexicographic max-min optimization is the computational problem of finding a maximal element of the leximin order in a given set.

References

1. Herve Moulin (2004). Fair Division and Collective Welfare. Cambridge, Massachusetts: MIT Press. ISBN 9780262134231.
2. Barbarà, Salvador; Jackson, Matthew (1988-10-01). "Maximin, leximin, and the protective criterion: Characterizations and comparisons". Journal of Economic Theory. 46 (1): 34–44. doi:10.1016/0022-0531(88)90148-2. ISSN 0022-0531.
3. Yager, Ronald R. (1997-10-01). "On the analytic representation of the Leximin ordering and its application to flexible constraint propagation". European Journal of Operational Research. 102 (1): 176–192. doi:10.1016/S0377-2217(96)00217-2. ISSN 0377-2217.
4. Sen, Amartya (2017-02-20). Collective Choice and Social Welfare. Harvard University Press. doi:10.4159/9780674974616. ISBN 978-0-674-97461-6.
5. Dubois, Didier; Fargier, Hélène; Prade, Henri (1997), Yager, Ronald R.; Kacprzyk, Janusz (eds.), "Beyond Min Aggregation in Multicriteria Decision: (Ordered) Weighted Min, Discri-Min, Leximin", The Ordered Weighted Averaging Operators: Theory and Applications, Boston, MA: Springer US, pp. 181–192, doi:10.1007/978-1-4615-6123-1_15, ISBN 978-1-4615-6123-1, retrieved 2021-06-11
6. Ehrgott, Matthias (2005-05-18). Multicriteria Optimization. Springer Science & Business Media. ISBN 978-3-540-21398-7.
7. Luss, Hanan (1999-06-01). "On Equitable Resource Allocation Problems: A Lexicographic Minimax Approach". Operations Research. 47 (3): 361–378. doi:10.1287/opre.47.3.361. ISSN 0030-364X.
8. Ogryczak, Włodzimierz (1997-08-01). "On the lexicographic minimax approach to location problems". European Journal of Operational Research. 100 (3): 566–585. doi:10.1016/S0377-2217(96)00154-3. ISSN 0377-2217.
9. Potters, Jos A. M.; Tijs, Stef H. (1992-02-01). "The Nucleolus of a Matrix Game and Other Nucleoli". Mathematics of Operations Research. 17 (1): 164–174. doi:10.1287/moor.17.1.164. hdl:2066/223732. ISSN 0364-765X. S2CID 40275405.
10. Dubois, Didier; Fortemps, Philippe (1999-10-01). "Computing improved optimal solutions to max–min flexible constraint satisfaction problems". European Journal of Operational Research. 118 (1): 95–126. doi:10.1016/S0377-2217(98)00307-5. ISSN 0377-2217.
11. Pires, J.M.; Prade, H. (1998-05-01). "Logical analysis of fuzzy constraint satisfaction problems". 1998 IEEE International Conference on Fuzzy Systems Proceedings. IEEE World Congress on Computational Intelligence (Cat. No.98CH36228) (PDF). Vol. 1. pp. 857–862 vol.1. doi:10.1109/FUZZY.1998.687603. ISBN 0-7803-4863-X. S2CID 123126673.
12. Frank, András; Murota, Kazuo (2020-09-18). "Fair integral network flows". Mathematics of Operations Research. 48 (3): 1393–1422. arXiv:1907.02673. doi:10.1287/moor.2022.1303. S2CID 246411731.
13. Frisch, Alan M.; Hnich, Brahim; Kiziltan, Zeynep; Miguel, Ian; Walsh, Toby (2009-02-01). "Filtering algorithms for the multiset ordering constraint". Artificial Intelligence. 173 (2): 299–328. arXiv:0903.0460. doi:10.1016/j.artint.2008.11.001. ISSN 0004-3702. S2CID 7869870.
14. Moulin, Herve (1991-07-26). Axioms of Cooperative Decision Making. Cambridge University Press. ISBN 978-0-521-42458-5.
15. Yager, R.R. (1988-01-01). "On ordered weighted averaging aggregation operators in multicriteria decisionmaking". IEEE Transactions on Systems, Man, and Cybernetics. 18 (1): 183–190. doi:10.1109/21.87068. ISSN 2168-2909.
16. Yager, Ronald R. (1997-10-01). "On the analytic representation of the Leximin ordering and its application to flexible constraint propagation". European Journal of Operational Research. 102 (1): 176–192. doi:10.1016/S0377-2217(96)00217-2. ISSN 0377-2217.