Suppose the point [latex]\left(r,\theta \right)[/latex] is on the graph of [latex]r=3\sin\left(2\theta \right)[/latex].

1. To test for symmetry about the polar axis, first try replacing [latex]\theta[/latex] with [latex]-\theta[/latex]. This gives [latex]r=3\sin\left(2\left(-\theta \right)\right)=-3\sin\left(2\theta \right)[/latex]. Since this changes the original equation, this test is not satisfied. However, returning to the original equation and replacing [latex]r[/latex] with [latex]-r[/latex] and [latex]\theta[/latex] with [latex]\pi -\theta[/latex] yields
   
   [latex]\begin{array}{}\\ -r=3\sin\left(2\left(\pi -\theta \right)\right)\hfill \\ -r=3\sin\left(2\pi -2\theta \right)\hfill \\ -r=3\sin\left(-2\theta \right)\hfill \\ -r=-3\sin2\theta .\hfill \end{array}[/latex]

   
   
   Multiplying both sides of this equation by [latex]-1[/latex] gives [latex]r=3\sin2\theta[/latex], which is the original equation. This demonstrates that the graph is symmetric with respect to the polar axis.

2. To test for symmetry with respect to the pole, first replace [latex]r[/latex] with [latex]-r[/latex], which yields [latex]-r=3\sin\left(2\theta \right)[/latex]. Multiplying both sides by −1 gives [latex]r=-3\sin\left(2\theta \right)[/latex], which does not agree with the original equation. Therefore the equation does not pass the test for this symmetry. However, returning to the original equation and replacing [latex]\theta[/latex] with [latex]\theta +\pi[/latex] gives
   
   [latex]\begin{array}{cc}\hfill r& =3\sin\left(2\left(\theta +\pi \right)\right)\hfill \\ & =3\sin\left(2\theta +2\pi \right)\hfill \\ & =3\left(\sin2\theta \cos2\pi +\cos2\theta \sin2\pi \right)\hfill \\ & =3\sin2\theta .\hfill \end{array}[/latex]

   
   
   Since this agrees with the original equation, the graph is symmetric about the pole.

3. To test for symmetry with respect to the vertical line [latex]\theta =\frac{\pi }{2}[/latex], first replace both [latex]r[/latex] with [latex]-r[/latex] and [latex]\theta[/latex] with [latex]-\theta[/latex].
   
   [latex]\begin{array}{}\\ -r=3\sin\left(2\left(-\theta \right)\right)\hfill \\ -r=3\sin\left(-2\theta \right)\hfill \\ -r=-3\sin2\theta .\hfill \end{array}[/latex]

   
   
   Multiplying both sides of this equation by [latex]-1[/latex] gives [latex]r=3\sin2\theta[/latex], which is the original equation. Therefore the graph is symmetric about the vertical line [latex]\theta =\frac{\pi }{2}[/latex].

This graph has symmetry with respect to the polar axis, the origin, and the vertical line going through the pole. To graph the function, tabulate values of [latex]\theta[/latex] between 0 and [latex]\frac{\pi}{2}[/latex] and then reflect the resulting graph.

This gives one petal of the rose, as shown in the following graph.

Reflecting this image into the other three quadrants gives the entire graph as shown.