The analyst's traveling salesman problem is an analog of the

traveling salesman problem The travelling salesman problem (also called the travelling salesperson problem or TSP) asks the following question: "Given a list of cities and the distances between each pair of cities, what is the shortest possible route that visits each cit ...

combinatorial optimization Combinatorial optimization is a subfield of mathematical optimization that consists of finding an optimal object from a finite set of objects, where the set of feasible solutions is discrete or can be reduced to a discrete set. Typical combi ...

. In its simplest and original form, it asks which plane sets are subsets of rectifiable curves of finite length. Whereas the original traveling salesman problem asks for the shortest way to visit every vertex in a finite set with a discrete path, this analytical version may require the curve to visit infinitely many points.

β-numbers

A rectifiable curve has

tangent In geometry, the tangent line (or simply tangent) to a plane curve at a given point is the straight line that "just touches" the curve at that point. Leibniz defined it as the line through a pair of infinitely close points on the curve. Mo ...

s at almost all of its points, where in this case "almost all" means all but a subset whose one-dimensional

Hausdorff measure In mathematics, Hausdorff measure is a generalization of the traditional notions of area and volume to non-integer dimensions, specifically fractals and their Hausdorff dimensions. It is a type of outer measure, named for Felix Hausdorff, that as ...

is zero. Accordingly, if a set is contained in a rectifiable curve, the set must look ''flat'' when zooming in on almost all of its points. This suggests that testing us whether a set could be contained in a rectifiable curve must somehow incorporate information about how flat it is when one zooms in on its points at different scales. This discussion motivates the definition of the following quantity, for a plane set

E\subset\R^2

: where

E

is the set that is to be contained in a rectifiable curve,

Q

is any square,

\ell(Q)

is the side length of

Q

, and dist

(x,L)

measures the distance from

x

to the line

L

. Intuitively,

2\beta_E(Q)\ell(Q)

is the width of the smallest rectangle containing the portion of

E

inside

Q

, and hence

\beta_E(Q)

gives a scale invariant notion of ''flatness''.

Jones' traveling salesman theorem in R²

Let Δ denote the collection of dyadic squares, that is, :

\Delta=\,

where

\mathbb

denotes the set of integers. For a set

E\subseteq\mathbb^2

, define :

\beta(E)=\text E+ \sum_\beta_(3Q)^2 \ell(Q)

where diam ''E'' is the

diameter In geometry, a diameter of a circle is any straight line segment that passes through the center of the circle and whose endpoints lie on the circle. It can also be defined as the longest chord of the circle. Both definitions are also valid fo ...

of ''E'' and

3Q

is the square with same center as

Q

with side length

3\ell(Q)

. Then Peter Jones's analyst's traveling salesman theorem may be stated as follows: * There is a number ''C'' > 0 such that whenever ''E'' is a set with such that ''β''(''E'') < ∞, ''E'' can be contained in a curve with length no more than ''Cβ''(''E''). * Conversely (and substantially more difficult to prove), if Γ is a rectifiable curve, then ''β''(Γ) < CH¹(Γ).

Generalizations and Menger curvature

Euclidean space and Hilbert space

The Traveling Salesman Theorem was shown to hold in general Euclidean spaces by Kate Okikiolu, that is, the same theorem above holds for sets

E\subseteq\mathbb^d

, ''d'' > 1, where Δ is now the collection of dyadic cubes in

\mathbb^d

defined in a similar way as dyadic squares. In her proof, the constant ''C'' grows exponentially with the dimension ''d''. With some slight modifications to the definition of ''β''(''E''), Raanan Schul showed Traveling Salesman Theorem also holds for sets ''E'' that lie in any Hilbert Space, and in particular, implies the theorems of Jones and Okikiolu, where now the constant ''C'' is independent of dimension. (In particular, this involves using ''β''-numbers of balls instead of cubes).

Menger curvature and metric spaces

Hahlomaa further adjusted the definition of ''β''(''E'') to get a condition for when a set ''E'' of an arbitrary

metric space In mathematics, a metric space is a set together with a notion of '' distance'' between its elements, usually called points. The distance is measured by a function called a metric or distance function. Metric spaces are the most general set ...

may be contained in the Lipschitz-image of a subset

A\subseteq\mathbb

of positive measure. For this, he had to redefine the definition of the ''β''-numbers using menger curvature (since in a metric space there isn't necessarily a notion of a cube or a straight line). Menger curvature, as in the previous example, can be used to give numerical estimates that determine whether a set contains a rectifiable subset, and the proofs of these results frequently depend on ''β''-numbers.

Denjoy–Riesz theorem

The

Denjoy–Riesz theorem In topology, the Denjoy–Riesz theorem states that every compact set of totally disconnected points in the Euclidean plane can be covered by a continuous image of the unit interval, without self-intersections (a Jordan arc). Definitions and sta ...

gives general conditions under which a point set can be covered by the homeomorphic image of a curve. This is true, in particular, for every compact

totally disconnected In topology and related branches of mathematics, a totally disconnected space is a topological space that has only singletons as connected subsets. In every topological space, the singletons (and, when it is considered connected, the empty set) ...

subset of the Euclidean plane. However, it may be necessary for such an arc to have infinite length, failing to meet the conditions of the analyst's traveling salesman theorem.

References

{{Reflist, 30em Harmonic analysis Real analysis Geometry Theorems in discrete mathematics