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Using the Pythagorean theorem to compute two-dimensional Euclidean distance

In mathematics, the Euclidean distance between two points in Euclidean space is the length of a line segment between the two points. It can be calculated from the Cartesian coordinates of the points using the Pythagorean theorem, therefore occasionally being called the Pythagorean distance. These names come from the ancient Greek mathematicians Euclid and Pythagoras, although Euclid did not represent distances as numbers, and the connection from the Pythagorean theorem to distance calculation was not made until the 17th century.

The distance between two objects that are not points is usually defined to be the smallest distance among pairs of points from the two objects. Formulas are known for computing distances between different types of objects, such as the distance from a point to a line. In advanced mathematics, the concept of distance has been generalized to abstract metric spaces, and other distances than Euclidean have been studied. In some applications in statistics and optimization, the square of the Euclidean distance is used instead of the distance itself.

Distance formulas

One dimension

The distance between any two points on the real line is the absolute value of the numerical difference of their coordinates. Thus if and are two points on the real line, then the distance between them is given by:[1] A more complicated formula, giving the same value, but generalizing more readily to higher dimensions, is:[1] In this formula, squaring and then taking the square root leaves any positive number unchanged, but replaces any negative number by its absolute value.[1]

Two dimensions

In the Euclidean plane, let point have Cartesian coordinates and let point have coordinates . Then the distance between and is given by:[2] This can be seen by applying the Pythagorean theorem to a right triangle with horizontal and vertical sides, having the line segment from to as its hypotenuse. The two squared formulas inside the square root give the areas of squares on the horizontal and vertical sides, and the outer square root converts the area of the square on the hypotenuse into the length of the hypotenuse.[3]

It is also possible to compute the distance for points given by polar coordinates. If the polar coordinates of are and the polar coordinates of are , then their distance is[2]

When and are expressed as complex numbers in the complex plane, the same formula for one-dimensional points expressed as real numbers can be used:[4]

Higher dimensions

Deriving the -dimensional Euclidean distance formula by repeatedly applying the Pythagorean theorem

In three dimensions, for points given by their Cartesian coordinates, the distance is In general, for points given by Cartesian coordinates in -dimensional Euclidean space, the distance is[5]

Objects other than points

For pairs of objects that are not both points, the distance can most simply be defined as the smallest distance between any two points from the two objects, although more complicated generalizations from points to sets such as Hausdorff distance are also commonly used.[6] Formulas for computing distances between different types of objects include:

Properties

The Euclidean distance is the prototypical example of the distance in a metric space,[9] and obeys all the defining properties of a metric space:[10]

  • It is symmetric, meaning that for all points and , . That is (unlike road distance with one-way streets) the distance between two points does not depend on which of the two points is the start and which is the destination.[10]
  • It is positive, meaning that the distance between every two distinct points is a positive number, while the distance from any point to itself is zero.[10]
  • It obeys the triangle inequality: for every three points , , and , . Intuitively, traveling from to via cannot be any shorter than traveling directly from to .[10]

Another property, Ptolemy's inequality, concerns the Euclidean distances among four points , , , and . It states that For points in the plane, this can be rephrased as stating that for every quadrilateral, the products of opposite sides of the quadrilateral sum to at least as large a number as the product of its diagonals. However, Ptolemy's inequality applies more generally to points in Euclidean spaces of any dimension, no matter how they are arranged.[11] Euclidean distance geometry studies properties of Euclidean distance such as Ptolemy's inequality, and their application in testing whether given sets of distances come from points in a Euclidean space.[12]

Squared Euclidean distance

A cone, the graph of Euclidean distance from the origin in the plane
A paraboloid, the graph of squared Euclidean distance from the origin

In many applications, and in particular when comparing distances, it may be more convenient to omit the final square root in the calculation of Euclidean distances. The value resulting from this omission is the square of the Euclidean distance, and is called the squared Euclidean distance.[13] As an equation, it can be expressed as a sum of squares:

Beyond its application to distance comparison, squared Euclidean distance is of central importance in statistics, where it is used in the method of least squares, a standard method of fitting statistical estimates to data by minimizing the average of the squared distances between observed and estimated values.[14] The addition of squared distances to each other, as is done in least squares fitting, corresponds to an operation on (unsquared) distances called Pythagorean addition.[15] In cluster analysis, squared distances can be used to strengthen the effect of longer distances.[13]

Squared Euclidean distance does not form a metric space, as it does not satisfy the triangle inequality.[16] However it is a smooth, strictly convex function of the two points, unlike the distance, which is non-smooth (near pairs of equal points) and convex but not strictly convex. The squared distance is thus preferred in optimization theory, since it allows convex analysis to be used. Since squaring is a monotonic function of non-negative values, minimizing squared distance is equivalent to minimizing the Euclidean distance, so the optimization problem is equivalent in terms of either, but easier to solve using squared distance.[17]

The collection of all squared distances between pairs of points from a finite set may be stored in a Euclidean distance matrix.[18] In rational trigonometry, squared Euclidean distance is used because (unlike the Euclidean distance itself) the squared distance between points with rational number coordinates is always rational; in this context it is also called "quadrance".[19]

Generalizations

In more advanced areas of mathematics, when viewing Euclidean space as a vector space, its distance is associated with a norm called the Euclidean norm, defined as the distance of each vector from the origin. One of the important properties of this norm, relative to other norms, is that it remains unchanged under arbitrary rotations of space around the origin.[20] By Dvoretzky's theorem, every finite-dimensional normed vector space has a high-dimensional subspace on which the norm is approximately Euclidean; the Euclidean norm is the only norm with this property.[21] It can be extended to infinite-dimensional vector spaces as the L2 norm or L2 distance.[22]

Other common distances on Euclidean spaces and low-dimensional vector spaces include:[23]

  • Chebyshev distance, which measures distance assuming only the most significant dimension is relevant.
  • Manhattan distance, which measures distance following only axis-aligned directions.
  • Minkowski distance, a generalization that unifies Euclidean distance, Manhattan distance, and Chebyshev distance.

