Differentiating Trig Functions
Differentiating Trig Functions Revision
Differentiating Trig Functions
We’re now going to look at how to differentiate the simple trig functions – that’s \textcolor{blue}{\sin}, \textcolor{limegreen}{\cos} and \textcolor{red}{\tan}.
Make sure you are happy with the following topics before continuing.
Simple Trig Results
Below is a diagram showing the derivative and integral of the basic trigonometric functions, \sin x and \cos x.
![](https://mmerevise.co.uk/app/uploads/2021/11/Trig-Int-Circle.png)
General Trig Differentiation
Below is a table of three derivative results.
![](https://mmerevise.co.uk/app/uploads/2021/08/Trig-Diffs-1.png)
Using the Chain Rule with Trig Functions
We can also use the Chain Rule to differentiate more complex trig functions.
For example, say we have f(x) = \textcolor{blue}{\sin} (x^2 - x + 1).
Then we can set \textcolor{red}{u} = x^2 - x + 1 and f(x) = g(\textcolor{red}{u}) = \textcolor{blue}{\sin} \textcolor{red}{u}.
Then \dfrac{d\textcolor{red}{u}}{dx} = 2x - 1 and \dfrac{df(x)}{d\textcolor{red}{u}} = \textcolor{limegreen}{\cos} u.
So,
\dfrac{df(x)}{dx} = (2x - 1)\textcolor{limegreen}{\cos} (x^2 - x + 1)
From First Principles
We can also find the derivatives from first principles.
For example, let f(x) = \textcolor{limegreen}{\cos} x. Then
f'(x) = \lim\limits_{\textcolor{purple}{h} \to 0}\left( \dfrac{\textcolor{limegreen}{\cos} (x + \textcolor{purple}{h}) - \textcolor{limegreen}{\cos} x}{\textcolor{purple}{h}} \right)
= \lim\limits_{\textcolor{purple}{h} \to 0}\left( \dfrac{\textcolor{limegreen}{\cos} x \textcolor{limegreen}{\cos} \textcolor{purple}{h} - \textcolor{blue}{\sin} x \textcolor{blue}{\sin} h - \textcolor{limegreen}{\cos} x}{\textcolor{purple}{h}}\right)
= \lim\limits_{\textcolor{purple}{h} \to 0}\left( \dfrac{\textcolor{limegreen}{\cos} x(\textcolor{limegreen}{\cos} \textcolor{purple}{h} - 1) - \textcolor{blue}{\sin} x \textcolor{blue}{\sin} \textcolor{purple}{h}}{\textcolor{purple}{h}}\right)
Using small angle approximations, we have
f'(x) = \lim\limits_{\textcolor{purple}{h} \to 0}\left( \dfrac{-\dfrac{1}{2}\textcolor{purple}{h}^2 \textcolor{limegreen}{\cos} x - \textcolor{purple}{h}\textcolor{blue}{\sin} x}{\textcolor{purple}{h}}\right)
= \lim\limits_{\textcolor{purple}{h} \to 0}\left( \dfrac{-1}{2}\textcolor{purple}{h}\textcolor{limegreen}{\cos} x - \textcolor{blue}{\sin} x\right)
= -\textcolor{blue}{\sin} x
Differentiating Trig Functions Example Questions
Question 1: Give an expression for \dfrac{dy}{dx} in terms of y, when x = \tan y.
[2 marks]
x = \tan y gives
\dfrac{dx}{dy} = \sec ^2 y
Then \dfrac{dy}{dx} = \cos ^2 y.
Question 2: For \tan x^2, find the derivative with respect to x.
[2 marks]
Let u = x^2 and y = \tan u.
Then
\dfrac{dy}{dx} = 2x \times \sec ^2 u = \dfrac{2x}{\cos ^2 x^2}
Question 3: Prove that the derivative of \sin kx is k\cos kx, using the first principles technique.
[4 marks]
f'(x) = \lim\limits_{h \to 0}\left( \dfrac{\sin (kx + kh) - \sin kx}{h} \right)
= \lim\limits_{h \to 0}\left( \dfrac{\sin kx \cos kh + \sin kh \cos kx - \sin kx}{h}\right)
= \lim\limits_{h \to 0}\left( \dfrac{\sin kx(\cos kh - 1) + \sin kh \cos kx}{h}\right)
Using small angle approximations, we have
f'(x) = \lim\limits_{h \to 0}\left( \dfrac{-\dfrac{1}{2}(kh)^2 \sin kx + kh\cos kx}{h}\right)
= \lim\limits_{h \to 0}\left( \dfrac{-1}{2}kh\sin kx + k\cos kx\right)
= k\cos kx
Differentiating Trig Functions Worksheet and Example Questions
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Differentiation
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