Need help with a parametric equation question thanks (1 Viewer)

Bigboigood · Sep 26, 2020

This question has me pretty stumped. It's question 14 d) from the Sydney Girls High School 2020 Maths Extension 1 Paper:
Find the cartesian equation of the curve with the parametric equations:
x=4cos(theta)-sin(theta) y=5cos(theta)+sin(theta)

Sorry for the terrible formatting and thanks in advance.

Greninja340 · Sep 26, 2020

could you just solve both of them for sin(theta) and then equate them and solve for y

Bigboigood · Sep 26, 2020

There would still be a cos(theta) in the equation wouldn't there?

fan96 · Sep 26, 2020

Observe that

$x + y = 9 \cos \theta$

$5x - 4y = -9 \sin \theta$

so

$\left(x+y\right)^2+\left(5x-4y\right)^2=81.$

cossine · Sep 26, 2020

x = 4*cos(theta) - sin(theta)

Use the theorem:
cos(theta + phi) = cos(theta)*cos(phi) - sin(theta)*sin(phi)

=> r*cos(theta + phi) = r*cos(theta)*cos(phi) - r*sin(theta)*sin(phi)

Equate

x = r*cos(theta)*cos(phi) - r*sin(theta)*sin(phi)

=> r*cos(phi) = 4, r*sin(phi) =1

Therefore (r^2)*cos^2(phi) + (r^2)*sin^2(phi) = 17

Using theorem: sin^2(theta) + cos^2(theta) = 1

=> r = sqrt(17)

tan(phi) = (r*sin(phi))/ (r*cos(phi) ) = 1/4

Using theorem (f^-1( f(x) ) = x ):

=> phi = tan^-1(1/4)

Therefore x = sqrt(17)*cos(theta + tan^-1(1/4))

=> cos^-1( x/sqrt(17) ) - tan^-1(1/4) = theta

Substitute the expression for theta into y

fan96 · Sep 27, 2020

cossine said:
Therefore x = sqrt(17)*cos(theta + tan^-1(1/4))

=> cos^-1( x/sqrt(17) ) - tan^-1(1/4) = theta

Substitute the expression for theta into y

If you plot this using software the graph you get is not the same as the original parametric equation.
(You only get the upper half of the graph.)

cossine said:
Using theorem (f^-1( f(x) ) = x ):
...
Therefore x = sqrt(17)*cos(theta + tan^-1(1/4))
=> cos^-1( x/sqrt(17) ) - tan^-1(1/4) = theta

This theorem requires $f$ to be invertible wherever $x$ is defined.
The input $\theta + \arctan(1/4)$ varies over an interval of length $2\pi$ , where $\cos$ does not have an inverse.

Perhaps an easier way to state this is that if $\theta = \arccos(x/\sqrt{17})-\arctan(1/4)$ then the range of $\theta$ is an interval of length $\pi$ , yet to get the entire graph of the curve we want we must take $\theta$ over a range of length at least $2\pi$ .

This problem is fixed by adding a $2\pi \pm$ in front, so

$\theta = (2\pi \pm \arccos(x/\sqrt{17}))-\arctan(1/4).$

cossine · Sep 27, 2020

fan96 said:
If you plot this using software the graph you get is not the same as the original parametric equation.
(You only get the upper half of the graph.)

This theorem requires $f$ to be invertible wherever $x$ is defined.
The input $\theta + \arctan(1/4)$ varies over an interval of length $2\pi$ , where $\cos$ does not have an inverse.

Perhaps an easier way to state this is that if $\theta = \arccos(x/\sqrt{17})-\arctan(1/4)$ then the range of $\theta$ is an interval of length $\pi$ , yet to get the entire graph of the curve we want we must take $\theta$ over a range of length at least $2\pi$ .

This problem is fixed by adding a $2\pi \pm$ in front, so

$\theta = (2\pi \pm \arccos(x/\sqrt{17}))-\arctan(1/4).$

Thank you

Need help with a parametric equation question thanks (1 Viewer)

Bigboigood

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Greninja340

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