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Parametrics and Polar curves (1 Viewer)
- Thread starter leehuan
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That's a circle with diameter 6 on the y-axis. Centre is (0, 3), radius is 3.Starting with a dumb question because I think my lecturer forgot to explicitly say how to.
I know what the graph looks like already
But how do I convert this to Cartesian form lol
To derive this, you could replace sin(theta) with y/r, so r = a*(y/r) (in this case a = 6), so r^2 = ay, that is, x^2 + y^2 = ay. Now just moves things around and complete the square to get the circle's Cartesian equation.
We assumed r was non-zero above, since we had r in a denominator. For the r = 0 case, we can get r = 0 at theta = 0 in the polar equation. So the Cartesian point (0, 0) (i.e. the place where r = 0) is part of the curve.
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leehuan
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Oh fair enough, sin(theta)=y/r was what I needed to see.
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represents a cardiod. It has a cusp at (0,0)
doesn't look like it has a cusp though.
Is there any way to deduce by inspection of the equation what's going on? So far I've been relying on my lecturer (for the former) and a graphing software.
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Is there any way to deduce by inspection of the equation what's going on? So far I've been relying on my lecturer (for the former) and a graphing software.
Say the curve is r = a + sin(theta) = f(theta), say.
Now, y = r.sin(theta) = f(theta).sin(theta) and similarly x = f(theta).cos(theta)
Now, dy/d(theta) = f'(theta).sin(theta) + f(theta).cos(theta) = cos(theta).sin(theta) + (a + sin(theta)).cos(theta) = a.cos(theta) + sin(2*theta).
Also, dx/d(theta) = f'(theta).cos(theta) - f(theta).sin(theta) = cos(theta).cos(theta) - (a + sin(theta)).sin(theta) = cos(2*theta) - a.sin(theta).
Now, dy/dx = (dy/d(theta))/(dx/d(theta)) = [a.cos(theta) + sin(2*theta)]/[cos(2*theta) - a.sin(theta)].
At theta = -pi/2, we see that dy/dx is perfectly well-defined if a =/= 1, as it equals [a*0 + 0]/[-1 + a] = 0. So we have a horizontal slope when theta = pi/2 for a =/= 1.
If a = 1, the denominator is 0 at theta = -pi/2 however and we need further investigation, and it turns out we end up with a cusp.
To find where dy/dx may be undefined for arbitrary given a, we can set the denominator of dy/dx to 0 and try and solve for sin(theta) (it'll be a quadratic in sin(theta)) and hence theta.
If you solve the quadratic we get, the solutions should be
sin(theta) = [-a +/- sqrt(a^2 + 8)]/4. For real solutions, we'd need the RHS to be between -1 and 1. You can investigate for which a this will happen. You'll find that at least one of these will always be between -1 and 1 for any real a. These'll usually give places where the tangents are vertical. You can try finding for which a it is possible to have both numerator and denominator of dy/dx be 0 simultaneously. You should find this can only happen if a = +/- 1. For a cusp, we'd need both numerator and denominator to be 0 at a point theta0, and at least one of these (x'(theta) and y'(theta)) should change sign here, which is what happens at -pi/2 for a = +/- 1 cases.
Now, y = r.sin(theta) = f(theta).sin(theta) and similarly x = f(theta).cos(theta)
Now, dy/d(theta) = f'(theta).sin(theta) + f(theta).cos(theta) = cos(theta).sin(theta) + (a + sin(theta)).cos(theta) = a.cos(theta) + sin(2*theta).
Also, dx/d(theta) = f'(theta).cos(theta) - f(theta).sin(theta) = cos(theta).cos(theta) - (a + sin(theta)).sin(theta) = cos(2*theta) - a.sin(theta).
Now, dy/dx = (dy/d(theta))/(dx/d(theta)) = [a.cos(theta) + sin(2*theta)]/[cos(2*theta) - a.sin(theta)].
At theta = -pi/2, we see that dy/dx is perfectly well-defined if a =/= 1, as it equals [a*0 + 0]/[-1 + a] = 0. So we have a horizontal slope when theta = pi/2 for a =/= 1.
If a = 1, the denominator is 0 at theta = -pi/2 however and we need further investigation, and it turns out we end up with a cusp.
To find where dy/dx may be undefined for arbitrary given a, we can set the denominator of dy/dx to 0 and try and solve for sin(theta) (it'll be a quadratic in sin(theta)) and hence theta.
If you solve the quadratic we get, the solutions should be
sin(theta) = [-a +/- sqrt(a^2 + 8)]/4. For real solutions, we'd need the RHS to be between -1 and 1. You can investigate for which a this will happen. You'll find that at least one of these will always be between -1 and 1 for any real a. These'll usually give places where the tangents are vertical. You can try finding for which a it is possible to have both numerator and denominator of dy/dx be 0 simultaneously. You should find this can only happen if a = +/- 1. For a cusp, we'd need both numerator and denominator to be 0 at a point theta0, and at least one of these (x'(theta) and y'(theta)) should change sign here, which is what happens at -pi/2 for a = +/- 1 cases.
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Are there any techniques you could employ to sketch this weird parametric curve?
Cause I couldn't see anything obvious and was basically gonna bombard it with a table of values
These symmetries mean if you were to use a table of values, you'd only need to do so for theta between 0 and pi/4. This gets the image for one 'octant' ('first' octant), and then to complete the image in the first quadrant, reflect it about he 45 degree line y = x. Then reflect this first-quadrant image about the x- and y-axes to get the fourth and second quadrants respectively. Then finally another reflection gives a similar image in the third quadrant.
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seanieg89
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tan(t)=x/y, use this and trig manipulations to eliminate the t in one of the equations if you want to get a cartesian form.Are there any techniques you could employ to sketch this weird parametric curve?
Cause I couldn't see anything obvious and was basically gonna bombard it with a table of values