Advertisements
Advertisements
प्रश्न
Find the derivative of the following function (it is to be understood that a, b, c, d, p, q, r and s are fixed non-zero constants and m and n are integers):
(ax + b)n (cx + d)m
Advertisements
उत्तर
Let f(x) = (ax + b)n (cx + d)m
By Leibnitz product rule,
f'(x) = `(ax + b)^n d/dx (cx + d)^m + (cx + d)^m d/dx (ax + b)^n` ...(1)
Now, let f1(x) = (cx + d)m
f1(x + h) = (cx + ch + d)m
f1(x) = `lim_(h->0)(f_1(x + h) - f_1(x))/h`
= `lim_(h->0) ((cx + ch + d)^m - (cx + d)^n)/h`
= `(cx + d)^m lim_(h-0)1/h [(1 + (ch)/(cx + d))^m - 1]`
= `(cx + d)^m lim_(h-0) 1/h[(1 + (mch)/(cx + d) + (m(m - 1))/2 ((c^2h^2))/(cx + d)^2 + ...) -1]`
= `(cx + d)^m lim_(h->0) 1/h [(mch)/(cx + d) + (m(m - 1)c^2h^2)/(2(cx + d)^2) + ...("Terms containing higher degrees of h")]`
= `(cx + d)^m lim_(h->0) [(mc)/(cx + d) + (m(m - 1)c^2h)/(2(cx + d)^2 + ...]]`
= `(cx + d)^m [(mc)/(cx + d) + 0]`
= `(mc(cx + d)^m)/(cx + d)`
= mc (cx + d)m - 1
`d/dx (cx + d)^m` = mc (cx + d)m - 1 .....(2)
Similarly, `d/dx (ax + b)^n` = na (ax + b)n - 1 ...(3)
Therefore, from (1), (2), and (3), we obtain
f(x) = (ax + b)n {mc(cx + d)m - 1} + (cx + d)m {na (ax + b)n - 1}
= (ax + b)n - 1 (cx + d)m - 1 [mc (ax + b) + na (cx + d)]
APPEARS IN
संबंधित प्रश्न
Find the derivative of x2 – 2 at x = 10.
Find the derivative of x–3 (5 + 3x).
Find the derivative of x5 (3 – 6x–9).
Find the derivative of the following function (it is to be understood that a, b, c, d, p, q, r and s are fixed non-zero constants and m and n are integers):
`(ax + b)/(cx + d)`
Find the derivative of the following function (it is to be understood that a, b, c, d, p, q, r and s are fixed non-zero constants and m and n are integers):
`(1 + 1/x)/(1- 1/x)`
Find the derivative of the following function (it is to be understood that a, b, c, d, p, q, r and s are fixed non-zero constants and m and n are integers):
x4 (5 sin x – 3 cos x)
Find the derivative of f (x) x at x = 1
Find the derivative of f (x) = cos x at x = 0
Find the derivative of the following function at the indicated point:
2 cos x at x =\[\frac{\pi}{2}\]
x2 + x + 3
(x2 + 1) (x − 5)
Differentiate of the following from first principle:
− x
Differentiate of the following from first principle:
sin (x + 1)
Differentiate of the following from first principle:
sin (2x − 3)
Differentiate each of the following from first principle:
\[a^\sqrt{x}\]
\[\sin \sqrt{2x}\]
\[\tan \sqrt{x}\]
\[\frac{x^3}{3} - 2\sqrt{x} + \frac{5}{x^2}\]
log3 x + 3 loge x + 2 tan x
\[\frac{(x + 5)(2 x^2 - 1)}{x}\]
\[\text{ If } y = \left( \sin\frac{x}{2} + \cos\frac{x}{2} \right)^2 , \text{ find } \frac{dy}{dx} at x = \frac{\pi}{6} .\]
For the function \[f(x) = \frac{x^{100}}{100} + \frac{x^{99}}{99} + . . . + \frac{x^2}{2} + x + 1 .\]
sin x cos x
\[\frac{2^x \cot x}{\sqrt{x}}\]
logx2 x
Differentiate each of the following functions by the product rule and the other method and verify that answer from both the methods is the same.
(x + 2) (x + 3)
Differentiate each of the following functions by the product rule and the other method and verify that answer from both the methods is the same.
(3 sec x − 4 cosec x) (−2 sin x + 5 cos x)
\[\frac{x^2 + 1}{x + 1}\]
\[\frac{e^x + \sin x}{1 + \log x}\]
\[\frac{p x^2 + qx + r}{ax + b}\]
\[\frac{x}{\sin^n x}\]
\[\frac{1}{a x^2 + bx + c}\]
Write the value of \[\lim_{x \to c} \frac{f(x) - f(c)}{x - c}\]
Write the value of \[\lim_{x \to a} \frac{x f (a) - a f (x)}{x - a}\]
Write the value of \[\frac{d}{dx} \left\{ \left( x + \left| x \right| \right) \left| x \right| \right\}\]
Write the value of \[\frac{d}{dx}\left( \log \left| x \right| \right)\]
