Note that we can rewrite the given complex fraction as: [latex]\dfrac{2}{3}\div\dfrac{1}{6}[/latex]

Now, multiply by the receprocal.

Keep [latex]\dfrac{2}{3}[/latex]

Change  [latex]\div[/latex] to  [latex]\cdot[/latex]

Flip [latex]\dfrac{1}{6}[/latex]

[latex]\dfrac{2}{3}\cdot\dfrac{6}{1}[/latex]

Multiply numerators and multiply denominators.

[latex]\dfrac{2\cdot6}{3\cdot1}=\dfrac{12}{3}[/latex]

Simplify.

[latex]\dfrac{12}{3}=\normalsize 4[/latex]

Note that we can rewrite the given complex fraction as: [latex]\dfrac{3}{5}\div\dfrac{2}{1}[/latex]

Multiply by the reciprocal.

Keep [latex]\dfrac{3}{5}[/latex], change [latex]\div[/latex] to [latex]\cdot[/latex], and flip [latex]2[/latex].

[latex]\dfrac{3}{5}\cdot\dfrac{1}{2}[/latex]

Multiply numerators and multiply denominators.

[latex]\dfrac{3\cdot 1}{5\cdot 2}=\dfrac{3}{10}[/latex]

Without looking at a graph, we can determine whether the function is even or odd by finding formulas for the reflections and determining if they return us to the original function. Let’s begin with the rule for even functions.

[latex]f\left(-x\right)={\left(-x\right)}^{3}+2\left(-x\right)=-{x}^{3}-2x[/latex]

This does not return us to the original function, so this function is not even. We can now test the rule for odd functions.

[latex]-f\left(-x\right)=-\left(-{x}^{3}-2x\right)={x}^{3}+2x[/latex]

Because [latex]-f\left(-x\right)=f\left(x\right)[/latex], this is an odd function.

Analysis of the Solution

Consider the graph of [latex]f[/latex]. Notice that the graph is symmetric about the origin. For every point [latex]\left(x,y\right)[/latex] on the graph, the corresponding point [latex]\left(-x,-y\right)[/latex] is also on the graph. For example, (1, 3) is on the graph of [latex]f[/latex], and the corresponding point [latex]\left(-1,-3\right)[/latex] is also on the graph.