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I am having trouble grasping some of the concepts regarding the unit circle. I think I have the basics down but I do not have an intuitive sense of what is going on. Is memorizing the radian measurements and their corresponding points the only way to master this? What are some ways one can memorize the unit circle?

Edit for clarification: I think my trouble arises by the use of $\pi$ instead of degrees. We started graphing today and the use of numbers on the number line were again being referred to with $\pi$. Why is this?

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What is it you are trying to "memorize" about the unit circle? It's the circle of radius $1$ with center at the origin. What else? – Arturo Magidin Apr 5 '11 at 19:57
You can derive it all from scratch if you don't memorize it, but it is faster to memorize it if you are taking tests. If you are doing real world stuff you can use a computer or reference book. – quanta Apr 5 '11 at 19:57
By the way, it's spelt pi. – Rahul Apr 5 '11 at 20:14
Radians are preferable to degrees because they will make Calculus (particularly derivatives) a lot simpler. Trust me: better to remember now that $2\pi$ radians = $360^{\circ}$ (and perhaps a few other obvious ones, like $\pi$ radians $= 180^{\circ}$, or $\frac{\pi}{6}$ radians $=30^{\circ}$, than to deal later with the difficulties you would encounter if you try to work with degrees throughout. Better to work with radians throughout. (And even better to stop confusing fundamental mathematical constants with baked dishes usually served for dessert). – Arturo Magidin Apr 5 '11 at 20:18
Or use $\$\backslash \text{pi}\$$ to get $\pi$. – Douglas Zare Apr 5 '11 at 20:18
up vote 5 down vote accepted

One way to remember is that in a unit circle, as you traverse the perimeter, the distance you cover along the perimeter, exactly equals the angle you covered.

So if you start at one point and cover the whole circle, the angle covered is the whole perimeter: $2 \pi$. If you only cover one fourth, then the angle you have covered if $\dfrac{\pi}{2}$.

Hope that helps.

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I understand that. My trouble comes in identifying the perimeter with pie. why pie / 2 instead of 1 / 2 ?? – Matt Apr 5 '11 at 20:03
@Matt: You do remember the perimeter of a circle is $2\pi r$ don't you? If you want a proof/intuition behind that, I believe a question has already been asked on this site. – Aryabhata Apr 5 '11 at 20:04
Yes, I understand that is the reason why pie is used. I guess my problem fundamentally boils down to weakness when it comes to fractions and adding pie in just confuses me. Do I just should I just look at the perimeter as fractions with pie and treat pie as if it where a variable? – Matt Apr 5 '11 at 20:07
@Matt: I am not sure what you mean. Anyway, the degree definition is arbitrary (or historic) while $\pi$ is the fundamental constant associated with the circle. It comes from the fact that the ratio of perimeter to the diameter of a circle is independent of the diameter and that constant is called $\pi$. So I suggest you start thinking in terms of radians, rather than degrees. – Aryabhata Apr 5 '11 at 20:10
@Matt It's not PIE, it's pi. – JavaMan Apr 5 '11 at 20:31

You can simplify the task of understanding the unit circle to the task of understanding two right triangles: the $30$-$60$-$90^\circ$ triangle and the $45^\circ$ triangle.

First note that $\frac{\pi}{4} = 45^\circ$ and $\frac{\pi}{6} = 30^\circ$. Then draw a $30^\circ$ angle of a right triangle and label the opposite side $1$, the adjacent side $\sqrt 3$, and the hypotenuse $2$. Since $\frac{\pi}{6} = 30^\circ$ and $cos(x) = \frac{adj}{hyp}$, we have that $cos(\frac{\pi}{6}) = \sqrt 3/2$. Similarly we can discover the values for $sin(\frac{\pi}{6})$, $cos(\frac{\pi}{3})$ and $sin(\frac{\pi}{3})$.

The $45^\circ$ triangle can be used to find values when $x = \frac{\pi}{4}$. Remember that on the $45^\circ$ triangle, $opposite = adjacent = 1$ and $hypotenuse = \sqrt 2$.

