Here is a graph of the curves $y=\sin x$y=sinx and $y=\cos x$y=cosx on the same set of axes:
The two curves $y=\sin x$y=sinx and $y=\cos x$y=cosx
We have looked quite thoroughly at these functions and their graphs. For instance, we know that they are periodic, each with a period of $2\pi$2π, and have an amplitude of $1$1 centred around a height of $y=0$y=0. We are now going to look into the graphs of sums and differences of $\sin x$sinx and $\cos x$cosx, using our knowledge of certain trigonometric identities.
$y=\sin x+\cos x$y=sinx+cosx
Let's begin by looking at the function $y=\sin x+\cos x$y=sinx+cosx. Using technology, we can obtain a graph of this function:
The curve $y=\sin x+\cos x$y=sinx+cosx
Notice that this looks much the same as a single sin or cos function, though it has a different amplitude and has been shifted horizontally. In fact we can rewrite the sum $\sin x+\cos x$sinx+cosx as a single trigonometric function. To see this we'll start with the variable $x$x and another fixed angle, which we choose to call $\alpha$α, and use the identity:
$\sin\left(x+\alpha\right)=\cos\alpha\sin x+\sin\alpha\cos x$sin(x+α)=cosαsinx+sinαcosx.
Now if $\cos\alpha$cosα and $\sin\alpha$sinα were to have the same value, we would be able to divide both sides by that value to leave the sum $\sin x+\cos x$sinx+cosx on the right hand side.
If we look back to the graph of the curves $y=\sin x$y=sinx and $y=\cos x$y=cosx at the beginning, we can see that the two graphs intersect at the angle $\frac{\pi}{4}$π4. That is,
$\sin\left(\frac{\pi}{4}\right)=\cos\left(\frac{\pi}{4}\right)=\frac{1}{\sqrt{2}}$sin(π4)=cos(π4)=1√2.
So replacing $\alpha$α with $\frac{\pi}{4}$π4, we have that
| $\sin\left(x+\frac{\pi}{4}\right)$sin(x+π4) | $=$= | $\cos\frac{\pi}{4}\sin x+\sin\frac{\pi}{4}\cos x$cosπ4sinx+sinπ4cosx |
| $=$= | $\frac{1}{\sqrt{2}}\sin x+\frac{1}{\sqrt{2}}\cos x$1√2sinx+1√2cosx |
Multiplying both sides by $\sqrt{2}$√2 gives us the result:
$\sin x+\cos x=\sqrt{2}\sin\left(x+\frac{\pi}{4}\right)$sinx+cosx=√2sin(x+π4)
Compared to $y=\sin x$y=sinx, the function $y=\sqrt{2}\sin\left(x+\frac{\pi}{4}\right)$y=√2sin(x+π4) has an amplitude of $\sqrt{2}$√2, and has a horizontal shift of $\frac{\pi}{4}$π4 units to the left. Here is a graph of $y=\sqrt{2}\sin\left(x+\frac{\pi}{4}\right)$y=√2sin(x+π4):
The curve $y=\sqrt{2}\sin\left(x+\frac{\pi}{4}\right)$y=√2sin(x+π4)
Comparing this to the graph of $y=\sin x+\cos x$y=sinx+cosx above, we can see that the two graphs (and therefore the two functions) are indeed the same!
$y=a\sin x+b\cos x$y=asinx+bcosx
We can generalise this process to any linear combination of $\sin x$sinx and $\cos x$cosx. That is, we can rewrite any function of the form $y=a\sin x+b\cos x$y=asinx+bcosx in the form $y=R\sin\left(x+\alpha\right)$y=Rsin(x+α), where $a$a, $b$b, $R$R and $\alpha$α are constants.
Using the same trigonometric identity, we have that $R\sin\left(x+\alpha\right)=R\cos\alpha\sin x+R\sin\alpha\cos x$Rsin(x+α)=Rcosαsinx+Rsinαcosx. Notice that this is in the form $a\sin x+b\cos x$asinx+bcosx, where
| $a$a | $=$= | $R\cos\alpha$Rcosα | , and |
| $b$b | $=$= | $R\sin\alpha$Rsinα |
We can rearrange these two equations to obtain expressions for $R$R and $\alpha$α in terms of $a$a and $b$b.
To find $R$R, we can square and add the two equations:
| $a^2+b^2$a2+b2 | $=$= | $R^2\cos^2\left(\alpha\right)+R^2\sin^2\left(\alpha\right)$R2cos2(α)+R2sin2(α) |
| $=$= | $R^2\left(\sin^2\left(\alpha\right)+\cos^2\left(\alpha\right)\right)$R2(sin2(α)+cos2(α)) | |
| $=$= | $R^2$R2 |
So we have that
$R=\sqrt{a^2+b^2}$R=√a2+b2.