For points on surfaces in three dimensions, the Euclidean distance should be distinguished from the geodesic distance, the length of a shortest curve that belongs to the surface. In particular, for measuring great-circle distances on the earth or other near-spherical surfaces, distances that have been used include the haversine distance giving great-circle distances between two points on a sphere from their longitudes and latitudes, and Vincenty's formulae also known as "Vincent distance" for distance on a spheroid.[24]

History

Euclidean distance is the distance in Euclidean space; both concepts are named after ancient Greek mathematician Euclid, whose Elements became a standard textbook in geometry for many centuries.[25] Concepts of length and distance are widespread across cultures, can be dated to the earliest surviving "protoliterate" bureaucratic documents from Sumer in the fourth millennium BC (far before Euclid),[26] and have been hypothesized to develop in children earlier than the related concepts of speed and time.[27] But the notion of a distance, as a number defined from two points, does not actually appear in Euclid's Elements. Instead, Euclid approaches this concept implicitly, through the congruence of line segments, through the comparison of lengths of line segments, and through the concept of proportionality.[28]

The Pythagorean theorem is also ancient, but it only took its central role in the measurement of distances with the invention of Cartesian coordinates by René Descartes in 1637.[29] Because of this connection, Euclidean distance is also sometimes called Pythagorean distance.[30] Although accurate measurements of long distances on the earth's surface, which are not Euclidean, had again been studied in many cultures since ancient times (see history of geodesy), the idea that Euclidean distance might not be the only way of measuring distances between points in mathematical spaces came even later, with the 19th-century formulation of non-Euclidean geometry.[31] The definition of the Euclidean norm and Euclidean distance for geometries of more than three dimensions also first appeared in the 19th century, in the work of Augustin-Louis Cauchy.[32]

References

  1. ^ a b c Smith, Karl (2013), Precalculus: A Functional Approach to Graphing and Problem Solving, Jones & Bartlett Publishers, p. 8, ISBN 9780763751777
  2. ^ a b Cohen, David (2004), Precalculus: A Problems-Oriented Approach (6th ed.), Cengage Learning, p. 698, ISBN 9780534402129
  3. ^ Aufmann, Richard N.; Barker, Vernon C.; Nation, Richard D. (2007), College Trigonometry (6th ed.), Cengage Learning, p. 17, ISBN 9781111808648
  4. ^ Andreescu, Titu; Andrica, Dorin (2014), "3.1.1 The Distance Between Two Points", Complex Numbers from A to ... Z (2nd ed.), Birkhäuser, pp. 57–58, ISBN 978-0-8176-8415-0
  5. ^ Tabak, John (2014), Geometry: The Language of Space and Form, Facts on File math library, Infobase Publishing, p. 150, ISBN 9780816068760
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  10. ^ a b c d Strichartz, Robert S. (2000), The Way of Analysis, Jones & Bartlett Learning, p. 357, ISBN 9780763714970
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  13. ^ a b Spencer, Neil H. (2013), "5.4.5 Squared Euclidean Distances", Essentials of Multivariate Data Analysis, CRC Press, p. 95, ISBN 9781466584792
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  17. ^ Kaplan, Wilfred (2011), Maxima and Minima with Applications: Practical Optimization and Duality, Wiley Series in Discrete Mathematics and Optimization, vol. 51, John Wiley & Sons, p. 61, ISBN 9781118031049
  18. ^ Alfakih, Abdo Y. (2018), Euclidean Distance Matrices and Their Applications in Rigidity Theory, Springer, p. 51, ISBN 9783319978468
  19. ^ Henle, Michael (December 2007), "Review of Divine Proportions by N. J. Wildberger", American Mathematical Monthly, 114 (10): 933–937, JSTOR 27642383
  20. ^ Kopeikin, Sergei; Efroimsky, Michael; Kaplan, George (2011), Relativistic Celestial Mechanics of the Solar System, John Wiley & Sons, p. 106, ISBN 9783527634576
  21. ^ Matoušek, Jiří (2002), Lectures on Discrete Geometry, Graduate Texts in Mathematics, Springer, p. 349, ISBN 978-0-387-95373-1
  22. ^ Ciarlet, Philippe G. (2013), Linear and Nonlinear Functional Analysis with Applications, Society for Industrial and Applied Mathematics, p. 173, ISBN 9781611972580
  23. ^ Klamroth, Kathrin (2002), "Section 1.1: Norms and Metrics", Single-Facility Location Problems with Barriers, Springer Series in Operations Research, Springer, pp. 4–6, doi:10.1007/0-387-22707-5_1
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  25. ^ Zhang, Jin (2007), Visualization for Information Retrieval, Springer, ISBN 9783540751489
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  29. ^ Maor, Eli (2019), The Pythagorean Theorem: A 4,000-Year History, Princeton University Press, p. 133, ISBN 9780691196886
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