Now this only clarifies the unit circle in the first quadrant, but one can often fill the entire unit circle out once you know these values and utilize certain properties like $cos(x) = cos(-x)$ and $sin(-x) = -sin(x)$.

This is the way I tutor my students on the unit circle and they seem to appreciate being able to `prove' that $cos(\frac{11\pi}{6}) = \sqrt 3/2$.

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Gee, a picture would be really swell here... – Joshua Shane Liberman Apr 5 '11 at 20:19

It is probably useful to memorize a table like this: \begin{align} \theta & & \sin\theta & & \cos \theta \\ 0 & & \frac{\sqrt{0}}{2} = 0 & & \frac{\sqrt{4}}{2} = 1 \\ \frac{\pi}{6} & & \frac{\sqrt{1}}{2} = \frac{1}{2} & & \frac{\sqrt{3}}{2} \\ \frac{\pi}{4} & & \frac{\sqrt{2}}{2} & & \frac{\sqrt{2}}{2} \\ \frac{\pi}{3} & & \frac{\sqrt{3}}{2} & & \frac{\sqrt{1}}{2} = \frac{1}{2} \\ \frac{\pi}{2} & & \frac{\sqrt{4}}{2} = 0 & & \frac{\sqrt{0}}{2} = 0 \end{align}

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This is not really an answer to the question you asked, but it is an answer to a question you could have asked: What good is the unit circle? What follows is a slight revision of some comments I've posted two or three times in the past few years in a listserv for (mainly U.S. high school) AP-calculus teachers.

By "unit circle", I mean a certain conceptual framework for many important trig facts and properties, NOT a big circle drawn on a sheet of paper that has angles labeled with degree measures 30, 45, 60, 90, 120, 150, etc. (and/or with the corresponding radian measures), along with the exact values for the sine and cosine of these angles.

I've found that an appropriate understanding of the unit circle gives a huge savings on memorization in that it allows you to efficiently catalogue and cross-check a large number of pertinent facts about the trig functions. All you have to know is that cosine goes with the $x$-coordinate and sine goes with the $y$-coordinate, and for this you just remember that it's alphabetical: *c*osine goes with $x$ and *s*ine goes with $y$.

Using this understanding of the unit circle, we can get the values of sine and cosine at integer multiples of 90 degrees, since these will correspond to points on the unit circle that are on the positive $x$-axis, the negative $x$-axis, the positive $y$-axis, or the negative $y$-axis, and for each of these possibilities we know what both coordinates of the point will be.

Using this understanding of the unit circle, we know that $\cos^{2} x + \sin^{2} x = 1$, from which so much else arises. (Essentially everything if you work hard enough. See [1] [2].)

[1] Andy Roy Magid, "Trigonometric identities", Mathematics Magazine 47 #4 (September 1974), 226-227.

[2] David Earl Dobbs, "Proving trig. identities to freshpersons", Mathematics and Computer Education 14 #1 (Winter 1980), 39-42.

Using this understanding of the unit circle, we can get the signs of sine and cosine in each of the 4 quadrants.

Using this understanding of the unit circle, we can deduce that $\sin(-\theta) = -\sin(\theta)$ and $\cos(-\theta) = \cos(\theta)$. [In practice, when you know each of sine and cosine is either an even function or an odd function and you know about graph reflection properties for even and odd functions, it's easy to figure out which is which by looking at how the $x$- and $y$-coordinates for $-45$ degrees compare with the $x$- and $y$-coordinates for 45 degrees.]

Using this understanding of the unit circle, we know, when given an interval, whether sine is increasing on that interval, decreasing on that interval, or neither. We also know this for cosine. [In fact, since just to the right of $0$ sine is increasing and cosine is decreasing and both are positive, it follows that cosine is the one you have to use a negative sign for when writing its derivative. That's assuming you remember the derivative of the sine is cosine and the derivative of the cosine is sine, modulo one of them requiring a negative sign. I didn't expect (nor ever see) this from students, however.]

