Polar Functions: Get Stronger Answer Key

Polar Coordinates

1. For polar coordinates, the point in the plane depends on the angle from the positive x-axis and distance from the origin, while in Cartesian coordinates, the point represents the horizontal and vertical distances from the origin. For each point in the coordinate plane, there is one representation, but for each point in the polar plane, there are infinite representations.

3. Determine [latex]\theta[/latex] for the point, then move [latex]r[/latex] units from the pole to plot the point. If [latex]r[/latex] is negative, move [latex]r[/latex] units from the pole in the opposite direction but along the same angle. The point is a distance of [latex]r[/latex] away from the origin at an angle of [latex]\theta[/latex] from the polar axis.

5. The point [latex]\left(-3,\frac{\pi }{2}\right)[/latex] has a positive angle but a negative radius and is plotted by moving to an angle of [latex]\frac{\pi }{2}[/latex] and then moving 3 units in the negative direction. This places the point 3 units down the negative y-axis. The point [latex]\left(3,-\frac{\pi }{2}\right)[/latex] has a negative angle and a positive radius and is plotted by first moving to an angle of [latex]-\frac{\pi }{2}[/latex] and then moving 3 units down, which is the positive direction for a negative angle. The point is also 3 units down the negative y-axis.

7. [latex]\left(-5,0\right)[/latex]

9. [latex]\left(-\frac{3\sqrt{3}}{2},-\frac{3}{2}\right)[/latex]

11. [latex]\left(2\sqrt{5}, 0.464\right)[/latex]

13. [latex]\left(\sqrt{34},5.253\right)[/latex]

17. [latex]r=4\csc \theta[/latex]

19. [latex]r=\sqrt[3]{\frac{sin\theta }{2co{s}^{4}\theta }}[/latex]

21. [latex]r=3\cos \theta[/latex]

23. [latex]r=\frac{3\sin \theta }{\cos \left(2\theta \right)}[/latex]

25. [latex]r=\frac{9\sin \theta }{{\cos }^{2}\theta }[/latex]

27. [latex]r=\sqrt{\frac{1}{9\cos \theta \sin \theta }}[/latex]

29. [latex]{x}^{2}+{y}^{2}=4x[/latex] or [latex]\frac{{\left(x - 2\right)}^{2}}{4}+\frac{{y}^{2}}{4}=1[/latex]; circle

31. [latex]3y+x=6[/latex]; line

33. [latex]y=3[/latex]; line

35. [latex]xy=4[/latex]; hyperbola

37. [latex]{x}^{2}+{y}^{2}=4[/latex]; circle

39. [latex]x - 5y=3[/latex]; line

41. [latex]\left(3,\frac{3\pi }{4}\right)[/latex]

43. [latex]\left(5,\pi \right)[/latex]

45.
Polar coordinate system with a point located on the second concentric circle and two-thirds of the way between pi and 3pi/2 (closer to 3pi/2).

49.
Polar coordinate system with a point located on the fifth concentric circle and pi/2.

51.
Polar coordinate system with a point located on the third concentric circle and 2/3 of the way between pi/2 and pi (closer to pi).

55. [latex]r=\frac{6}{5\cos \theta -\sin \theta }[/latex]
Plot of given line in the polar coordinate grid

57. [latex]r=2\sin \theta[/latex]
Plot of given circle in the polar coordinate grid

59. [latex]r=\frac{2}{\cos \theta }[/latex]
Plot of given circle in the polar coordinate grid

61. [latex]r=3\cos \theta[/latex]
Plot of given circle in the polar coordinate grid.

63. [latex]{x}^{2}+{y}^{2}=16[/latex]
Plot of circle with radius 4 centered at the origin in the rectangular coordinates grid.

65. [latex]y=x[/latex]
Plot of line y=x in the rectangular coordinates grid.

67. [latex]{x}^{2}+{\left(y+5\right)}^{2}=25[/latex]
Plot of circle with radius 5 centered at (0,-5).

69. [latex]\left(1.618,-1.176\right)[/latex]

71. [latex]\left(10.630,131.186^\circ \right)[/latex]

73. [latex]\left(2,3.14\right)or\left(2,\pi \right)[/latex]

Polar Coordinates: Graphs

1. Symmetry with respect to the polar axis is similar to symmetry about the [latex]x[/latex] -axis, symmetry with respect to the pole is similar to symmetry about the origin, and symmetric with respect to the line [latex]\theta =\frac{\pi }{2}[/latex] is similar to symmetry about the [latex]y[/latex] -axis.

3. Test for symmetry; find zeros, intercepts, and maxima; make a table of values. Decide the general type of graph, cardioid, limaçon, lemniscate, etc., then plot points at [latex]\theta =0,\frac{\pi }{2},\pi \text{and }\frac{3\pi }{2}[/latex], and sketch the graph.

5. The shape of the polar graph is determined by whether or not it includes a sine, a cosine, and constants in the equation.

7. symmetric with respect to the polar axis

9. symmetric with respect to the polar axis, symmetric with respect to the line [latex]\theta =\frac{\pi }{2}[/latex], symmetric with respect to the pole

11. no symmetry

13. no symmetry

15. symmetric with respect to the pole

17. circle
Graph of given circle.

19. cardioid
Graph of given cardioid.

