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Search: a350378 -id:a350378
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Consider integer-sided triangles having integer area and let d be the distance between the center of the inscribed circle and the center of the circumscribed circle. The sequence lists the set of distances d which are prime numbers.
+0
4
5, 13, 17, 53, 193, 241
OFFSET
1,1
COMMENTS
The corresponding integer areas of integer-sided triangles such that the distance between the incenter and the circumcenter is a prime number is given by the sequence A350378.
In geometry, Euler's theorem states that the distance between the incenter and circumcenter can be expressed as d = sqrt(R(R-2r)), where R is the circumradius and r is the inradius.
The area A of a triangle whose sides have lengths a, b, and c is given by Heron's formula: A = sqrt(s(s-a)(s-b)(s-c)), where s = (a+b+c)/2.
The inradius r is given by r = A/s and the circumradius is given by R = abc/4A.
The following table gives the first values (A, a, b, c, r, R, d) where A is the area of the triangles, a, b, c are the integer sides of the triangles, r is the inradius, R is the circumradius and d is the distance between the incenter and circumcenter with d = sqrt(R(R-2r)).
+------------+--------+--------+---------+---------+---------+-----+
| A | a | b | c | r | R | d |
+------------+--------+--------+---------+---------+---------+-----+
| 48 | 10 | 10 | 16 | 8/3 | 25/3 | 5 |
| 768 | 40 | 40 | 48 | 12 | 25 | 5 |
| 3840 | 80 | 104 | 104 | 80/3 | 169/3 | 13 |
| 108000 | 480 | 510 | 510 | 144 | 289 | 17 |
| 1134000 | 1590 | 1590 | 1680 | 1400/3 | 2809/3 | 53 |
| 200202240 | 21280 | 21616 | 21616 | 18620/3 | 37249/3 | 193 |
| 4382077920 | 100320 | 100738 | 100738 | 29040 | 58081 | 241 |
....................................................................
From the previous table, we observe that the triangles are isosceles, the distance between the incenter and the circumcenter is d = sqrt(R) if R is a perfect square, or d = sqrt(3R) if R is of the form k^2/3, k integer. We also observe that d divides the two equal sides of the isosceles triangle: 10/5 = 2, 40/5 = 8, 104/13 = 8, 510/17 = 30, 1590/853 = 30, 21616/193 = 112, 100738/241 = 418,...}.
REFERENCES
Mohammad K. Azarian, Circumradius and Inradius, Problem S125, Math Horizons, Vol. 15, Issue 4, April 2008, p. 32.
R. A. Johnson, Modern Geometry: An Elementary Treatise on the Geometry of the Triangle and the Circle. Boston, MA: Houghton Mifflin, 1929.
LINKS
Mohammad K. Azarian, Solution of problem 125: Circumradius and Inradius, Math Horizons, Vol. 16, No. 2 (Nov. 2008), p. 32.
Eric Weisstein's World of Mathematics, Exradius
Eric Weisstein's World of Mathematics, Inradius
MATHEMATICA
nn=520; lst={}; Do[s=(a+b+c)/2; If[IntegerQ[s], area2=s (s-a)(s-b)(s-c); If[area2>0&&IntegerQ[Sqrt[area2]]&&PrimeQ[Sqrt[a*b*c/(4*Sqrt[area2])*(a*b*c/(4*Sqrt[area2])-2*Sqrt[area2]/s)]], Print[Sqrt[area2], " ", c, " ", b, " ", a, " ", Sqrt[area2]/s, " ", a*b*c/(4*Sqrt[area2]), " ", Sqrt[a*b*c/(4*Sqrt[area2])*(a*b*c/(4*Sqrt[area2])-2*Sqrt[area2]/s)]]]], {a, nn}, {b, a}, {c, b}]
CROSSREFS
KEYWORD
nonn,more
AUTHOR
Michel Lagneau, Dec 28 2021
STATUS
approved
Primitive triples (a, b, c) of integer-sided triangles such that the distance d = OI between the circumcenter O and the incenter I is also a positive integer. The triples of sides (a, b, c) are in increasing order a <= b <= c.
