Lonely runner conjecture

Animation illustrating the case of 6 runners

Example of lonely runner conjecture with 6 runners

In number theory, and especially the study of diophantine approximation, the lonely runner conjecture is a conjecture originally due to J. M. Wills in 1967. Applications of the conjecture are widespread in mathematics; they include view obstruction problems^[1] and calculating the chromatic number of distance graphs and circulant graphs.^[2] The conjecture was given its picturesque name by L. Goddyn in 1998.^[3]

Formulation

Unsolved problem in mathematics:

Is the lonely runner conjecture true for any number k of runners?
(more unsolved problems in mathematics)

Consider k runners on a circular track of unit length. At t = 0, all runners are at the same position and start to run; the runners' speeds are pairwise distinct. A runner is said to be lonely at time t if they are at a distance of at least 1/k from every other runner at time t. The lonely runner conjecture states that each runner is lonely at some time.

A convenient reformulation of the conjecture is to assume that the runners have integer speeds,^[4] not all divisible by the same prime; the runner to be lonely has zero speed. The conjecture then states that for any set D of k − 1 positive integers with greatest common divisor 1,

\exists t\in \mathbb {R} \quad \forall d\in D\quad \|td\|\geq {\frac {1}{k}},

where ||x|| denotes the distance of real number x to the nearest integer.

Known results

k	year proved	proved by	notes
1	-	-	trivial: t = 0; any t
2	-	-	trivial: t = 1 / (2(v₁ − v₀))
3	-	-	trivial: with zero speed of the runner to be lonely, it happens within the first round of the slower runner
4	1972	Betke and Wills;^[5] Cusick^[6]	-
5	1984	Cusick and Pomerance;^[7] Bienia et al.^[3]	-
6	2001	Bohman, Holzman, Kleitman;^[8] Renault^[9]	-
7	2008	Barajas and Serra^[2]	-

Dubickas^[10] shows that for a sufficiently large number of runners for speeds $v_{1}<v_{2}<\cdots <v_{k}$ the lonely runner conjecture is true if ${\frac {v_{i+1}}{v_{i}}}\geq 1+{\frac {33\log(k)}{k}}$ .

Notes

↑ T. W. Cusick (1973). "View-Obstruction problems". Aequationes Mathematicae. 9 (2–3): 165–170. doi:10.1007/BF01832623.
1 2 J. Barajas and O. Serra (2008). "The lonely runner with seven runners". Electronic Journal of Combinatorics. 15: R48.
1 2 W. Bienia; et al. (1998). "Flows, view obstructions, and the lonely runner problem". Journal of Combinatorial Theory, Series B. 72: 1–9. doi:10.1006/jctb.1997.1770.
↑ This reduction is proved, for example, in section 4 of the paper by Bohman, Holzman, Kleitman.
↑ Betke, U.; Wills, J. M. (1972). "Untere Schranken für zwei diophantische Approximations-Funktionen". Monatshefte für Mathematik. 76 (3): 214. doi:10.1007/BF01322924.
↑ T. W. Cusick (1974). "View-obstruction problems in n-dimensional geometry". Journal of Combinatorial Theory, Series A. 16 (1): 1–11. doi:10.1016/0097-3165(74)90066-1.
↑ Cusick, T.W.; Pomerance, Carl (1984). "View-obstruction problems, III". Journal of Number Theory. 19 (2): 131–139. doi:10.1016/0022-314X(84)90097-0.
↑ Bohman, T.; Holzman, R.; Kleitman, D. (2001), "Six lonely runners", Electronic Journal of Combinatorics, 8 (2)
↑ Renault, J. (2004). "View-obstruction: A shorter proof for 6 lonely runners". Discrete Mathematics. 287: 93–101. doi:10.1016/j.disc.2004.06.008.
↑ Dubickas, A. (2011). "The lonely runner problem for many runners". Glasnik Matematicki. 46: 25–30. doi:10.3336/gm.46.1.05.

External links

article in the Open Problem Garden

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