To find $\alpha$α, we can divide the two equations:
| $\frac{b}{a}$ba | $=$= | $\frac{R\sin\alpha}{R\cos\alpha}$RsinαRcosα |
| $=$= | $\frac{\sin\alpha}{\cos\alpha}$sinαcosα | |
| $=$= | $\tan\alpha$tanα |
We can then find the value of $\alpha$α from this relation, though we may need to consider which quadrant the angle is in depending on the signs of $a$a and $b$b, since after all we know that $a=R\cos\alpha$a=Rcosα and $b=R\sin\alpha$b=Rsinα.
For example: if $\frac{b}{a}$ba was positive but the values of $a$a and $b$b were negative, then the value of $\alpha$α will lie in the third quadrant (since this is where $\tan$tan is positive, but sine and cosine are negative).
We can also rewrite a function of the form $y=a\sin x+b\cos x$y=asinx+bcosx in the form $y=R\cos\left(x+\alpha\right)$y=Rcos(x+α). Performing some similar rearrangements, we find in this case that $R=\sqrt{a^2+b^2}$R=√a2+b2 and $\tan\alpha=\frac{-a}{b}$tanα=−ab.
A function of the form $y=a\sin x+b\cos x$y=asinx+bcosx can be rewritten in the form $y=R\sin\left(x+\alpha\right)$y=Rsin(x+α), where $R>0$R>0 and $-\pi<\alpha<\pi$−π<α<π. We can find the values of $R$R and $\alpha$α using the relations
- $R=\sqrt{a^2+b^2}$R=√a2+b2, and
- $\tan\alpha=\frac{b}{a}$tanα=ba.
Similarly, a function of the form $y=a\sin x+b\cos x$y=asinx+bcosx can be rewritten in the form $y=R\cos\left(x+\alpha\right)$y=Rcos(x+α), where $R>0$R>0 and $-\pi<\alpha<\pi$−π<α<π, by using the relations
- $R=\sqrt{a^2+b^2}$R=√a2+b2, and
- $\tan\alpha=\frac{-a}{b}$tanα=−ab.
When finding the value of $\alpha$α, remember that the inverse $\tan$tan function only gives values between $-\frac{\pi}{2}$−π2 and $\frac{\pi}{2}$π2. The actual value of $\alpha$α can be between $-\pi$−π and $\pi$π, and the particular angle will depend on the signs of the coefficients $a$a and $b$b.
Graphs of $y=a\sin x+b\cos x$y=asinx+bcosx
To more easily sketch the graph of a function of the form $y=a\sin x+b\cos x$y=asinx+bcosx, we can first rewrite it as a single trigonometric function, using either $\sin$sin or $\cos$cos, as we have just seen. Then we can use our knowledge of transformations of trig graphs to sketch the function.
Remember that for a function of the form $y=R\sin\left(x+\alpha\right)$y=Rsin(x+α), we can start with the graph of $y=\sin x$y=sinx. The value of $\alpha$α corresponds to a horizontal shift (left if $\alpha$α is positive, right if $\alpha$α is negative), and the value of $R$R corresponds to a vertical dilation - that is, it changes the amplitude of the function. The same is true for a function of the form $y=R\cos\left(x+\alpha\right)$y=Rcos(x+α), starting from the graph of $y=\cos x$y=cosx.
To more easily sketch the graph of $y=a\sin x+b\cos x$y=asinx+bcosx, we can first rewrite it in the form $y=R\sin\left(x+\alpha\right)$y=Rsin(x+α) or $y=R\cos\left(x+\alpha\right)$y=Rcos(x+α) using the method above.
The value of $R$R will then be the amplitude of the $\sin$sin or $\cos$cos function, and the value of $\alpha$α will be the horizontal shift of the function.
Practice questions
Question 1
Consider the equation $y=\sin x-\cos x$y=sinx−cosx.
Rewrite the equation in the form $y=R\sin\left(x+\alpha\right)$y=Rsin(x+α), where $R>0$R>0 and $-\pi<\alpha<\pi$−π<α<π.
Which of the following could be the graph of $y=\sin x-\cos x$y=sinx−cosx?
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Question 2
Consider the equation $y=4\sin x+5\cos x$y=4sinx+5cosx.
Rewrite the equation in the form $y=R\cos\left(x+\alpha\right)$y=Rcos(x+α), where $R>0$R>0 and $-\pi<\alpha<\pi$−π<α<π.
Give the value of $\alpha$α correct to three decimal places.
Which of the following could be the graph of $y=4\sin x+5\cos x$y=4sinx+5cosx?
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Question 3
Consider the equation $y=\sqrt{3}\sin x+\cos x$y=√3sinx+cosx.
Rewrite the equation in the form $y=R\cos\left(x+\alpha\right)$y=Rcos(x+α), where $R>0$R>0 and $-\pi<\alpha<\pi$−π<α<π.
Now sketch the curve $y=\sqrt{3}\sin x+\cos x$y=√3sinx+cosx on the axes below:
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