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 centred at (1,0) or radius 1. You will...

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

Demonstrate that the curve r=4sin(θ) is a circle centred at (0,2)of radius 2.

Demonstrate that the curve r=4sin(θ) is a circle centred at (0,2)of radius 2.

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.

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

1.     Given a circle centered at C with a radius of r and a point P outside of the circle. If segment PT is tangent to the circle at T show that the power of point P with respect to the circle is equal to PT squared.

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...

Find the exact area of the region inside the circle r=2cos(theta) but outside the circle r=1

Find the exact area of the region inside the circle r=2cos(theta) but outside the circle r=1

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...

A thin ring of radius R in the x − y plane is centered at the...

A thin ring of radius R in the x − y plane is centered at the coordinate origin, and is charged with linear charge density λ which depends on the polar angle θ as λ(θ) = λ0 sin(θ), where λ0 > 0. (a) Sketch λ(θ) for θ ∈ [0, 2π]. (b) Before doing any calculations, sketch the E~ x and E~ y vector components of the electric field at the coordinate origin, as well as where (roughly) you expect the...

Describe the shape of the parametrically defined curve (eg, upper half of circle with radius =...

Describe the shape of the parametrically defined curve (eg, upper half of circle with radius = 3, centered at (1, -2) ) and sketch. x(t) = 5cos(t) + 5; y(t) = 5sin(t) – 2, -pi <= t <= pi.

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)