Austin moving-knife procedures

Last updated March 16, 2023

The Austin moving-knife procedures are procedures for equitable division of a cake. They allocate each of n partners, a piece of the cake which this partner values as exactly $1/n$ of the cake. This is in contrast to proportional division procedures, which give each partner at least $1/n$ of the cake, but may give more to some of the partners.

When $n=2$ , the division generated by Austin's procedure is an exact division and it is also envy-free. Moreover, it is possible to divide the cake to any number k of pieces which both partners value as exactly 1/k. Hence, it is possible to divide the cake between the partners in any fraction (e.g. give 1/3 to Alice and 2/3 to George).

When $n>2$ , the division is neither exact nor envy-free, since each partner only values his own piece as $1/n$ , but may value other pieces differently.

The main mathematical tool used by Austin's procedure is the intermediate value theorem (IVT).^[1]^[2]^[3]^: 66

Two partners and half-cakes

The basic procedures involve $n=2$ partners who want to divide a cake such that each of them gets exactly one half.

Two knives procedure

For the sake of description, call the two players Alice and George, and assume the cake is rectangular.

Alice places one knife on the left of the cake and a second parallel to it on the right where she judges it splits the cake in two.
Alice moves both knives to the right in a way that the part between the two knives always contains half of the cake's value in her eyes (while the physical distance between the knives may change).
George says "stop!" when he thinks that half the cake is between the knives. How can we be sure that George can say "stop" at some point? Because if Alice reaches the end, she must have her left knife positioned where the right knife started. The IVT establishes that George must be satisfied the cake is halved at some point.
A coin is tossed to select between two options: either George receives the piece between the knives and Alice receives the two pieces at the flanks, or vice versa. If partners are truthful, then they agree that the piece between the knives has a value of exactly 1/2, and so the division is exact.

One knife procedure

A single knife can be used to achieve the same effect.

Alice rotates the knife over the cake through 180° keeping a half on either side.
George says "stop!" when he agrees.

Alice must of course end the turn with the knife on the same line as where it started. Again, by the IVT, there must be a point in which George feels that the two halves are equal.

Two partners and general fractions

As noted by Austin, the two partners can find a single piece of cake that both of them value as exactly $1/k$ , for any integer $k\geq 2$ .^[2] Call the above procedure $\mathrm {Cut} _{2}(1/k)$ :

Alice makes $k-1$ parallel marks on the cake such that $k$ pieces so determined have a value of exactly $1/k$ .
If there is a piece that George also values as $1/k$ , then we are done.
Otherwise, there must be a piece that George values as less than $1/k$ , and an adjacent piece that George values as more than $1/k$ .
Let Alice place two knives on the two marks of one of these pieces, and move them in parallel, keeping the value between them at exactly $1/k$ , until they meet the marks of the other piece. By the IVT, there must be a point at which George agrees that the value between the knives is exactly $1/k$ .

By recursively applying $\mathrm {Cut} _{2}$ , the two partners can divide the entire cake to $k$ pieces, each of which is worth exactly $1/k$ for both of them:^[2]

Use $\mathrm {Cut} _{2}(1/k)$ to cut a piece which is worth exactly $1/k$ for both partners.
Now the remaining cake is worth exactly $(k-1)/k$ for both partners; use $\mathrm {Cut} _{2}(1/(k-1))$ to cut another piece worth exactly $1/k$ for both partners.
Continue like this until there are $k$ pieces.

Two partners can achieve an exact division with any rational ratio of entitlements by a slightly more complicated procedure.^[3]^: 71

Many partners

By combining $\mathrm {Cut} _{2}$ with the Fink protocol, it is possible to divide a cake to $n$ partners, such that each partner receives a piece worth exactly $1/n$ for him:^[1]^[4]

Partners #1 and #2 use $\mathrm {Cut} _{2}(1/2)$ to give each one of them a piece worth exactly 1/2 for them.
Partner #3 uses $\mathrm {Cut} _{2}(1/3)$ with partner #1 to get exactly 1/3 of his share and then $\mathrm {Cut} _{2}(1/3)$ with partner #2 to get exactly 1/3 of her share. The first piece is worth exactly 1/6 for partner #1 and so partner #1 remains with exactly 1/3; the same is true for partner #2. As for partner #3, while each piece can be more or less than 1/6, the sum of the two pieces must be exactly 1/3 of the entire cake.

Note that for $n>2$ , the generated division is not exact, since a piece is worth $1/n$ only to its owner and not necessarily to the other partners. As of 2015, there is no known exact division procedure for $n>2$ partners; only near-exact division procedures are known.

Related Research Articles

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Divide and choose is a procedure for fair division of a continuous resource, such as a cake, between two parties. It involves a heterogeneous good or resource and two partners who have different preferences over parts of the cake. The protocol proceeds as follows: one person cuts the cake into two pieces; the other person selects one of the pieces; the cutter receives the remaining piece.

A proportional division is a kind of fair division in which a resource is divided among n partners with subjective valuations, giving each partner at least 1/n of the resource by his/her own subjective valuation.

