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6.2 Trigonometric identities

6.2 Trigonometric identities (EMBHH)

An identity is a mathematical statement that equates one quantity with another. Trigonometric identities allow us to simplify a given expression so that it contains sine and cosine ratios only. This enables us to solve equations and also to prove other identities.

Quotient identity

Quotient identity

  1. Complete the table without using a calculator, leaving your answer in surd form where applicable:

    \(\theta = \text{45}\text{°}\) 077eb8d03c8aefeafbcbd6c81f77f3e7.png b70b3e9cda1573734f2b43e96649a1e5.png
    \(\sin \theta\)
    \(\cos \theta\)
    \(\dfrac{\sin \theta}{\cos \theta}\)
    \(\tan \theta\)
  2. Examine the last two rows of the table and make a conjecture.
  3. Are there any values of \(\theta\) for which your conjecture would not be true? Explain your answer.

We know that \(\tan \theta\) is defined as:

\[\tan \theta = \frac{\text{opposite side}}{\text{adjacent side}}\]

Using the diagram below and the theorem of Pythagoras, we can write the tangent function in terms of \(x, y\) and \(r\):

400947466fb909fba071d4da223113f3.png

This is the quotient identity:

\[\tan \theta = \frac{\sin \theta}{\cos \theta}\]

Notice that \(\tan \theta\) is undefined if \(\cos \theta = 0\), therefore \(\theta \ne k \times \text{90}\text{°}\), where \(k\) is an odd integer.

e4b73e2acc57bcd0d61aaad59d8f885b.png

Square identity

Square identity

  1. Use a calculator to complete the following table:

    \(\sin^2 \text{80}\text{°} + \cos^2 \text{80}\text{°} =\)
    \(\cos^2 \text{23}\text{°} + \sin^2 \text{23}\text{°} =\)
    \(\sin \text{50}\text{°} + \cos \text{50}\text{°} =\)
    \(\sin^2 \text{67}\text{°} - \cos^2 \text{67}\text{°} =\)
    \(\sin^2 \text{67}\text{°} + \cos^2 \text{67}\text{°} =\)
  2. What do you notice? Make a conjecture.
  3. Draw a sketch and prove your conjecture in general terms, using \(x, y\) and \(r\).
fd119d00261f854d6bd9b56994762e6e.png

Using the theorem of Pythagoras, we can write the sine and cosine functions in terms of \(x, y\) and \(r\):

\begin{align*} \sin^2 \theta + \cos^2 \theta &= \left( \frac{y}{r} \right)^2 + \left( \frac{x}{r} \right)^2 \\ &= \frac{y^2}{r^2} + \frac{x^2}{r^2} \\ &= \frac{y^2 + x^2}{r^2} \\ &= \frac{r^2}{r^2} \\ &= 1 \end{align*}

This is the square identity:

\[\sin^2 \theta + \cos^2 \theta = 1\]

Other forms of the square identity

Complete the following:

  1. \(\sin^2 \theta = 1 - \ldots\ldots\)
  2. \(\cos \theta = \pm \sqrt{\ldots\ldots}\)
  3. \(\sin^2 \theta = (1 + \ldots\ldots)(1 - \ldots\ldots)\)
  4. \(\cos^2 \theta - 1 = \ldots\ldots\)

Here are some useful tips for proving identities:

  • Change all trigonometric ratios to sine and cosine.
  • Choose one side of the equation to simplify and show that it is equal to the other side.
  • Usually it is better to choose the more complicated side to simplify.
  • Sometimes we need to simplify both sides of the equation to show that they are equal.
  • A square root sign often indicates that we need to use the square identity.
  • We can also add to the expression to make simplifying easier:
    • replace \(\text{1}\) with \(\sin^2 \theta + \cos^2 \theta\).
    • multiply by \(\text{1}\) in the form of a suitable fraction, for example \(\dfrac{1 + \sin \theta}{1 + \sin \theta}\).
temp text

Worked example 5: Trigonometric identities

Simplify the following:

  1. \(\tan^2 \theta \times \cos^2 \theta\)
  2. \(\dfrac{1}{\cos^2 \theta} - \tan^2 \theta\)

Write the expression in terms of sine and cosine only

We use the square and quotient identities to write the given expression in terms of sine and cosine and then simplify as far as possible.

