Geometry and Mensuration: Level 3 Test 7

$ \displaystyle \begin{array}{l}Let\,\,R\,\,be\,\,the\,\,radius\,\,of\,\,the\,\,semicircle\,\\Therefore\,\,OC=R=CB\\\sin ce\,\,OCB\,\,is\,a\,\,right\,\,angle\,\,triangle\,\,\\so\,\,OB=R\sqrt{2}\\Now\,\,area\,\,of\,semicircle=\frac{\pi {{r}^{2}}}{2}=\frac{\pi {{R}^{2}}}{2}\\Now\,\,FB=OB-OF=R\sqrt{2}-R=R\left( \sqrt{2}-1 \right)\\therfore\,\,the\,\,area\,\,of\,\,circle=\frac{\pi {{R}^{2}}{{\left( \sqrt{2}-1 \right)}^{2}}}{{{2}^{2}}}\\therfore\,\,the\,\,required\,\,ratio=\frac{\frac{\pi {{R}^{2}}{{\left( \sqrt{2}-1 \right)}^{2}}}{{{2}^{2}}}}{\frac{\pi {{R}^{2}}}{2}}={{\left( \sqrt{2}-1 \right)}^{2}}:2\end{array}$

The actual surface area painted = 2{(11-1)(21-1)+20X5+10X5} = 700 sq. units.
Thus cost per sq. cm =70/700 =0.10 Rs
Correct option is (c)

$ \begin{array}{l}Now\,\,AB=\sqrt{{{\left( x+3 \right)}^{2}}+{{(x-3)}^{2}}}=\sqrt{2({{x}^{2}}+9)}\\BD=\sqrt{100-{{(x-3)}^{2}}}=\sqrt{2\left( {{x}^{2}}+9 \right)}\\BD=\sqrt{100-{{(x-3)}^{2}}}\\thus\\\sqrt{100-(x-3){}^{2}}+x=\sqrt{2({{x}^{2}}+9)}\\Putting\text{ }the\text{ }values\text{ }of\text{ }x\text{ }none\text{ }of\text{ }them\text{ }satisfy\text{ }the\text{ }equation.\\Thus\text{ }the\text{ }correct\text{ }option\text{ }is\text{ }\left( d \right)\end{array}$

$\displaystyle \begin{array}{l}Let\text{ }the\text{ }radius\text{ }be\text{ }r\text{ }and\text{ }the\text{ }center\text{ }be\text{ }0,0\\Now\text{ }since\text{ }between\text{ }the\text{ }point\text{ }from\text{ }where\text{ }it\text{ }can\text{ }be\text{ }just\text{ }seen\text{ }\left( -9,-r \right)\\\sqrt{6r+9}+9=\sqrt{{{(2r+3)}^{2}}+{{9}^{2}}}\\By\,\,putting\,the\,\,values\,\,only\,\,b\,\,satisfies\end{array}$

Opening up the cylinder into a rectangle we can see that the
string is wound to a height of h with equal vertical spacing for n times.
Thus the distance = h/n
Correct option is (a)