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Chapter 10: Problem 17

Express the following polar coordinates in Cartesian coordinates. \(\left(1,-\frac{\pi}{3}\right)\)

Short Answer

Expert verified
Question: Convert the polar coordinates (1, -π/3) to Cartesian coordinates. Answer: The Cartesian coordinates are (1/2, -√3/2).

Step by step solution

01

Convert the polar coordinate to Cartesian coordinates

We are given the polar coordinate \((r, \theta) = \left(1,-\frac{\pi}{3}\right)\). We will plug these values into the conversion formulas to find the Cartesian coordinates \((x, y)\). \(x = r\cos\theta = 1\cos\left(-\frac{\pi}{3}\right)\) and \(y = r\sin\theta = 1\sin\left(-\frac{\pi}{3}\right)\)
02

Evaluate the Trigonometric Functions

Evaluate the cosine and sine functions in the conversion formulas. \(x = \cos\left(-\frac{\pi}{3}\right)\) As cosine function is an even function, so \(\cos(-\theta)=\cos\theta\). Thus, \(x = \cos\left(\frac{\pi}{3}\right) = \frac{1}{2}\) \(y = \sin\left(-\frac{\pi}{3}\right)=-\sin\left(\frac{\pi}{3}\right)=-\frac{\sqrt{3}}{2}\)
03

Write the Cartesian coordinates

Now that we have found the values of \(x\) and \(y\), we can write the Cartesian coordinates. The Cartesian coordinates are \((x, y) = \left(\frac{1}{2},-\frac{\sqrt{3}}{2}\right)\).

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Trigonometric Functions
Trigonometric functions are fundamental in mathematics, especially in the context of converting polar coordinates to cartesian coordinates. They relate the angles of a triangle to the lengths of its sides and have applications in various fields such as physics, engineering, and astronomy.
Cartesian Coordinate System
The Cartesian coordinate system is a two-dimensional coordinate system created by the French mathematician René Descartes. In this system, each point on a plane is determined by an ordered pair of numbers, known as coordinates. The first number (x-coordinate) measures the distance along the horizontal axis, while the second number (y-coordinate) measures the distance along the vertical axis. The Cartesian system is widely used in algebra and calculus for representing geometrical shapes, functions, and other mathematical expressions graphically.
Polar Coordinate System
The polar coordinate system is an alternative to the Cartesian coordinate system. It represents each point on a plane with two numbers: the radial distance from a fixed point (the pole, analogous to the origin in the Cartesian system) and an angle from a fixed direction (the polar axis, typically the line that represents the 0-degree angle). The radial distance is denoted as r, while the angle, usually measured in radians, is represented by θ. Polar coordinates are particularly useful for dealing with scenarios where phenomena are circular or radial in nature, such as in the orbits of celestial bodies or the vibration patterns of musical instruments.

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Most popular questions from this chapter

An ellipse (discussed in detail in Section 10.4 ) is generated by the parametric equations \(x=a \cos t, y=b \sin t.\) If \(0 < a < b,\) then the long axis (or major axis) lies on the \(y\) -axis and the short axis (or minor axis) lies on the \(x\) -axis. If \(0 < b < a,\) the axes are reversed. The lengths of the axes in the \(x\) - and \(y\) -directions are \(2 a\) and \(2 b,\) respectively. Sketch the graph of the following ellipses. Specify an interval in t over which the entire curve is generated. $$x=4 \cos t, y=9 \sin t$$

Show that the graph of \(r=a \sin m \theta\) or \(r=a \cos m \theta\) is a rose with \(m\) leaves if \(m\) is an odd integer and a rose with \(2 m\) leaves if \(m\) is an even integer.

An epitrochoid is the path of a point on a circle of radius \(b\) as it rolls on the outside of a circle of radius \(a\). It is described by the equations $$\begin{array}{l}x=(a+b) \cos t-c \cos \left(\frac{(a+b) t}{b}\right) \\\y=(a+b) \sin t-c \sin \left(\frac{(a+b) t}{b}\right)\end{array}$$ Use a graphing utility to explore the dependence of the curve on the parameters \(a, b,\) and \(c.\)

An idealized model of the path of a moon (relative to the Sun) moving with constant speed in a circular orbit around a planet, where the planet in turn revolves around the Sun, is given by the parametric equations $$x(\theta)=a \cos \theta+\cos n \theta, y(\theta)=a \sin \theta+\sin n \theta.$$ The distance from the moon to the planet is taken to be \(1,\) the distance from the planet to the Sun is \(a,\) and \(n\) is the number of times the moon orbits the planet for every 1 revolution of the planet around the Sun. Plot the graph of the path of a moon for the given constants; then conjecture which values of \(n\) produce loops for a fixed value of \(a\) a. \(a=4, n=3\) b. \(a=4, n=4 \) c. \(a=4, n=5\)

Graph the following equations. Then use arrows and labeled points to indicate how the curve is generated as \(\theta\) increases from 0 to \(2 \pi\). $$r=\frac{3}{1-\cos \theta}$$
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