1.     Given a circle centered at C with a radius of r and a point P...

A particle in R^2 travels along a circle centered at (x, y) with radius r >...

A particle in R^2 travels along a circle centered at (x, y) with radius r > 0. Parametrize this circular path r(t) as a function of the parameter variable t. Please prove that at all t values, the tangent vector r'(t) is orthogonal to the vector r(t) - vector(x, y)

particle in R2 travels along a circle centered at (h,k) with radius a > 0. Parametrize...

particle in R2 travels along a circle centered at (h,k) with radius a > 0. Parametrize this circular path r(t) as a function of the parameter variable t. Please prove that at all t values, the tangent vector r0(t) is orthogonal to the vector r(t)−<h,k>

Problem 2. Let C be the circle of radius 100, centered at the origin and positively...

Problem 2. Let C be the circle of radius 100, centered at the origin and positively oriented. The goal of this problem is to compute Z C 1 z 2 − 3z + 2 dz. (i) Decompose 1 z 2−3z+2 into its partial fractions. (ii) Compute R C1 1 z−1 dz and R C2 1 z−2 dz, where C1 is the circle of radius 1/4, centered at 1 and positively oriented, and C2 is the circle of radius 1/4, centered...

1.    A point is chosen at random in the interior of a circle of radius R....

1.    A point is chosen at random in the interior of a circle of radius R. The probability that the point falls inside a given region situated in the interior of the circle is proportional to the area of this region. Find the probability that: a)    The point occurs at a distance less than r (r>R) from the center b)    The smaller angle between a given direction and the line joining the point to the center does not exceed α.

Demonstrate that the curve r=2cos(θ) is a circle centered at (1,0) or radius 1. You will...

Demonstrate that the curve r=2cos(θ) is a circle centered at (1,0) or radius 1. You will NOT receive any partial credit for a correct sketch.

Evaluate ∫c(1−xy/2)dS where C is the upper half of the circle centered at the origin with...

Evaluate ∫c(1−xy/2)dS where C is the upper half of the circle centered at the origin with radius 1 with the clockwise rotation followed by the line segment from (1,0)to (3,0) which in turn is followed by the lower half of the circle centerd at the origin of radius 3 with clockwise rotation.

If a circle C with radius 1 rolls along the outside of the circle x2 +...

If a circle C with radius 1 rolls along the outside of the circle x2 + y2 = 49, a fixed point P on C traces out a curve called an epicycloid, with parametric equations x = 8 cos(t) − cos(8t), y = 8 sin(t) − sin(8t). Use one of the formulas below to find the area it encloses. A = C x dy = −C  y dx = 1/2 C x dy − y dx

Find a vector parametrization of the circle of radius 5 in the xy-plane, centered at (−4,2),...

Find a vector parametrization of the circle of radius 5 in the xy-plane, centered at (−4,2), oriented counterclockwise. The point (1,2) should correspond to t=0. Use t as the parameter in your answer. find r⃗ (t)=

a) Find the parametric equations for the circle centered at (1,0) of radius 2 generated clockwise...

a) Find the parametric equations for the circle centered at (1,0) of radius 2 generated clockwise starting from (1+21/2 , 21/2). <---( one plus square root 2, square root 2) b) When given x(t) = tcost, y(t) = sint, 0 <_ t. Find dy/dx as a function of t. c) When given the parametric equations x(t) = eatsin2*(pi)*t, y(t) = eatcos2*(pi)*t where a is a real number. Find the arc length as a function of a for 0 <_ t...

The curve C1 is the circle in R 2 of radius 2 centered at the origin,...

The curve C1 is the circle in R 2 of radius 2 centered at the origin, directed counterclockwise; the curve C2 is the hexagon in R 2 with vertices (4, −4), (4, 4), (0, 6), (−4, 4), (−4, −4), (0, −6), directed counterclockwise; and F(x, y) = (y/(x^2 + y^2))i − (x/(x^2+y^2))j. (a) Evaluate R C1 F · dr. (b) Evaluate R C2 F · dr.