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Question
Find two numbers whose sum is 15 and when the square of one number multiplied by the cube of the other is maximum.
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Solution
Let the two numbers be x and y.
Then x + y = 15
∴ y = 15 − x
Let P is the product of square of y and cube of x.
Then P = x3y2
∴ P = x3(15 − x)2
∴ P = x3(225 − 30x + x2)
∴ P = x5 − 30x4 + 225x3
∴ `(dP)/(dx) = (d)/(dx) (x^5 − 30x^4 + 225x^3)`
∴ `(dP)/(dx) = 5x^4 − 30 × 4x^3 + 225 × 3x^2`
∴ `(dp)/(dx) = 5x^4 − 120x^3 + 675x^2`
and `(d^2P)/(dx^2) = (d)/(dx)(5x^4 - 120x^3 + 675x^2)`
`(d^2P)/(dx^2) = 5 xx 4x^3 - 120 xx 3x^2 + 675 xx 2x`
`(d^2P)/(dx^2) = 20x^3 - 360x^2 + 1350x`
`(d^2P)/(dx^2) = 10x(2x^2 - 36x + 135)`
Now, `(dP)/(dx)` = 0 gives 5x4 − 120x3 + 675x2 = 0
∴ 5x2(x2 − 24x + 135) = 0
∴ 5x2(x2 − 15x − 9x + 135) = 0
∴ 5x2[x(x − 15) − 9(x − 15)] = 0
∴ 5x2(x − 15)(x − 9) = 0
∴ The roots of `(dP)/(dx)` = 0 are x1 = 0, x2 = 15 and x3 = 9
If x = 0, then y = 15 − 0 = 15
If x = 15, then y = 15 − 15 = 0
In both the cases product x3y2 are zero, which is not maximum.
∴ x ≠ 0 and x ≠ 15
∴ x = 6
Now, `((d^2P)/(dx^2))_("at x = 6")` = 10(6)[2(6)2 − 36 × 6 + 135]
= 60[72 − 216 + 135]
= 60(− 9)
= − 540 < 0
∴ P is maximum when x = 6
If x = 6, then y = 15 − 6 = 9
Hence, the required numbers are 6 and 9.
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