A cylindrical tank of radius R and height H must be redesign

ans is E
volume of cylinder=pi*r^2*H
=>reqd multiplication factor is 2
=>any change in R will cause volume to be multiplied by "square of (1+/- change in fractions)"
=>any change in H will cause vol to b multiplied by (1+/-change)
1. a 100% increase in R and a 50% decrease in H=>4*.5=2=>as required
2. a 30% decrease in R and a 300% increase in H=>.49*4=1.96
3. a 10% decrease in R and a 150% increase in H=>.81*2.5=2.025
4. a 40% increase in R and no change in H=>1.96
5. a 50% increase in R and a 20% decrease in H=>1.8=>max difference from required multiplication factor of 2



very easy qs...but my method took like 3 minutes....anyone with a faster solution?

easy but time consuming...ny 1 with any easy method??

Can any body explain it geometrically.
Thanks

"Farthest from the new design requirement" denotes highest difference between "twice the volume" (- the actual requirement) and volume given by each of the answer choices (- the new design requirement). Actual required volume is 2*pi*r^2*h.
We need to calculate 2 metrics for each answer choice:
1) Volume of each of the new design requirements and
2) Difference from actual required volume (2*pi*r^2*h)
A)
Volume of new design = pi*(2r)^2 * (.50h) = 2*pi*r^2*h
Difference = 2*pi*r^2*h ~ 2*pi*r^2*h = 0
B)
Volume of new design = pi*(.7r)^2 * (4h) = 1.96 *pi*r^2*h
Difference = 1.96 *pi*r^2*h ~ 2*pi*r^2*h = 0.04 *pi*r^2*h
C)
Volume of new design = pi*(1.4r)^2 * (h) = 2.025*pi*r^2*h
Difference = 2.025*pi*r^2*h ~ 2*pi*r^2*h = 0.025 *pi*r^2*h
D)
Volume of new design = pi*(.9r)^2 * (2.5h) = 1.96*pi*r^2*h
Difference = 1.96 *pi*r^2*h ~ 2*pi*r^2*h = 0.04 *pi*r^2*h
E)
Volume of new design = pi*(1.5r)^2 * (.8h) = 1.8*pi*r^2*h
Difference = 1.8*pi*r^2*h ~ 2*pi*r^2*h = 0.2 *pi*r^2*h

Therefore, the largest difference (farthest design) is 0.2. so the correct choice is E.

Also, we can follow the below technique for finding the percentage increase in volume/area.
Say if side of a square increased by 10%. The new area is (1.1*side)^2 = 1.21 (side)^2 = 1.21(Old Volume). Therefore volume increased by 21%.

Similarly, for this question, we can just multiply the numeric part before radius^2 and height after applying appropriate % increase/decrease.
The old volume is pi * r^2 *h. And the required volume is 2*pi * r^2 *h.
Working out option E -> If radius increased by 50% and height decreased by 20%, then new volume = (1.5)^2 * (.80) (Old Volume)=1.8(Old Volume). Whereas required volume is 2*(Old Volume). Hence new design is .2 farther from required design.

Karishma, I took R=10 and H=10 and proceeded but I am unable to arrive at a constructive answer. Can you please explain how to proceed using the above values and using substitution method. Thanks in advance .

R = 10
H = 10

We know volume of a cylinder\(= \pi * r^2 * h = 1000\pi\)

A. A 100% increase in R and a 50% decrease in H (R = 20, H = 5)
Volume =\(\pi * 400 * 5 = 2000\pi\)(matches the design requirement)

B. A 30% decrease in R and a 300% increase in H (R = 7, H = 40)
Volume =\(\pi * 49 * 40 = 1960\pi\) (approximately matches the design requirement)
Note that 49 is approximately 50


C. A 10% decrease in R and a 150% increase in H (R = 9, H = 25)
Volume\(= \pi * 81 * 25 = 2025\pi\) (approximately matches the design requirement)
Notice that 81 is approximately 80

D. A 40% increase in R and no change in H (R = 14)
Volume\(= \pi * 196 * 10 = 1960 \pi\) (approximately matches the design requirement)

E. A 50% increase in R and a 20% decrease in H (R = 15, H = 8)
Volume \(= \pi * 225 * 8 = 1800\pi\) (Does not match)

Can't you just use the formula, and multiply it pretty quickly? Took me less than 2 minutes if you just use the percentage increases.

A) 100% increase to R = 2R and 50% decrease to H = .5 H so formula is pi*r^2*h
so 2^2*.5=2

Repeat with each solution and you get E at 1.8.

This worked for me, but is this correct?

Let the radius be 1 and the height be 2- now, the algebraic translation of twice the volume would be

2( (pi)(r)^2(h))
2( (pi)(1)^2(2))

We could simply construct an equation for each of the answer choices- for example

pi * 2(1)^2 (h-1/2h)

Eventually we would be able to arrive at the answer. Bunuel is there a quicker method- perhaps I am not reading into some of the other answers deeply enough- but it seems too time-consuming and inefficient to construct an equation for each answer choice and calculate which has an answer choice has a volume furthest away from the volume of twice the original cylinder's volume- is there a more efficient way of solving this problem?

Life saver, right here! I almost postponed this one for later. Thanks a lot!

It is similar to an "except" question on CR....didn't read the word "farthest" and instead marked A without going through all options!

I should not rush!

Thank you it makes a lot more sense now. We can just look for the change is radius and height and find our answer.

Just wondering here, why does multiplying r by \sqrt{2} qualify as doubling the volume?

A trivial question as well: For A), why does 100% increase in the radius amount to multiplying by 4?

Both of your questions revolve around what happens to a value that multiplied by r in this equation (i.e. is an exponent question).

For anyone who sees this later on. Multipying r by \sqrt{2} qualifies as doubling the volume because, as mentioned above, anything that changes the value of r will be squared. So, \(\sqrt{2}\)
, squared, is equal to 2. This then would mean then that the volume of the cylindrical tank would double. (i.e. \(2 * pi * h* r^2\) = a doubled cylindrical volume)

As for the question about A), this is a similar question to your first one. Anything that r is multipled by in this equation will be squared. A 100% increase of R is equal to \(2 * r\), therefore \(2^2\) will be equal to 4.

Given: A cylindrical tank of radius R and height H must be redesigned to hold approximately twice as much liquid.

Asked: Which of the following changes would be farthest from the new design requirements?

Volume of a cylindrical tank = \(\pi Rˆ2 H\)
Let us take new radius = k * old radius = kR
& new height = m * old height = mH

New Volume of the cylindrical tank = \(\pi kˆ2 Rˆ2 mH = kˆ2m \)

A. A 100% increase in R and a 50% decrease in H; k = 2; m = .5; kˆ2m = 2; No deviation
B. A 30% decrease in R and a 300% increase in H; k = .7; m = 4; kˆ2m = .7ˆ2*4 = .49*4 = 1.96; Deviation = .04/2 = 2%
C. A 10% decrease in R and a 150% increase in H; k = .9; m = 2.5; kˆ2m = .9ˆ2*2.5 = .81*2.5 = 2.025; Deviation = .025/2 = 1.25%
D. A 40% increase in R and no change in H; k = 1.4; m = 1; kˆ2m = 1.4ˆ2 = 1.96; Deviation = .04/2 = 2%
E. A 50% increase in R and a 20% decrease in H; k = 1.5; m = .8; kˆ2m = 1.5ˆ2*.8 = 1.8; Deviation = .2/2 = 10%

IMO E

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