Differentiate:
y = (f(x))^n
when f(x) contains multiple terms
(The Chain Rule)
dy/dx = n x f’(x) x (f(x))^(n-1)
Differentiate:
y = e^f(x)
dy/dx = f’(x)e^f(x)
Differentiate:
y = a^x
when a does not equal 1
dy/dx = ln(a) x a^x
Differentiate:
y = ln(kx)
dy/dx = 1/x
Diffentiate:
y = ln(f(x))
dy/dx = f’(x) / f(x)
Differentiate:
y = sin(kx)
dy/dx= kcos(kx)
Differentiate:
y = cos(kx)
dy/dx= -ksin(kx)
Differentiate:
y = tan(kx)
dy/dx = ksec^2(kx)
Differentiate
y = u x v
(Product Rule)
dy/dx = u x dv/dx + v x du/dx
Differentiate:
y = u/v
(Quotient Rule)
dy/dx = ((v x du/dx)-(u x dv/dx)) / v^2
dx/dy =
= 1/ (dy/dx)
(and vice versa)
Implicit Differentiation
when differentiating y^(n) with respects to x, you get….
ny^(n-1) x dy/dx
(NEVER USE THE QUOTIENT RULE DURING IMPLICIT DIFFERENTIATION)
Differentiate:
y= a^f(x)
dy/dx = ln(a) x a^f(x) x f’(x)
Concave curve
d2y/dx2 < 0
As gradient is decreasing
Convex Curve
d2y/dx2 >0
As gradient is increasing
Draw:
A concave curve
Refer to notes for answers
Draw:
A convex curve
Refer to notes for answers
Differentiate
sinx using first principles
refer to notes for answers
Differentiate
cosx using first principles
Refer to notes for answer
