Math::PlanePath::Hypot(3pm) | User Contributed Perl Documentation | Math::PlanePath::Hypot(3pm) |
Math::PlanePath::Hypot -- points in order of hypotenuse distance
use Math::PlanePath::Hypot; my $path = Math::PlanePath::Hypot->new; my ($x, $y) = $path->n_to_xy (123);
This path visits integer points X,Y in order of their distance from the origin 0,0, or anti-clockwise from the X axis among those of equal distance,
84 73 83 5 74 64 52 47 51 63 72 4 75 59 40 32 27 31 39 58 71 3 65 41 23 16 11 15 22 38 62 2 85 53 33 17 7 3 6 14 30 50 82 1 76 48 28 12 4 1 2 10 26 46 70 <- Y=0 86 54 34 18 8 5 9 21 37 57 89 -1 66 42 24 19 13 20 25 45 69 -2 77 60 43 35 29 36 44 61 81 -3 78 67 55 49 56 68 80 -4 87 79 88 -5 ^ -5 -4 -3 -2 -1 X=0 1 2 3 4 5
For example N=58 is at X=4,Y=-1 is sqrt(4*4+1*1) = sqrt(17) from the origin. The next furthest from the origin is X=3,Y=3 at sqrt(18).
See "TriangularHypot" for points in order of X^2+3*Y^2, or "DiamondSpiral" and "PyrmaidSides" in order of plain sum X+Y.
Points with the same distance are taken in anti-clockwise order around from the X axis. For example X=3,Y=1 is sqrt(10) from the origin, as are the swapped X=1,Y=3, and X=-1,Y=3 etc in other quadrants, for a total 8 points N=30 to N=37 all the same distance.
When one of X or Y is 0 there's no negative, so just four negations like N=10 to 13 points X=2,Y=0 through X=0,Y=-2. Or on the diagonal X==Y there's no swap, so just four like N=22 to N=25 points X=3,Y=3 through X=3,Y=-3.
There can be more than one way for the same distance to arise. A Pythagorean triple like 3^2 + 4^2 == 5^2 has 8 points from the 3,4, then 4 points from the 5,0 giving a total 12 points N=70 to N=81. Other combinations like 20^2 + 15^2 == 24^2 + 7^2 occur too, and also with more than two different ways to have the same sum.
The first point of a given distance from the origin is either on the X axis or somewhere in the first octant. The row Y=1 just above the axis is the first of its equals from X>=2 onwards, and similarly further rows for big enough X.
There's always a multiple of 4 many points with the same distance so the first point has N=4*k+2, and similarly on the negative X side N=4*j, for some k or j. If you plot the prime numbers on the path then those even N's (composites) are gaps just above the positive X axis, and on or just below the negative X axis.
Gauss's circle lattice problem asks how many integer X,Y points there are within a circle of radius R.
The points on the X axis N=2,10,26,46, etc are the first for which X^2+Y^2==R^2 (integer X==R). Adding option "n_start=>0" to make them each 1 less gives the number of points strictly inside, ie. X^2+Y^2 < R^2.
The last point satisfying X^2+Y^2==R^2 is either in the octant below the X axis, or is on the negative Y axis. Those N's are the number of points X^2+Y^2<=R^2, Sloane's A000328.
When that A000328 sequence is plotted on the path a straight line can be seen in the fourth quadrant extending down just above the diagonal. It arises from multiples of the Pythagorean 3^2 + 4^2, first X=4,Y=-3, then X=8,Y=-6, etc X=4*k,Y=-3*k. But sometimes the multiple is not the last among those of that 5*k radius, so there's gaps in the line. For example 20,-15 is not the last since because 24,-7 is also 25 away from the origin.
Option "points => "even"" visits just the even points, meaning the sum X+Y even, so X,Y both even or both odd.
points => "even" 52 40 39 51 5 47 32 23 31 46 4 53 27 16 15 26 50 3 33 11 7 10 30 2 41 17 3 2 14 38 1 24 8 1 6 22 <- Y=0 42 18 4 5 21 45 -1 34 12 9 13 37 -2 54 28 19 20 29 57 -3 48 35 25 36 49 -4 55 43 44 56 -5 ^ -5 -4 -3 -2 -1 X=0 1 2 3 4 5
Even points can be mapped to all points by a 45 degree rotate and flip. N=1,6,22,etc on the X axis here is on the X=Y diagonal of all-points. And conversely N=1,2,10,26,etc on the X=Y diagonal here is the X axis of all-points.
The sets of points with equal hypotenuse are the same in the even and all, but the flip takes them in a reversed order.
Option "points => "odd"" visits just the odd points, meaning sum X+Y odd, so X,Y one odd the other even.
points => "odd" 71 55 54 70 6 63 47 36 46 62 5 64 37 27 26 35 61 4 72 38 19 14 18 34 69 3 48 20 7 6 17 45 2 56 28 8 2 5 25 53 1 39 15 3 + 1 13 33 <- Y=0 57 29 9 4 12 32 60 -1 49 21 10 11 24 52 -2 73 40 22 16 23 44 76 -3 65 41 30 31 43 68 -4 66 50 42 51 67 -5 74 58 59 75 -6 ^ -6 -5 -4 -3 -2 -1 X=0 1 2 3 4 5 6
Odd points can be mapped to all points by a 45 degree rotate and a shift X-1,Y+1 to put N=1 at the origin. The effect of that shift is as if the hypot measure in "all" points was (X-1/2)^2+(Y-1/2)^2 and for that reason the sets of points with equal hypots are not the same in odd and all.
See "FUNCTIONS" in Math::PlanePath for behaviour common to all path classes.
"all" all integer X,Y (the default) "even" only points with X+Y even "odd" only points with X+Y odd
For "$n < 1" the return is an empty list, it being considered the first point at X=0,Y=0 is N=1.
Currently it's unspecified what happens if $n is not an integer. Successive points are a fair way apart, so it may not make much sense to say give an X,Y position in between the integer $n.
For "even" and "odd" options only every second square in the plane has an N and if "$x,$y" is a position not covered then the return is "undef".
The calculations are not particularly efficient currently. Private arrays are built similar to what's described for "HypotOctant", but with replication for negative and swapped X,Y.
Entries in Sloane's Online Encyclopedia of Integer Sequences related to this path include
points="all", n_start=0 A051132 N on X axis, being count points norm < X^2 points="odd" A005883 count of points with norm==4*n+1
Math::PlanePath, Math::PlanePath::HypotOctant, Math::PlanePath::TriangularHypot, Math::PlanePath::PixelRings, Math::PlanePath::PythagoreanTree
<http://user42.tuxfamily.org/math-planepath/index.html>
Copyright 2011, 2012, 2013, 2014, 2015, 2016, 2017, 2018, 2019, 2020 Kevin Ryde
This file is part of Math-PlanePath.
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2021-01-23 | perl v5.32.0 |