The initial side is usually placed on the positive x-axis. The angle is usually measured counter-clockwise from the pos. x-axis. An angle of 135 degrees would have its terminal side halfway into the upper left quadrant of the unit circle.onemic said:When creating a right triangle in a unit circle how do you know where to place the leg from the terminal side? My textbook and Khan academy don't really explain this and it's just sort of assumed that I'd know. For example, If theta is equal to 135 degrees, where does the leg to complete the right triangle get placed? The y-axis or the x-axis?
RUber said:Most people draw the leg to the x-axis, but there is no reason one way would be better than another. In this case ##\frac \pi 2 < \theta < \pi##, so if you drew the leg to the x-axis, your triangle will have an angle at the origin measuring ##\pi - \theta##. If you drew the leg to the y-axis, you would have an angle at the origin measuring ##\theta - \frac \pi 2##. Once you have dealt with the right triangle, be sure to account for your signs; in this quadrant, cosine is negative and sine is positive.
Mark44 said:The initial side is usually placed on the positive x-axis. The angle is usually measured counter-clockwise from the pos. x-axis. An angle of 135 degrees would have its terminal side halfway into the upper left quadrant of the unit circle.
It should be drawn down to the x-axis (for angles between 0 and 180 degrees, or up to the x-axis for angles between 180 and 360 degrees.onemic said:Ah, so I can always draw the leg to the x axis? I was getting confused because sometimes the leg from the terminal side would be drawn to the x-axis and sometimes the y axis
That I know, but I'm specifically talking about the leg drawn from the terminal side to complete the right triangle.
Correct. If there are coordinates on the circle that are greater than 1 or less than -1, then it's not a unit circle.onemic said:Another question. There are times where I see a triangle constructed in the unit circle where the terminal side intersects the circle at coordinates greater than 1. I thought that the unit circle has a radius of one and thus any x or y coordinate that intersects the circle can never be greater than 1?
You don't get a triangle with those angles. A better way of thinking of things is that for any point on the unit circle, with coordinates of (x, y), we have ##x = \cos(\theta)## and ##y = \sin(\theta)##. Here ##\theta## is the angle measured from the positive x-axis to the ray that extends from (0, 0) to the point (x, y) on the unit circle. See https://en.wikipedia.org/wiki/Unit_circle.onemic said:Also when theta is equal to pi/2, pi, 2pi or 3pi/2 what would the opposite and adjacent sides be equal to, since you can't create a right triangle?
A unit circle is a circle with a radius of 1 unit, centered at the origin on a Cartesian coordinate plane. It is often used in trigonometry to establish the relationships between angles and the coordinates of points on the circle.
The unit circle is used to define the six trigonometric functions (sine, cosine, tangent, cotangent, secant, and cosecant). The coordinates of points on the unit circle correspond to the values of these functions at various angles.
The unit circle can be used to find the values of trigonometric functions for any angle, which can then be used to solve equations involving these functions. It is also used to visualize the relationship between angles and the values of these functions.
Radians and degrees are two different units of measuring angles. Degrees are based on a circle divided into 360 equal parts, while radians are based on the length of an arc on the unit circle. One radian is equal to approximately 57.3 degrees.
To find the values of trigonometric functions at a specific angle, you can use the coordinates of the corresponding point on the unit circle. For example, the sine of an angle is equal to the y-coordinate of the corresponding point on the unit circle.