let r(t)=<cos(2t),sin(2t),3> describe the shape of the path of motion of the object. how far has...

a(t) = 2e^ −t + 4 cos(2t) − sin(2t). Find the initial acceleration at t =...

a(t) = 2e^ −t + 4 cos(2t) − sin(2t). Find the initial acceleration at t = 0. If time is measured in seconds and distance is measured in meters, what units is your answer in? Find the velocity v(t) of the object given an initial velocity of 2 meters per second. Find the position s(t) of the object given an initial position of 0 meters.

Consider the parameterized motion given by r(t)=3t^2i-2t^2j+(6-t^3)k. Where is the object at time t=1? What is...

Consider the parameterized motion given by r(t)=3t^2i-2t^2j+(6-t^3)k. Where is the object at time t=1? What is the velocity at t=1? What is the speed at t=1? How far does the object move from 0≤t≤1? Round your answer to 2 decimal places. * r, i, j, and k should all have vector arrows above them

find t? x= 2cos(t)+ sin(2t) y=2sin(t)+cos(2t) when x= 0, y= -3

find t? x= 2cos(t)+ sin(2t) y=2sin(t)+cos(2t) when x= 0, y= -3

The position of an object in circular motion is modeled by the given parametric equations. Describe...

The position of an object in circular motion is modeled by the given parametric equations. Describe the path of the object by stating the radius of the circle, the position at time t = 0, the orientation of the motion (clockwise or counterclockwise), and the time t that it takes to complete one revolution around the circle. x = sin(4t), y = cos(4t) what is the radius of the circle? what is the position at time t = 0 (x,...

6.) Let ~r(t) =< 3 cos t, -2 sin t > for 0 < t <...

6.) Let ~r(t) =< 3 cos t, -2 sin t > for 0 < t < pi. a) Sketch the curve. Make sure to pay attention to the parameter domain, and indicate the orientation of the curve on your graph. b) Compute vector tangent to the curve for t = pi/4, and sketch this vector on the graph.

1. a) Get the arc length of the curve. r(t)= (cos(t) + tsin(t), sin(t) - tcos(t),...

1. a) Get the arc length of the curve. r(t)= (cos(t) + tsin(t), sin(t) - tcos(t), √3/2 t^2) in the Interval 1 ≤ t ≤ 4 b) Get the curvature of r(t) = (e^2t sen(t), e^2t, e^2t cos (t))

Let a > b. Suppose a particle moves in an elliptical path given by r(t) =...

Let a > b. Suppose a particle moves in an elliptical path given by r(t) = (a cos ωt) i+(b sin ωt) j where ω > 0. Sketch its velocity and acceleration vectors at one of the vertices of the ellipse (±a, 0).

Find r(t) for the given conditions. r''(t) = −7 cos(t)j − 3 sin(t)k,     r'(0) = 3k,     r(0) =...

Find r(t) for the given conditions. r''(t) = −7 cos(t)j − 3 sin(t)k,     r'(0) = 3k,     r(0) = 7j

Let r(t) = 1/2t ,4t^1/2 ,2t be a position function for some object. (a) (2 pts)...

Let r(t) = 1/2t ,4t^1/2 ,2t be a position function for some object. (a) (2 pts) Find the position of the object at t = 1. (b) (6 pts) Find the velocity of the object at t = 1. (c) (6 pts) Find the acceleration of the object at t = 1. (d) (6 pts) Find the speed of the object at t = 1. (e) (15 pts) Find the curvature K of the graph C determined by r(t) when...

Let C be a closed curve parametrized by r(t) = sin ti+cos tj with 0 ≤...

Let C be a closed curve parametrized by r(t) = sin ti+cos tj with 0 ≤ t ≤ 2π. Let F = yi − xj be a vector field. (a) Evaluate the line integral xyds. C (b) Find the circulation of F over C. (c) Find the flux of F over C.