Respuesta :
Answer:
[tex]x=2\cos(t)[/tex] and [tex]y=-2\sin(t)+1[/tex]
Step-by-step explanation:
[tex](x-h)^2+(y-k)^2=r^2[/tex] has parametric equations:
[tex](x-h)=r\cos(t) \text{ and } (y-k)=r\sin(t)[/tex].
Let's solve these for x and y  respectively.
[tex]x-h=r\cos(t)[/tex] can be solved for x by adding h on both sides:
[tex]x=r\cos(t)+h[/tex].
[tex]y-k=r \sin(t)[/tex] can be solve for y by adding k on both sides:
[tex]y=r\sin(t)+k[/tex].
We can verify this works by plugging these back in for x and y respectively.
Let's do that:
[tex](r\cos(t)+h-h)^2+(r\sin(t)+k-k)^2[/tex]
[tex](r\cos(t))^2+(r\sin(t))^2[/tex]
[tex]r^2\cos^2(t)+r^2\sin^2(t)[/tex]
[tex]r^2(\cos^2(t)+\sin^2(t))[/tex]
[tex]r^2(1)[/tex] By a Pythagorean Identity.
[tex]r^2[/tex] which is what we had on the right hand side.
We have confirmed our parametric equations are correct.
Now here your h=0 while your k=1 and r=2.
So we are going to play with these parametric equations:
[tex]x=2\cos(t)[/tex] and [tex]y=2\sin(t)+1[/tex]
We want to travel clockwise so we need to put -t and instead of t.
If we were going counterclockwise it would be just the t.
[tex]x=2\cos(-t)[/tex] and [tex]y=2\sin(-t)+1[/tex]
Now cosine is even function while sine is an odd function so you could simplify this and say:
[tex]x=2\cos(t)[/tex] and [tex]y=-2\sin(t)+1[/tex].
We want to find [tex]\theta[/tex] such that
[tex]2\cos(t-\theta_1)=2 \text{ while } -2\sin(t-\theta_2)+1=1[/tex] when t=0.
Let's start with the first equation:
[tex]2\cos(t-\theta_1)=2[/tex]
Divide both sides by 2:
[tex]\cos(t-\theta_1)=1[/tex]
We wanted to find [tex]\theta_1[/tex] for when [tex]t=0[/tex]
[tex]\cos(-\theta_1)=1[/tex]
Cosine is an even function:
[tex]\cos(\theta_1)=1[/tex]
This happens when [tex]\theta_1=2n\pi[/tex] where n is an integer.
Let's do the second equation:
[tex]-2\sin(t-\theta_2)+1=1[/tex]
Subtract 2 on both sides:
[tex]-2\sin(t-\theta_2)=0[/tex]
Divide both sides by -2:
[tex]\sin(t-\theta_2)=0[/tex]
Recall we are trying to find what [tex]\theta_2[/tex] is when t=0:
[tex]\sin(0-\theta_2)=0[/tex]
[tex]\sin(-\theta_2)=0[/tex]
Recall sine is an odd function:
[tex]-\sin(\theta_2)=0[/tex]
Divide both sides by -1:
[tex]\sin(\theta_2)=0[/tex]
[tex]\theta_2=n\pi[/tex]
So this means we don't have to shift the cosine parametric equation at all because we can choose n=0 which means [tex]\theta_1=2n\pi=2(0)\pi=0[/tex].
We also don't have to shift the sine parametric equation either since at n=0, we have [tex]\theta_2=n\pi=0(\pi)=0[/tex].
So let's see what our equations look like now:
[tex]x=2\cos(t)[/tex] and [tex]y=-2\sin(t)+1[/tex]
Let's verify these still work in our original equation:
[tex]x^2+(y-1)^2[/tex]
[tex](2\cos(t))^2+(-2\sin(t))^2[/tex]
[tex]2^2\cos^2(t)+(-2)^2\sin^2(t)[/tex]
[tex]4\cos^2(t)+4\sin^2(t)[/tex]
[tex]4(\cos^2(t)+\sin^2(t))[/tex]
[tex]4(1)[/tex]
[tex]4[/tex]
It still works.
Now let's see if we are being moving around the circle once around for values of t between [tex]0[/tex] and [tex]2\pi[/tex].
This first table will be the first half of the rotation.
t          0            pi/4         pi/2        3pi/4        pi Â
x          2           sqrt(2)       0          -sqrt(2)       -2
y          1           -sqrt(2)+1      -1          -sqrt(2)+1       1
Ok this is the fist half of the rotation. Â Are we moving clockwise from (2,1)?
If we are moving clockwise around a circle with radius 2 and center (0,1) starting at (2,1) our x's should be decreasing and our y's should be decreasing at the beginning we should see a 4th of a circle from the point (x,y)=(2,1) and the point (x,y)=(0,-1).
Now after that 4th, the x's will still decrease until we make half a rotation but the y's will increase as you can see from point (x,y)=(0,-1) to (x,y)=(-2,1). Â We have now made half a rotation around the circle whose center is (0,1) and radius is 2.
Let's look at the other half of the circle:
t         pi        5pi/4          3pi/2       7pi/4           2pi
x        -2        -sqrt(2)         0         sqrt(2)            2
y         1         sqrt(2)+1       3          sqrt(2)+1          1
So now for the talk half going clockwise we should see the x's increase since we are moving right for them. Â The y's increase after the half rotation but decrease after the 3/4th rotation.
We also stopped where we ended at the point (2,1).
