6.01 Angles and radian measure

\dfrac{\pi}{2}

On the coordinate plane, the unit circle is cut into four portions for each quadrant. We know that \dfrac{1}{4} of the entire unit circle is equivalent to 90 \degree or \dfrac{\pi}{2}.

The axes on the coordinate plane form 90 \degree angles and we can see that the first quarter of the unit circle is equivalent to 90 \degree or \dfrac{\pi}{2}.

We can also describe the angle in terms of \pi since \pi is 180 \degree. If we need half of \pi or \dfrac{\pi}{2}, we know that this measure is half of a semicircle, which we have shown as the same as a quarter of a circle.

\dfrac{3 \pi}{2}

Place the initial side on the x-axis, then use the fact that each axis represents 90 \degree or \dfrac{\pi}{2} to choose what fraction of the entire circle \dfrac{3 \pi}{2} is:

Since \dfrac{\pi}{2} represents 90 \degree or a quarter of one full circle, and we need to draw \dfrac{3 \pi}{2}, we would draw three portions of the unit circle we found in part (a).

\dfrac{\pi}{3}

We know that \pi represents half of a revolution of the unit circle, so if we cut half of the circle into three, we know one of the three portions will be \dfrac{\pi}{3}.

Since \dfrac{\pi}{3} represents \dfrac{1}{3} of \pi or \dfrac{1}{3} of half of the unit circle, we know that there are a total of 6 of those portions throughout the unit circle. This makes sense since \dfrac{\pi}{3}=30 \degree and 360 \degree \div 6 = 30 \degree.

\dfrac{4 \pi}{3}

We can view this radian measure as four \dfrac{\pi}{3} of the unit circle. We know that \dfrac{\pi}{3} is a third of a semicircle, so in order to determine the location of \dfrac{4 \pi}{3}, we can imagine a total of four portions of the graph from part (c).

A total of four \dfrac{\pi}{3} from part (c) would give us \dfrac{4 \pi}{3}.

Given a circle with a 12 \text{ ft} arc subtended by the angle \dfrac{\pi}{4}, find the radius.

Use the formula for calculating the radian measure of an arc in a circle: \theta = \dfrac{s}{r}

Since the radius is unknown, we could start by rearranging the formula in terms of r and then substitute the values into the equation to solve for the radius:

Given a circle with a radius of 9 \text{ m}, find the length of the arc subtended by a 2.09 \text{ radian} angle.

Note that radians are not always written in terms of \pi.

Given a circle with a radius of 6 \text{ cm}, find the radian measure of the angle subtended by a 33 \text{ cm} arc.

By using the formula for calculating the radian measure of an arc, we know that the solution will be in radians, not degrees.

If we wanted to determine how many degrees 5.5 radians is, we could first determine the fraction of a circle that 5.5 radians makes up. This is \dfrac{5.5}{6.28} \approx 0.876. Then, we can multiply this by 360 \degree and see that the angle measure in degrees is about 315 \degree.

As we become more fluent with understanding radian measures in terms of \pi, we may notice that 315 \degree is a multiple of 45 \degree, which is equivalent to \dfrac{\pi}{4}. Since \dfrac{315 \degree}{45 \degree}= 7, the radian measure of this angle can also be written as 7 \cdot \dfrac{\pi}{4} = \dfrac{7 \pi}{4}.

Graph the angle in standard form.

We know that since the angle is negative, the terminal side of the angle will move in the clockwise direction.

First, draw a circle and since each semicircle is equivalent to \pi, cut the semicircles into four so that the circle has a total of eight equal portions.

Use five measures of \dfrac{\pi}{4} in the clockwise direction to graph the angle in standard form.

Find the measure of the coterminal angle to - \dfrac{5 \pi}{4} that is between 0 and 2 \pi.

Add 2 \pi to -\dfrac{5\pi}{4} until the coterminal angle is between 0 and 2 \pi.

-\dfrac{5 \pi}{4} + 2 \pi = - \dfrac{ 5 \pi}{4} + \dfrac{8 \pi}{4} = \dfrac{3 \pi}{4}.

The measure of the coterminal angle to -\dfrac{5 \pi}{4} that is between 0 and 2 \pi is \dfrac{3 \pi}{4}.

We could also have used the angle graphed in standard form on the unit circle to see that \dfrac{3 \pi}{4} is equivalent to -\dfrac{5 \pi}{4}.

Find the measure of the reference angle for - \dfrac{5 \pi}{4}.

Since the coterminal angle to -\dfrac{5 \pi}{4} is \dfrac{3 \pi}{4} which is in the second quadrant, we can use the symmetry of the unit circle to find the reference angle to \dfrac{3 \pi}{4} in the first quadrant.

The reference angle for -\dfrac{5 \pi}{4} is \dfrac{\pi}{4}.

\dfrac{35 \pi}{6} radians

The given angle is more than one full revolution, 360 \degree or 2 \pi, so subtract 2 \pi from \dfrac{35 \pi}{6} until we get to an angle coterminal to it between 0 and 2 \pi.

\dfrac{35 \pi}{6} - \dfrac{12 \pi}{6} = \dfrac{23 \pi}{6} - \dfrac{12 \pi}{6} = \dfrac{11 \pi}{6}

Since \dfrac{35 \pi}{6} was a counterclockwise or positive rotation with its initial side along the positive x-axis, we know to find its coterminal side between 0 and 2 \pi by moving clockwise or in the negative direction, leading to subtracting two full revolutions.

-\dfrac{8 \pi}{3}

The given angle is negative, so to find the angle coterminal to it between 0 and 2 \pi, add 2 \pi to -\dfrac{8 \pi}{3} until we get to an angle coterminal to it between 0 and 2 \pi.

-\dfrac{8 \pi}{3} + \dfrac{6 \pi}{3} = -\dfrac{2 \pi}{3} + \dfrac{6 \pi}{3} = \dfrac{4 \pi}{3}

Since -\dfrac{8 \pi}{3} was a clockwise or negative rotation with its initial side along the positive x-axis, we know to find its coterminal side between 0 and 2 \pi by moving counterclockwise or in the positive direction, leading to adding two full revolutions.