  1. \begin{align*} \tan^2 \theta \times \cos^2 \theta &= \left( \frac{\sin \theta}{\cos \theta} \right)^2 \times \cos^2 \theta \\ &= \frac{\sin^2 \theta}{\cos^2 \theta} \times \cos^2 \theta \\ &= \sin^2 \theta \end{align*}
  2. \begin{align*} \frac{1}{\cos^2 \theta} - \tan^2 \theta &= \frac{1}{\cos^2 \theta} - \left( \frac{\sin \theta}{\cos \theta} \right)^2 \\ &= \frac{1}{\cos^2 \theta} - \frac{\sin^2 \theta}{\cos^2 \theta} \\ &= \frac{1 - \sin^2 \theta}{\cos^2 \theta} \\ &= \frac{\cos^2 \theta}{\cos^2 \theta} \\ &= 1 \end{align*}

Worked example 6: Trigonometric identities

Prove: \(\dfrac{1 - \sin \alpha}{\cos \alpha} = \dfrac{\cos \alpha}{1 + \sin \alpha}\)

Note restrictions

When working with fractions, we must be careful that the denominator does not equal \(\text{0}\). Therefore \(\cos \theta \ne 0\) for the fraction on the left-hand side and \(\sin \theta + 1 \ne 0\) for the fraction on the right-hand side.

Simplify the left-hand side

This is not an equation that needs to be solved. We are required to show that one side of the equation is equal to the other. We can choose either of the two sides to simplify.

\begin{align*} \text{LHS} &= \frac{1 - \sin \alpha}{\cos \alpha} \\ &= \frac{1 - \sin \alpha}{\cos \alpha} \times \frac{1 + \sin \alpha}{1 + \sin \alpha} \end{align*}

Notice that we have not changed the equation — this is the same as multiplying by \(\text{1}\) since the numerator and the denominator are the same.

Determine the lowest common denominator and simplify

\begin{align*} \text{LHS} &= \frac{1 - \sin^2 \alpha}{\cos \alpha(1 + \sin \alpha)} \\ &= \frac{\cos^2 \alpha}{\cos \alpha(1 + \sin \alpha)} \\ &= \frac{\cos \alpha}{1 + \sin \alpha} \\ &= \text{RHS} \end{align*}

Trigonometric identities

Textbook Exercise 6.2

Reduce the following to one trigonometric ratio:

\(\dfrac{\sin\alpha}{\tan\alpha}\)

\begin{align*} \dfrac{\sin\alpha}{\tan\alpha} &= \dfrac{\sin\alpha}{\tan\alpha} \\ &= \dfrac{\sin\alpha}{\dfrac{\sin\alpha}{\cos\alpha}} \\ &= \sin\alpha \times \dfrac{\cos\alpha}{\sin\alpha} \\ &= \cos\alpha \end{align*}

\(\cos^2 \theta \tan^2 \theta + \tan^2 \theta \sin^2 \theta\)

\begin{align*} \cos^2 \theta \tan^2 \theta + \tan^2 \theta \sin^2 \theta &= \tan^2 \theta \left( \cos^2 \theta + \sin^2 \theta \right) \\ &= \tan^2 \theta \left( 1 \right) \\ &= \tan^2 \theta \end{align*}

\(1-\sin \theta \cos \theta \tan \theta\)

\begin{align*} 1-\sin \theta \cos \theta \tan \theta &= 1-\sin \theta \cos \theta \left( \frac{\sin\theta}{\cos\theta} \right) \\ &= 1-\sin^2 \theta \\ &= \cos^2 \theta \end{align*}

\(\left( \dfrac{1 - \cos^2\beta}{\cos^2 \beta}\right) - \tan^2 \beta\)

\begin{align*} \left( \dfrac{1 - \cos^2\beta}{\cos^2 \beta}\right) - \tan^2 \beta &= \left( \dfrac{\sin^2\beta}{\cos^2 \beta}\right) - \tan^2 \beta \\ &= \left( \tan^2 \beta \right) - \tan^2 \beta \\ &= \text{0} \end{align*}

Prove the following identities and state restrictions where appropriate:

\(\dfrac{1+\sin\theta}{\cos\theta} = \dfrac{\cos\theta}{1-\sin\theta}\)

\begin{align*} \text{LHS } &= \dfrac{1+\sin \theta }{\cos\theta }\\ &=\dfrac{(1+\sin\theta)}{\cos\theta})\times \dfrac{(1-\sin\theta)}{1-\sin\theta}\\ &=\dfrac{1-\sin^2\theta}{\cos\theta(1-\sin\theta)} \\ &=\dfrac{\cos^2\theta }{\cos\theta(1-\sin\theta)} \\ &=\dfrac{\cos\theta}{(1-\sin\theta)} \\ &= \text{RHS} \end{align*}

Restrictions: undefined where \(\cos \theta = \text{0}, \sin \theta = \text{1}\) and where \(\tan \theta\)is undefined.

Therefore \(\theta \ne \text{90}\text{°};\text{270}\text{°}\).

