Mathematics desk
< December 20	<< Nov \| December \| Jan >>	Current desk >

Welcome to the Wikipedia Mathematics Reference Desk Archives
The page you are currently viewing is a transcluded archive page. While you can leave answers for any questions shown below, please ask new questions on one of the current reference desk pages.

December 21[edit]

Calculate distance between centers of circles given area of intersections[edit]

I need help checking my work. I'm working on a representation of multiple regression effect sizes using a Venn Diagram for educational policy research. I see that the area of a geometric lens has a closed form solution. Given a Venn diagram made from circles $A$ , $B$ , and $C$ with centers $X$ , $Y$ , and $Z$ , that $r=R={\sqrt {1/\pi }}$ , and $A_{A\cap B}=0.23$ , then $d_{XY}\approx 0.429$ . Can someone validate this? The Venn diagram is represented at this link here.Schyler (exquirito veritatem bonumque) 04:07, 21 December 2022 (UTC)[reply]

Circle

C

has no role. I cannot replicate these numbers. When each circle passes through the centre of the other circle, so the circle centres are

r\approx 0.56419

apart, a rhombus of two equilateral triangles fits within the lens. The area of this rhombus is

{\tfrac {\sqrt {3}}{2\pi }}\approx 0.27566,

so when

d_{XY}=0.429<r

,

A_{A\cap B}>0.27566,

contradicting

A_{A\cap B}\approx 0.23\,.

My calculations give me that distance

d_{XY}=0.429

gets you

A_{A\cap B}\approx 0.52785\,.

Conversely, to get lens area

A_{A\cap B}=0.23\,,

I find we need

d_{XY}\approx 0.73938\,.

--Lambiam 07:38, 21 December 2022 (UTC)[reply]

Yes, circle

C

has no role. Let

\theta

be the angle at X (or Y) between the lines to the junctions of ABD and of CEFG. The lens has area

A=R^{2}\left(\theta -\sin \theta \right)

, where

R={\sqrt {1/\pi }}

, and the diagram says

A_{A\cap B}

(D+G) has area 0.03, so

\theta -\sin \theta =0.03\pi

. That gives

\theta \approx 0.8235

(in radians). The length from X (or Y) to the midpoint of XY is

R\cos(\theta /2)

, and twice this gives

d_{XY}\approx 1.0341

. My trig is rusty and I may have made some errors, but I think the principle and the order of magnitude are right. If

A_{A\cap B}

were 0.23, we'd get

\theta \approx 1.1377

and

d_{XY}\approx 0.9507

. Certes (talk) 13:31, 21 December 2022 (UTC)[reply]

For

\theta =0.8235,

we have

(\theta -\sin \theta )/\pi \approx 0.02864,

not quite

0.03

but at least in the ballpark. But in the second case, you missed a factor

\pi

: for

\theta =1.1377,

we have

\theta -\sin \theta \approx 0.23

while

(\theta -\sin \theta )/\pi \approx 0.07322.

--Lambiam 15:52, 21 December 2022 (UTC)[reply]

Here are the calculations for lens area

0.23,

step by step:

{\begin{array}{cccc}\theta &=&1.71254\\\sin \theta &=&\sin 1.71254&\approx &0.98997\\\theta -\sin \theta &\approx &1.71254-0.98997&\approx &0.72257\\(\theta -\sin \theta )/\pi &\approx &0.72257/3.14159&\approx &0.23000\\\cos(\theta /2)&\approx &\cos 0.85627&\approx &0.65526\\2R\cos(\theta /2)&\approx &2\times 0.56419\times 0.65526&\approx &0.73938\\\end{array}}

--Lambiam 16:03, 21 December 2022 (UTC)[reply]

Oops. Thanks, that looks more credible. Certes (talk) 18:40, 21 December 2022 (UTC)[reply]

Okay, well this is interesting. Yes, in the example, circle C has no role here. Someone said "When each circle passes through the centre of the other circle," but I do not think that is probable. Here were my steps:

Circles $A$ , $B$ , and $C$ have centers $X$ , $Y$ , and $Z$ and radii $r_{A}=r_{B}=r_{C}={\sqrt {1/\pi }}$ . The centers form $\triangle XYZ$ and intersect such that $Area_{A\cap B}=0.03$ , $Area_{B\cap C}=0.11$ , $Area_{A\cap C}=0.23$

$d_{1}={\overline {\rm {XY}}};d_{2}={\overline {\rm {XZ}}};d_{3}={\overline {\rm {YZ}}}$

$Area_{A\cap C}=r_{A}^{2}\cos ^{-1}({\frac {d_{1}^{2}+r_{A}^{2}-r_{C}^{2}}{2d_{1}r_{A}}})+r_{C}^{2}\cos ^{-1}({\frac {d_{1}^{2}+r_{C}^{2}-r_{A}^{2}}{2d_{1}r_{C}}})-2\Delta$

$\Delta ={\frac {1}{4}}{\sqrt {(-d_{1}+r_{A}+r_{B})(d_{1}-r_{A}+r_{B})(d_{1}+r_{A}-r_{B})(d_{1}+r_{A}+r_{B})}}$

Simplifying:

${\cancel {0.23=2({\frac {1}{\pi }}\cos ^{-1}({\frac {d_{1}^{2}}{2d_{1}{\sqrt {\frac {1}{\pi }}}}}))-{\frac {1}{2}}{\sqrt {(-d_{1}+2{\frac {1}{\pi }})(d_{1}+2{\frac {1}{\pi }})}}}}$

oh I see this was my problem, I think... I distributed the 2 onto ${\frac {1}{4}}\Delta$

${\cancel {0.23=2({\frac {1}{\pi }}\cos ^{-1}({\frac {d_{1}^{2}}{2d_{1}{\sqrt {\frac {1}{\pi }}}}}))-{\frac {1}{4}}{\sqrt {(-d_{1}+2{\frac {1}{\pi }})(d_{1}+2{\frac {1}{\pi }})}}}}$

Update: well, here i am checking my own work again. i found another error. i deleted some values of d within $\Delta$ . I should know better than to ask for help right away... i can do this... but the doubt is strong in this one

${\cancel {0.23=2({\frac {1}{\pi }}\cos ^{-1}({\frac {d_{1}^{2}}{2d_{1}{\sqrt {\frac {1}{\pi }}}}}))-{\frac {1}{4}}{\sqrt {(-d_{1}+2{\frac {1}{\pi }})(d_{1}+2{\frac {1}{\pi }})}}}}$

no that's wrong too, $r={\sqrt {\frac {1}{\pi }}}$ ... i got it mixed up in $\Delta$ again...

You can shift two equal-sized circles such that each passes through the other's centre; I used this special case merely to easily establish bounds that were violated by a purported solution.

The function

f(\theta )=(\theta -\sin \theta )/\pi

is transcendental, and one cannot hope to solve the equation

f(\theta )=x

by a combination of algebraic and trigonometric manipulations for rational values of

x,

except when

x

is an integer, in which case the equation is solved by

\theta =x\pi .

--Lambiam 09:01, 22 December 2022 (UTC)[reply]