+0
2
10, 10, 16, 40, 40, 48, 16, 49, 55, 80, 104, 104, 15, 169, 176, 130, 130, 240, 231, 361, 416, 246, 246, 480, 272, 272, 480, 480, 510, 510, 296, 296, 560, 350, 350, 672, 455, 961, 1104, 672, 1200, 1200, 259, 1040, 1221, 1040, 1369, 1551, 1160, 1160, 1680, 1218, 1218, 1680
OFFSET
1,1
COMMENTS
The triples (a, b, c) are displayed in increasing order of largest side c, and if largest sides c coincide then by increasing order of the middle side b.
Primitive triples means here that gcd(a, b, c, d) = 1 (see first example).
Equilateral triangles are not present because in this case O = I and d = 0.
Euler's triangle formula says that distance between the circumcenter O and the incenter I of a triangle is given by d = OI = sqrt(R*(R-2r)).
Heron's formula says the area A of a triangle whose sides have lengths a, b and c is given by A = sqrt(s(s-a)(s-b)(s-c)), where s = (a+b+c)/2; then, the circumradius is given by R = abc/4A and the inradius r is given by r = A/s.
With these relations, d = OI = abc * sqrt(1/(16*A^2) - 1/(abc*(a+b+c))).
+-----+-----+-----+---------------+---------------+-----+----------------------+
| a | b | c | r | R | d | a+b+c| A |
+-----------+-----+---------------+---------------+-----+------+---------------+
| 10 | 10 | 16 | 8/3 | 25/3 | 5 | 36 | 48 |
| 40 | 40 | 48 | 12 | 25 | 5 | 128 | 768 |
| 16 | 49 | 55 | 11*sqrt(3)/3 | 49*sqrt(3)/3 | 21 | 120 | 220*sqrt(3) |
| 80 | 104 | 104 | 80/3 | 169/3 | 13 | 288 | 3840 |
| 15 | 169 | 176 | 11*sqrt(3)/3 | 169*sqrt(3)/3 | 91 | 360 | 1903sqrt(3)/3 |
| 130 | 130 | 240 | 24 | 169 | 143 | 500 | 6000 |
| 231 | 361 | 416 | 143*sqrt(3)/3 | 361*sqrt(3)/3 | 95 | 1008 | 24024*sqrt(3) |
| 246 | 246 | 480 | 80/3 | 1681/3 | 533 | 972 | 12960 |
| 272 | 272 | 480 | 60 | 289 | 221 | 1024 | 30720 |
| 480 | 510 | 510 | 144 | 289 | 17 | 1500 | 108000 |
| 296 | 296 | 560 | 140/3 | 1369/3 | 407 | 1152 | 26880 |
................................................................................
Observations coming from the previous table:
There exist two families of triangles,
1) triangle ABC is isosceles with a = b < c or a < b = c.
In this case, r and R are rational integers with same denominator = 1 or 3, and the area A of this triangle is a term of A231174.
Note that besides, if d is prime, d divides the two equal sides of the isosceles triangle, and also, there are these two possibilities:
-> d^2 = R and then r = (R-1)/2, or
-> d^2 = 3R and then r = (R-3)/2.
2) triangle ABC is scalene with a < b < c.
In this case, r and R are both quadratic of the form k*sqrt(3)/3.
LINKS
Eric Weisstein's World of Mathematics, Circumcircle.
Eric Weisstein's World of Mathematics, Circumradius.
Eric Weisstein's World of Mathematics, Euler Triangle Formula.
Eric Weisstein's World of Mathematics, Incircle.
Eric Weisstein's World of Mathematics, Inradius.
EXAMPLE
The table begins:
10, 10, 16;
40, 40, 48;
16, 49, 55;
80, 104, 104;
15, 169, 176;
130, 130, 240;
231, 361, 416;
.........
For first triple (10, 10, 16), s = (10+10+16)/2 = 18, A = 48, r = 48/18 = 8/3, R = 10*10*16/4*48 = 25/3, and d = sqrt(25/3 * 9/3) = 5. We observe that gcd(10, 10, 16) = 2, but that gcd(10, 10, 16, 5) = 1, in fact for triple (5, 5, 8) with gcd(5, 5, 8) = 1, OI should be 5/2.