\({\sin}^{2}\alpha + \left(\cos\alpha - \tan\alpha \right)\left(\cos\alpha +\tan\alpha \right)=1-{\tan}^{2}\alpha\)

\begin{align*} \text{LHS } &= \sin^2 \alpha + (\cos\alpha-\tan\alpha) (\cos\alpha+\tan\alpha) \\ &=\sin^2\alpha+\cos^2\alpha-\tan^2\alpha \\ &=1 - \tan^2\alpha \\ &= \text{RHS} \end{align*}

Restrictions: undefined where \(\tan \theta\) is undefined.

Therefore \(\theta \ne \text{90}\text{°};\text{270}\text{°}\).

\(\dfrac{1}{\cos\theta}-\dfrac{\cos\theta {\tan}^{2}\theta }{1}=\cos\theta\)

\begin{align*} \text{LHS } &= \dfrac{1}{\cos\theta}-\dfrac{\cos\theta \tan^2\theta}{1}\\ &=\dfrac{1-\cos^2\theta \times \tan^2\theta}{\cos\theta}\\ &=\dfrac{1-\cos^2\theta \times \dfrac{\sin^2\theta}{\cos^2\theta}}{\cos\theta}\\ &=\dfrac{1-\sin^2\theta}{\cos\theta}\\ &=\dfrac{\cos^2\theta}{\cos\theta}\\ &=\cos\theta\\ &= \text{RHS} \end{align*}

Restrictions: undefined where \(\cos \theta = \text{0}\) and where \(\tan \theta\)is undefined.

Therefore \(\theta \ne \text{90}\text{°};\text{270}\text{°}\).

\(\dfrac{2\sin\theta\cos\theta}{\sin\theta +\cos\theta }=\sin\theta +\cos\theta -\dfrac{1}{\sin\theta +\cos\theta }\)

\begin{align*} \text{RHS } &= \sin\theta+\cos\theta-\dfrac{1}{\sin\theta+\cos\theta} \\ &=\dfrac{\sin^2\theta+\sin\theta \cos\theta+\cos\theta \sin\theta+\cos^2\theta-1}{\sin\theta+\cos\theta} \\ &=\dfrac{1+2\sin\theta \cos\theta-1}{\sin\theta+\cos\theta} \\ &=\dfrac{2\sin\theta \cos\theta}{\sin\theta+\cos\theta} \\ &= \text{LHS} \end{align*}

\(\left(\dfrac{\cos\beta}{\sin\beta }+\tan\beta \right) \cos\beta =\dfrac{1}{\sin\beta }\)

\begin{align*} \text{ LHS} &= \left ( \dfrac{\cos\beta}{\sin\beta}+\dfrac{\sin\beta}{\cos\beta} \right ) \\ &=\left ( \dfrac{\cos^2\beta + \sin^2\beta}{\sin\beta\cos\beta} \right )\cos\beta\\ &=\dfrac{1}{\sin\beta}\\ &= \text{RHS } \end{align*}

\(\dfrac{1}{1 + \sin \theta} + \dfrac{1}{1 - \sin \theta} = d\frac{2 \tan \theta}{\sin \theta \cos \theta}\)

\begin{align*} \text{ LHS} &= \dfrac{1-\sin\theta+1+\sin\theta}{(1+\sin\theta)(1-\sin\theta)} \\ &=\dfrac{2}{1-\sin^2\theta} \\ &=\dfrac{2}{\cos^2\theta} \end{align*} \begin{align*} \text{ RHS} &= \dfrac{2 \tan \theta}{\sin \theta \cos \theta} \\ &=\dfrac{2 \sin \theta}{\sin \theta \cos \theta \cos \theta} \\ &=\dfrac{2}{\cos^2\theta} \\ \therefore \text{LHS } &= \text{RHS } \end{align*}

\(\dfrac{(1 + \tan^2 \alpha) \cos \alpha}{(1 - \tan \alpha)} = \dfrac{1}{\cos \alpha - \sin \alpha}\)

\begin{align*} \text{ LHS} &= \dfrac{(1 + \tan^2 \alpha) \cos \alpha}{(1 - \tan \alpha)} \\ &= \dfrac{\left (1+\frac{\sin^2\alpha}{\cos^2\alpha} \right )\cos\alpha}{\left ( 1-\frac{\sin\alpha}{\cos\alpha} \right )} \\ &=\dfrac{\left ( \frac{\cos^2\alpha+\sin^2\alpha}{\cos^2\alpha} \right )\cos\alpha}{\frac{\cos\alpha-\sin\alpha}{\cos\alpha}}\\ &=\dfrac{1}{\cos\alpha}\times \frac{\cos\alpha}{\cos\alpha-\sin\alpha} \\ &=\dfrac{1}{\cos\alpha-\sin\alpha} \\ &= \text{RHS } \end{align*}