What is the maximum area of a rectangle that can be circumscribed about a given rectangle with length L and width W?

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What is the maximum area of a rectangle that can be circumscribed about a given rectangle with length L and width W?

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Answer 1 · 2017-02-05T21:28:32

$1/2(L+W)^2$

Explanation:

Let us set up a concrete scenario...

Start with a rectangle with vertices:

$(L/2, W/2)$

$(-L/2, W/2)$

$(-L/2, -W/2)$

$(L/2, -W/2)$

Rotate it anticlockwise about the origin by $theta$ to give a rectangle with vertices:

$(L/2 cos theta - W/2 sin theta, W/2 cos theta + L/2 sin theta)$

$(-L/2 cos theta - W/2 sin theta, W/2 cos theta - L/2 sin theta)$

$(-L/2 cos theta + W/2 sin theta, -W/2 cos theta - L/2 sin theta)$

$(L/2 cos theta + W/2 sin theta, -W/2 cos theta + L/2 sin theta)$

(For simplicity, just consider $0 <= theta <= pi/2$ so we don't have to be concerned about a variety of cases, etc.)

Then the circumscribing rectangle with sides parallel to the $x$ and $y$ axes has area:

$(L cos theta + W sin theta)(W cos theta + L sin theta) = (L^2+W^2)cos theta sin theta+WL$

$color(white)((L cos theta + W sin theta)(W cos theta + L sin theta)) = 1/2(L^2+W^2)sin 2theta+WL$

This takes its maximum value when $sin 2theta = 1$ , e.g. when $theta = pi/4$

So the maximum area is:

$WL+1/2(L^2+W^2) = 1/2(L+W)^2$

Unsurprisingly, this is when the circumscribing rectangle is a square.

Answer 2 · 2017-02-06T00:29:26

$1/2(L+ W)^2$

Explanation:

Now using the Lagrange Multipliers technique.

enter image source here

The circumscribed rectangle has the side dimensions

$(a+b)$ and $(c+d)$ so the sough area is $(a+b)(c+d)$

The restrictions are

$a^2+b^2=L^2$ and
$c^2+d^2=W^2$

The lagrangian is

$Phi(a,b,c,d,lambda_1,lambda_2)=(a+b)(c+d)+lambda_1(a^2+b^2-L^2)+lambda_2(c^2+d^2-W^2)$

The stationary points are the solutions of

$grad Phi=(Phi_a,Phi_b,Phi_c,Phi_d,Phi_(lambda_1),Phi_(lambda_2))=0$

or

${(c + d + 2 a lambda_1=0),(c + d + 2 blambda_2=0),(a + b + 2 c lambda_2=0),(a + b + 2 d lambda_1=0),(a^2 + d^2 - L^2=0),(b^2 + c^2 - W^2=0):}$

Solving for $a,b,c,d,lambda_1,lambda_2$ we get at

$((a=L/sqrt[2]),(b=W/sqrt[2]),(c=W/sqrt[2]),(d=L/sqrt[2]),(lambda_1=-(L +W)/(2 L)),(lambda_1=-(L +W)/(2 W)))$

and the maximum area is

$(a+b)(c+d)=1/2(L+ W)^2$

Of course the minimum area circumscribing rectangle has the area $L cdot W$

Answer 3 · 2017-02-06T04:22:22

$1/2(L+W)^2$

Explanation:

And now with rotations.

enter image source here

The circumscribed quadrilateral area is given by

$A(theta)=2(1/2(Wsintheta)(Wcostheta)+1/2(Lsintheta)(Lcostheta))+LW$

so

$A(theta)=(W^2+L^2)sintheta costheta+LW$

Now the maximum is at the solution of

$(dA)/(d theta) = (W^2+L^2)(1-2sin^2theta)=0$

giving $theta={-3pi/4,-pi/4,pi/4,3pi/4}$ . Between those solutions we will choose the maximum. The local maxima are located at points in which $(d^2A)/(d theta^2) < 0$

so the solution is for $theta=pi/4$ or $theta=-3pi/4$

$A(pi/4)=(W^2+L^2)(1/sqrt(2))^2+LW=1/2(L+W)^2$

because at this point

$(d^2A)/(d theta^2)=-4(W^2+L^2)costheta sintheta=-2(W^2+L^2)<0$

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What is the maximum area of a rectangle that can be circumscribed about a given rectangle with length L and width W?

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