By considering a right triangle with one vertex at the origin, one vertex on the $x$-axis between $x=0$ and $x=1$, and one vertex on $x^2 + y^2 = 1$ in the first quadrant, you can see that sine and cosine are opp/hyp and adj/hyp, respectively.

You can even obtain the sine and cosine of 30 degrees, 45 degrees, and 60 degrees if you know that $\frac{1}{2}$ shows up as a value for at least one of them. Let's first consider the case where the $y$-coordinate of a first quadrant point on the unit circle is equal to $\frac{1}{2}$. Then we get $x^2 + \left(\frac{1}{2}\right)^2 = 1$, which gives us $x = \frac{\sqrt{3}}{2}$. Since $\frac{\sqrt{3}}{2} > \frac{1}{2}$ (square both sides, or just note that $\sqrt{3} > 1$), it must be that these are the values for a point $(x,y)$ on the unit circle such that $x > y$, so this has to be for 30 degrees (given that we know $\frac{1}{2}$ can be the value of sine and/or cosine only for first quadrant angles among those with degree measure 30, 45, 60). Since $x = \frac{1}{2}$ and $y = \frac{\sqrt{3}}{2}$ also satisfies $x^2 + y^2 = 1$ (no work needed; just switch the order of addition in the previous case), and here $x < y$, these must be the values for 60 degrees. (Or reflect our earlier $x > y$ situation about the line $y=x$, which is equivalent to a 90 degree counterclockwise rotation followed by a reflection across the vertical axis.) As for the values at 45 degrees, clearly this is when $x = y$, which you can easily substitute into $x^2 + y^2 = 1$ and get $x = y = \frac{\sqrt{2}}{2}$. No, I didn't expect any students to do this, nor did any of them do so to my knowledge. I'm just showing how much you can get from the unit circle with a bit of ingenuity and a few scraps of incompletely remembered results (such as one of the outputs being $\frac{1}{2}$).

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The cool thing about radians is that they relate linear measure to angular measure. So if we go $x$ radians around a circle of radius $r$ units, then we've traveled $xr$ units of length. This comes from the formula $C = 2\pi r$. You can see that $2\pi$ is the ratio of the circumference of a whole circle to its radius and that this formula can be viewed as creating a function that maps radii to circumferences. So if we go halfway around the circle, then we've traveled only half the distance and we must have $C/2 = \frac{2\pi}{2}r = \pi r$. Again, we see that $\pi$ radians can be viewed as a function mapping radii to lengths of half circles. You want a quarter circle? Well, $C/4 = \frac{2\pi}{4}r = \frac{\pi}{2}r$ and we see that to figure out the length of a quarter circular arc, one just multiplies by $\frac{\pi}{2}$.

So I would forget all about degrees and think in terms of what part of the circle an angle sweeps out. You'll get some real number between $0$ and $1$ ($1$, $\frac{1}{2}$, and $\frac{1}{4}$ in the cases we've looked at). Multiply that number by $2\pi$ and that's how many radians the angle is.


And note that my restriction that the number be between $0$ and $1$ is arbitrary. What about traveling around a circle twice? Then you've gone $2C = 2 \cdot 2\pi r = 4\pi r$ times around the circle and traveled around an angle of $4\pi$ radians. Nothing at all is different.

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I would be glad if you like! enter image description here

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enter image description here


We start by remembering the sequence is simply the Square Root of 0 on 2 (which is just 0) the Square Root 1 on 2 (or 1/2) etc. You write those numbers for 0 degrees, 30,45,60, 90. Then repeat the process back down for the X values.

Once you create the first quadrant (that upper right quarter) the rest just reflect over the X and Y axis. The trig books I see don't spell this out, but when I hand this to a student, and tell them to practice producing that quadrant, they come back a few days later having aced their test, and their friends come ask for a copy of the circle.

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