Yahoo Clever wird am 4. Mai 2021 (Eastern Time, Zeitzone US-Ostküste) eingestellt. Ab dem 20. April 2021 (Eastern Time) ist die Website von Yahoo Clever nur noch im reinen Lesemodus verfügbar. Andere Yahoo Produkte oder Dienste oder Ihr Yahoo Account sind von diesen Änderungen nicht betroffen. Auf dieser Hilfeseite finden Sie weitere Informationen zur Einstellung von Yahoo Clever und dazu, wie Sie Ihre Daten herunterladen.
Question about decomposing an equilateral triangle into two triangles?
What are all possible positive integer pairs (m, n) that validate the picture exactly?
Note:
the smallest solution is (m, n) = (7, 4).
2 Antworten
- Barry GLv 7vor 6 JahrenBeste Antwort
The height of the triangle is h where
h^2=(2n)^2-n^2=3n^2.
Also, m^2=h^2+1^2.
Therefore
m^2=3n^2+1
or
m^2-3n^2=1.
This is Pell's Equation (see Source). The smallest solution is trivial : (m,n) = (1,0). The smallest non-trivial solution (the fundamental solution) is (2,1). Then comes (7,4) as stated in the question.
All other solutions can be found from the coupled recurrence relations
m(k+1)=am(k)+nbn(k)
n(k+1)=bm(k)+an(k)
where (a,b)=(m0,n0) is the fundamental solution.
Here (a,b)=(2,1) so the next solutions are
m1=2*2+3*1*1=7
n1=1*2+2*1=4
m2=2*7+3*1*4=26
n2=1*7+2*4=15.
- DukeLv 7vor 6 Jahren
Excellent answer and thumbs up for Barry G! All solutions of the Pell's Equation m² - 3n² = 1, starting from (7, 4) exhaust the question.
Yet I decided to contribute a little bit, because I noticed some points of interest. Imagine not single Cevian as on Rita's picture above, but all 3, whose endpoints divide each side in ratio r = (n - 1)/(n + 1) as shown below. Trivially follows that the green triangle is also equilateral and the areas of the initial and the internal triangles are in ratio
(r² + r + 1) / (r - 1)²
http://en.wikipedia.org/wiki/Routh%27s_theorem
For r = (n - 1)/(n + 1) the above expression yields (3n² + 1)/4, what is integer for all n - odd, but if n is an odd solution of the cited Pell's Equation, then
3n² + 1 = m² with m - even (m and n have different parity in each solution), so we have in fact proven the following statement:
Given the conditions in the initial question, the ratio of areas of both equilateral triangles is also integer (and even a perfect square - m²/4) for every solution
(m, n) of m² - 3n² = 1 with m - even and n - odd.
First and second such non-trivial solutions are (26, 15) and (362, 209); for (2, 1) both triangles coincide of course.