Chore division is a fair division problem in which the divided resource is undesirable, so that each participant wants to get as little as possible. It is the mirror-image of the fair cake-cutting problem, in which the divided resource is desirable so that each participant wants to get as much as possible. Both problems have heterogeneous resources, meaning that the resources are nonuniform. In cake division, cakes can have edge, corner, and middle pieces along with different amounts of frosting. Whereas in chore division, there are different chore types and different amounts of time needed to finish each chore. Similarly, both problems assume that the resources are divisible. Chores can be infinitely divisible, because the finite set of chores can be partitioned by chore or by time. For example, a load of laundry could be partitioned by the number of articles of clothing and/or by the amount of time spent loading the machine. The problems differ, however, in the desirability of the resources. The chore division problem was introduced by Martin Gardner in 1978.

Exact division, also called consensus division, is a partition of a continuous resource ("cake") into some k pieces, such that each of n people with different tastes agree on the value of each of the pieces. For example, consider a cake which is half chocolate and half vanilla. Alice values only the chocolate and George values only the vanilla. The cake is divided into three pieces: one piece contains 20% of the chocolate and 20% of the vanilla, the second contains 50% of the chocolate and 50% of the vanilla, and the third contains the rest of the cake. This is an exact division (with k=3 and n=2), as both Alice and George value the three pieces as 20%, 50% and 30% respectively. Several common variants and special cases are known by different terms:

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The last diminisher procedure is a procedure for fair cake-cutting. It involves a certain heterogenous and divisible resource, such as a birthday cake, and n partners with different preferences over different parts of the cake. It allows the n people to achieve a proportional division, i.e., divide the cake among them such that each person receives a piece with a value of at least 1/n of the total value according to his own subjective valuation. For example, if Alice values the entire cake as $100 and there are 5 partners then Alice can receive a piece that she values as at least $20, regardless of what the other partners think or do.

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The Fink protocol is a protocol for proportional division of a cake.

The fair pie-cutting problem is a variation of the fair cake-cutting problem, in which the resource to be divided is circular.

The Brams–Taylor–Zwicker procedure is a protocol for envy-free cake-cutting among 4 partners.

Equitable (EQ) cake-cutting is a kind of a fair cake-cutting problem, in which the fairness criterion is equitability. It is a cake-allocation in which the subjective value of all partners is the same, i.e., each partner is equally happy with his/her share. Mathematically, that means that for all partners $i$ and $j$ :

A proportional cake-cutting is a kind of fair cake-cutting. It is a division of a heterogeneous resource ("cake") that satisfies the proportionality criterion, namely, that every partner feels that his allocated share is worth at least 1/n of the total.

Weller's theorem is a theorem in economics. It says that a heterogeneous resource ("cake") can be divided among n partners with different valuations in a way that is both Pareto-efficient (PE) and envy-free (EF). Thus, it is possible to divide a cake fairly without compromising on economic efficiency.

In the fair cake-cutting problem, the partners often have different entitlements. For example, the resource may belong to two shareholders such that Alice holds 8/13 and George holds 5/13. This leads to the criterion of weighted proportionality (WPR): there are several weights $that sum up to 1, and every partner should receive at least a fraction of the resource by their own valuation.$

The Robertson–Webb rotating-knife procedure is a procedure for envy-free cake-cutting of a two-dimensional cake among three partners. It makes only two cuts, so each partner receives a single connected piece.

The Barbanel–Brams rotating-knife procedure is a procedure for envy-free cake-cutting of a cake among three partners. It makes only two cuts, so each partner receives a single connected piece.

Symmetric fair cake-cutting is a variant of the fair cake-cutting problem, in which fairness is applied not only to the final outcome, but also to the assignment of roles in the division procedure.

Truthful cake-cutting is the study of algorithms for fair cake-cutting that are also truthful mechanisms, i.e., they incentivize the participants to reveal their true valuations to the various parts of the cake.

References

1 2 Austin, A. K. (1982). "Sharing a Cake". The Mathematical Gazette. 66 (437): 212–215. doi:10.2307/3616548. JSTOR 3616548. S2CID 158398839.
1 2 3 Brams, Steven J.; Taylor, Alan D. (1996). Fair Division[From cake-cutting to dispute resolution]. pp. 22–27. ISBN 978-0-521-55644-6.
1 2 Robertson, Jack; Webb, William (1998). Cake-Cutting Algorithms: Be Fair If You Can. Natick, Massachusetts: A. K. Peters. ISBN 978-1-56881-076-8. LCCN 97041258. OL 2730675W.
↑ Brams, Steven J.; Taylor, Alan D. Fair Division[From cake-cutting to dispute resolution]. pp. 43–44. ISBN 978-0-521-55644-6.

External links

Fischer, Daniel. "Consensus division of a cake to two people in arbitrary ratios". Math.SE. Retrieved 23 June 2015.

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[austin-1] 1 2 Austin, A. K. (1982). "Sharing a Cake". The Mathematical Gazette. 66 (437): 212–215. doi:10.2307/3616548. JSTOR 3616548. S2CID 158398839.

[bramstaylor-2] 1 2 3 Brams, Steven J.; Taylor, Alan D. (1996). Fair Division[From cake-cutting to dispute resolution]. pp. 22–27. ISBN 978-0-521-55644-6.

[rw98-3] 1 2 Robertson, Jack; Webb, William (1998). Cake-Cutting Algorithms: Be Fair If You Can. Natick, Massachusetts: A. K. Peters. ISBN 978-1-56881-076-8. LCCN 97041258. OL 2730675W.

[bramstaylor43-4] Brams, Steven J.; Taylor, Alan D. Fair Division[From cake-cutting to dispute resolution]. pp. 43–44. ISBN 978-0-521-55644-6.

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