# How to draw line 'y=x' using PolarPlot in mathematica?

Because `PolarPlot` should type r=... type of command.

But y=x will cause r to disappear.

How to draw that line with `PolarPlot`?

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Could you explain a bit of what you're trying to accomplish? There may be a better way of doing what you want. – Mike Bantegui Dec 15 '11 at 4:44
Sorry for the unclear question. I want a general form that I can draw the picture that r is elimiated. Example 1: rcosx=rsin(2x). Example 2: rsin(3x)=rcos(x)*sin(2x). All the example's r is disappeared. Now thank for many people give answers to me, but I haven't understand which is the better way for my question clearly. – sam Jan 21 '12 at 3:13

I suggest you use a new function for things like this.

``````PolarParametricPlot[
{rT : {_, _} ..} | rT : {_, _},
uv : {_, _, _} ..,
opts : OptionsPattern[]
] :=
ParametricPlot[
Evaluate[# {Cos@#2, Sin@#2} & @@@ {rT}],
uv,
opts
]
``````

Usage:

``````PolarParametricPlot[{t, 45 Degree}, {t, -10, 10}]
``````

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@Harm You could also just turn off that message completely as there is apparently no good reason for it. Similarly I believe most people turned off `General::spell1` after a while. – Mr.Wizard Dec 15 '11 at 11:34
@Harm thanks for the vote, but I didn't mean to twist your arm, and I agree with you about concise solutions. I wrote/adapted `PolarParametricPlot` before `PolarPlot` was introduced, and I still find it useful. I don't know of a more concise approach for this family of plots. – Mr.Wizard Dec 15 '11 at 12:11
@Harm, PolarPlot was added in version 6. – Mr.Wizard Dec 15 '11 at 12:40

First, consider `Plot[]` which "generates a plot of f as a function of x from xmin to xmax" (I'm quoting the Mathematica documentation). You can't use it to plot a vertical line satisfying the equation x = x0, because the latter is not a function of x: instead of being single-valued, it has infinitely many values at x0.

Similarly, `PolarPlot[]` cannot be used to draw a straight line that passes through the origin, because its equation is not a function of θ: it has infinitely many values at a particular θ (equal to Pi/4 in the case requested), but none at all elsewhere. (Well, one could also allow the complementary angle 3Pi/4 as well.)

So I maintain it can't be done using the tools specified, short of the cheat

``````PolarPlot[0, {\[Theta], 0, 1},
Epilog -> Line[{Scaled[{1, 1}], Scaled[{0, 0}]}]]
``````
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You can plot vertical lines using `ParamtericPlot`. Technically `PolarPlot` and `Plot` are just special cases of `ParametricPlot` – Mike Bantegui Dec 15 '11 at 4:49
How to use ParamtericPlot to plot r=1 & x=y ? What the example I found is too difficult to understand... – sam Dec 15 '11 at 15:07

Here is the general polar form for a line of the form y = m x + b:

``````In[155]:= r /.
Solve[Eliminate[{x == r Cos[t], y == r Sin[t], y == m x + b}, {x,
y}], r]

Out[155]= {-(b/(m Cos[t] - Sin[t]))}
``````

The solution vanishes when the y-intercept b is zero. This makes sense, since such lines are drawn at a constant angle, which is problematic since `PolarPlot` works by varying the angle.

You could approximate such a line by using a very small value for b, but there are probably better approaches.

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Trying to plot the solution `y == x` with this is also problematic because it deviates ever so slightly no matter what b you choose. – Mike Bantegui Dec 15 '11 at 4:45
This solution seems great as general form,but how to draw picture by this method? Thank you~ – sam Jan 13 '12 at 4:18

You could draw the line using `ListPolatPlot`:

``````ListPolarPlot[{{Pi/4, 5}, {5 Pi/4, 5}}, Joined -> True]
``````
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