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Question
Find the minimum value of (ax + by), where xy = c2.
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Solution 1
Let z = ax + by ...(1)
Given:
xy = c2 or \[y = \frac{c^2}{x}\]
Putting
\[y = \frac{c^2}{x}\] in (1), we get
z = ax + \[\frac{b c^2}{x}\]
Differentiating both sides w.r.t. x, we get
\[\frac{dz}{dx} = a - \frac{b c^2}{x^2}\]
For maxima or minima,
\[\frac{dz}{dx} = 0\]
⇒ \[a - \frac{b c^2}{x^2} = 0\]
⇒ \[x^2 = \frac{b c^2}{a}\]
⇒ \[x = \pm c\sqrt{\frac{b}{a}}\]
Now,
\[\frac{d^2 z}{d x^2} = \frac{2b c^2}{x^3}\]
At \[x = c\sqrt{\frac{b}{a}}\], \[\frac{d^2 z}{d x^2} = \frac{2b c^2}{\left( c\sqrt{\frac{b}{a}} \right)^3} > 0\]
\[\therefore x = c\sqrt{\frac{b}{a}}\] is the point of minima.
At \[x = - c\sqrt{\frac{b}{a}}\], \[\frac{d^2 z}{d x^2} = \frac{2b c^2}{\left( - c\sqrt{\frac{b}{a}} \right)^3} < 0\]
\[\therefore x = - c\sqrt{\frac{b}{a}}\] is the point of maxima.
So,
When \[x = c\sqrt{\frac{b}{a}}\], \[y = \frac{c^2}{x} = \frac{c^2}{c\sqrt{\frac{b}{a}}} = c\sqrt{\frac{a}{b}}\]
\[\therefore z_{\text { minimum}} = ac\sqrt{\frac{b}{a}} + bc\sqrt{\frac{a}{b}} = \frac{abc + abc}{\sqrt{ab}} = \frac{2abc}{\sqrt{ab}} = 2c\sqrt{ab}\]
Thus, the minimum value of (ax + by), where xy = c2 is \[2c\sqrt{ab}\].
Solution 2
Given that xy = c2
`y = c^2/x` ...(i)
Now, suppose S = ax + by
⇒ `S = ax + b xx c^2/x` ...[From (i)]
⇒ `"dS"/"dx" = a - (bc^2)/x^2`
For local points of maxima or minima
⇒ `"dS"/"dx" = 0`
⇒ `a - (bc^2)/x^2 = 0`
⇒ `x = - c sqrt(b/a)`
Also, ``
`(d^2S)/(dx^2)]_("at" x = csqrt(b/a)) = (2bc^2)/(c^3(b/a)^(3//2)) > 0`
∴ S = ax + by is minimum at `x = csqrt(b/a)`
⇒ Minimum value of `S = a xx csqrt(b/a) + b xx c^2/(csqrt(b/a))`
= `csqrt(ab) + csqrt(ab)`
= `2csqrt(ab)`
∴ Minimum value of ax + by, where xy = c2 is `2csqrt(ab)`.