CROSSREFS
KEYWORD
nonn,tabf
AUTHOR
Bernard Schott, Mar 11 2022
EXTENSIONS
More terms from Jinyuan Wang, Mar 12 2022
STATUS
approved
a(n) is the distance d between the incenter I and the circumcenter O of the integer-sided triangle whose sides correspond to the n-th primitive triple of A352314.
+0
2
5, 5, 21, 13, 91, 143, 95, 533, 221, 17, 407, 575, 341, 275, 703, 259, 377, 319, 53, 559, 4181, 793, 481, 3599, 715, 784, 943, 1955, 3965, 549, 7055, 6815, 2144, 1961
OFFSET
1,1
COMMENTS
The triples of sides (a, b, c) are in increasing order of largest side c.
For the corresponding primitive triples and miscellaneous properties, formulas and references see A352314.
Two distinct such triangles can have the same distance OI (see examples).
From the table in A352314, when d is prime and the triangle ABC isosceles, then
-> d divides the two equal sides of this triangle, and also,
-> if d^2 = R, then r = (R-1)/2,
-> if d^2 = 3R then r = (R-3)/2.
EXAMPLE
a(1) = 5 because with the smallest triple (10, 10, 16), we get s = (10+10+16)/2 = 18, A = 48, r = 48/18 = 8/3, R = (10*10*16)/(4*48) = 25/3, and d = sqrt(25/3 * 9/3) = 5 is an integer.
a(2) = 5 also because with the second triple (40, 40, 48), we get s = (40+40+48)/2 = 64, A = 768, r = 768/64 = 12, R = (40*40*48)/(4*768) = 25, and d = sqrt(25*(25-24)) = 5.
a(3) = 21 because with the third triple (16, 49, 55) that is the first triangle not isosceles, we get s = (16+49+55)/2 = 60, A = 220*sqrt(3), r = 11*sqrt(3)/3, R = (16*49*55)/(4*220*sqrt(3)) = 49*sqrt(3)/3, and d = sqrt(49^2/3 - (2*11*49)/3) = 21.
PROG
(PARI) lista(nn) = my(d, s); for(c=2, nn, for(b=1+c\2, c, for(a=1+c-b, b, s=(a+b+c)/2; if(denominator(d=a^2*b^2*c^2/16/s/(s-a)/(s-b)/(s-c)-a*b*c/2/s) == 1 && issquare(d) && gcd([a, b, c, d=sqrtint(d)]) == 1, print1(d, ", "))))); \\ Jinyuan Wang, Mar 15 2022
CROSSREFS
KEYWORD
nonn,more
AUTHOR
Bernard Schott, Mar 11 2022
EXTENSIONS
a(8) inserted by and a(12)-a(34) from Jinyuan Wang, Mar 15 2022
STATUS
approved
Perimeter of primitive integer-sided triangles such that the distance d = OI between the circumcenter O and the incenter I is also a positive integer.
+0
1
36, 128, 120, 288, 360, 500, 1008, 972, 1024, 1500, 1152, 1372, 2520, 3072, 2520, 3960, 4000, 4116, 4860, 5040, 4500, 5760, 6860, 5324, 6804, 6435, 8000, 7776, 8192, 10920, 8788, 9216, 10395, 10976
OFFSET
1,1
COMMENTS
For the corresponding primitive triples, miscellaneous properties and links, see A352314.
The sequence is not increasing. For example, a(2) = 128 for triangle with largest side = 48 while a(3) = 120 for triangle with largest side = 55.
FORMULA
a(n) = A352314(n, 1) + A352314(n, 2) + A352314(n, 3).
EXAMPLE
a(1) = 36 because the smallest triple is (10, 10, 16) with corresponding d = OI = A352315(1) = 5.
CROSSREFS
KEYWORD
nonn,more
AUTHOR
Bernard Schott, Mar 14 2022
EXTENSIONS
a(19)-a(34) from Jinyuan Wang, Mar 14 2022
STATUS
approved

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