How do you find a parametric equation for a particle moving twice counter-clockwise around the circle #(x-2)^2 + (y+1)^2 = 9# starting at (-1,-1)?

1 Answer
Feb 22, 2017

# {: (x = 2+ 3cost),(y = -1 + 3sint) :} } \ \ \pi le t le 5pi #

Explanation:

The Cartesian equation of a circle with centre #(a,b)# and radius #r# is:

# (x-a)^2 + (y-a)^2 = r^2 #

And so the equation:

# (x-2)^2 + (y+1)^2 = 9 #

represents a circle of centre #(2,-1)# and radius #3#

The parametric equations of a circle of centre #(0,0)# and radius #r# are;

# x = rcost #
# y = rsint #

This can easily be verified, as:

# x^2 + y^2 = (rcost)^2 + (rsint)^2 #
# " "= r^2cos^2t + r^2sin^2t #
# " "= r^2(cos^2t + sin^2t) #
# " "= r^2 \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ (because cos^2t + sin^2t -= 1) #

And so the parametric equations of circle centre #(a,b)# and radius #r# are simply:

# x = a+ rcost #
# y = b+ rsint #

And so the required equations are:

# x = 2+ 3cost #
# y = -1 + 3sint #

(NB If we swap the #sin"/"cos# we can change the direction of travel; as it happens the order we have chosen will cause an anti-clockwise trajectory).

We require that particle to start at #(-1,-1)# which correspond to a start parameter #t=pi# relative to the centre #(2,-1)#, and we need two full revolutions, and so the end parameter is #t=pi+2*2pi=5pi#

Hence we have:

# {: (x = 2+ 3cost),(y = -1 + 3sint) :} } \ \ \pi le t le 5pi #

The following shows the plot
https://www.desmos.com/calculator/a15yobsjcj