21. cardioid
Graph of given cardioid.

23. one-loop/dimpled limaçon
Graph of given one-loop/dimpled limaçon

25. one-loop/dimpled limaçon
Graph of given one-loop/dimpled limaçon

27. inner loop/two-loop limaçon
Graph of given inner loop/two-loop limaçon

29. inner loop/two-loop limaçon
Graph of given inner loop/two-loop limaçon

31. inner loop/two-loop limaçon
Graph of given inner loop/two-loop limaçon

33. lemniscate
Graph of given lemniscate (along horizontal axis)

35. lemniscate
Graph of given lemniscate (along y=x)

37. rose curve
Graph of given rose curve - four petals.

39. rose curve
Graph of given rose curve - eight petals.

41. Archimedes’ spiral
Graph of given Archimedes' spiral

43. Archimedes’ spiral
Graph of given Archimedes' spiral

45.
Graph of given equation.

47.
Graph of given hippopede (two circles that are centered along the x-axis and meet at the origin)

49.
Graph of given equation.

51.
Graph of given equation. Similar to original Archimedes' spiral.

53.
Graph of given equation.

61. The graphs are three-petal, rose curves. The larger the coefficient, the greater the curve’s distance from the pole.

63. The graphs are spirals. The smaller the coefficient, the tighter the spiral.

65. [latex]\left(4,\frac{\pi }{3}\right),\left(4,\frac{5\pi }{3}\right)[/latex]

67. [latex]\left(\frac{3}{2},\frac{\pi }{3}\right),\left(\frac{3}{2},\frac{5\pi }{3}\right)[/latex]

69. [latex]\left(0,\frac{\pi }{2}\right),\left(0,\pi \right),\left(0,\frac{3\pi }{2}\right),\left(0,2\pi \right)[/latex]

71. [latex]\left(\frac{\sqrt[4]{8}}{2},\frac{\pi }{4}\right),\left(\frac{\sqrt[4]{8}}{2},\frac{5\pi }{4}\right)[/latex]
and at [latex]\theta =\frac{3\pi }{4},\frac{7\pi }{4}[/latex] since [latex]r[/latex] is squared

Polar Form of Complex Numbers

1. a is the real part, b is the imaginary part, and [latex]i=\sqrt{−1}[/latex]

3. Polar form converts the real and imaginary part of the complex number in polar form using [latex]x=r\cos\theta[/latex] and [latex]y=r\sin\theta[/latex]

7. [latex]5\sqrt{2}[/latex]

9. [latex]\sqrt{38}[/latex]

11. [latex]\sqrt{14.45}[/latex]

13. [latex]4\sqrt{5}\text{cis}\left(333.4^{\circ}\right)[/latex]

15. [latex]2\text{cis}\left(\frac{\pi}{6}\right)[/latex]

17. [latex]\frac{7\sqrt{3}}{2}+i\frac{7}{2}[/latex]

19. [latex]−2\sqrt{3}−2i[/latex]

21. [latex]−1.5−i\frac{3\sqrt{3}}{2}[/latex]

23. [latex]4\sqrt{3}\text{cis}\left(198^{\circ}\right)[/latex]

25. [latex]\frac{3}{4}\text{cis}\left(180^{\circ}\right)[/latex]

27. [latex]5\sqrt{3}\text{cis}\left(\frac{17\pi}{24}\right)[/latex]

29. [latex]7\text{cis}\left(70^{\circ}\right)[/latex]

31. [latex]5\text{cis}\left(80^{\circ}\right)[/latex]

33. [latex]5\text{cis}\left(\frac{\pi}{3}\right)[/latex]

35. [latex]125\text{cis}\left(135^{\circ}\right)[/latex]

37. [latex]9\text{cis}\left(240^{\circ}\right)[/latex]

39. [latex]\text{cis}\left(\frac{3\pi}{4}\right)[/latex]

41. [latex]3\text{cis}\left(80^{\circ}\right)\text{, }3\text{cis}\left(200^{\circ}\right)\text{, }3\text{cis}\left(320^{\circ}\right)[/latex]

43. [latex]2\sqrt[3]{4}\text{cis}\left(\frac{2\pi}{9}\right)\text{, }2\sqrt[3]{4}\text{cis}\left(\frac{8\pi}{9}\right)\text{, }2\sqrt[3]{4}\text{cis}\left(\frac{14\pi}{9}\right)[/latex]

45. [latex]2\sqrt{2}\text{cis}\left(\frac{7\pi}{8}\right)\text{, }2\sqrt{2}\text{cis}\left(\frac{15\pi}{8}\right)[/latex]

47.
Plot of -3 -3i in the complex plane (-3 along real axis, -3 along imaginary axis).

49.
Plot of -1 -5i in the complex plane (-1 along real axis, -5 along imaginary axis).

51.
Plot of 2i in the complex plane (0 along the real axis, 2 along the imaginary axis).

53.
Plot of 6-2i in the complex plane (6 along the real axis, -2 along the imaginary axis).

55.
Plot of 1-4i in the complex plane (1 along the real axis, -4 along the imaginary axis).

57. [latex]3.61e^{−0.59i}[/latex]

59. [latex]−2+3.46i[/latex]

61. [latex]−4.33−2.50i[/latex]