2. (12 pts.)If r"(t) = 〈1, t, sin(t)〉 , r'(0) = 〈2, 3, 1〉 and r(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

The curve r(t) = <sin(t),sin(t+sin(t))> intersects itself at (0, 0). Find the acute angle (in radians)...

The curve r(t) = <sin(t),sin(t+sin(t))> intersects itself at (0, 0). Find the acute angle (in radians) at which the curve intersects

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.

3.2) If a(t)=<-1/(t+1)^2, sec^3 t+ tan^2 t sec t,-t sin t+ 2 cos t- 2> represents...

3.2) If a(t)=<-1/(t+1)^2, sec^3 t+ tan^2 t sec t,-t sin t+ 2 cos t- 2> represents the acceleration of a particle at time t with v(0)=〈2,-1, 0〉 and r(0)=〈0, 2, 0〉 then find the distance from the the particle to the plane 2x- 3y+z= 10 at t= 1 (ie Find the Distance from the particle to the Plane)

. Find the arc length of the curve r(t) = <t^2 cos(t), t^2 sin(t)> from the...

. Find the arc length of the curve r(t) = <t^2 cos(t), t^2 sin(t)> from the point (0, 0) to (−π^2 , 0).

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...

17.)Find the curvature of r(t) at the point (1, 0, 0). r(t) = et cos(t), et...

17.)Find the curvature of r(t) at the point (1, 0, 0). r(t) = et cos(t), et sin(t), 3t κ =

Consider the curve r(t) = cost(t)i + sin(t)j + (2/3)t2/3k Find: a. the length of the...

Consider the curve r(t) = cost(t)i + sin(t)j + (2/3)t2/3k Find: a. the length of the curve from t = 0 to t = 2pi. b. the equation of the tangent line at the point t = 0. c. the speed of the point moving along the curve at the point t = 2pi

Letr(t)=(4t2+1)i+2tjfor−2≤t≤2. (a) (10 pts) Draw a sketch of the curve C determined by r(t). (b) (5...

Letr(t)=(4t2+1)i+2tjfor−2≤t≤2. (a) (10 pts) Draw a sketch of the curve C determined by r(t). (b) (5 pts) Plot r(0) and label its endpoint P. (c) (10 pts) Plot the vector tangent to C at P . (d) (10 pts) Find the equation of the line tangent to C at P (you may give this parametrically or not). (e) (5 pts) Find the curvature K at P . (f) (5 pts) Find the radius of curvature ρ at P. (g) (5...

Consider the ellipse r(t) =〈3 cos(t),4 sin(t)〉, for 0 ≤ t ≤ 2π. (a) At what...

Consider the ellipse r(t) =〈3 cos(t),4 sin(t)〉, for 0 ≤ t ≤ 2π. (a) At what positions does ‖r′(t)‖ have maximum and minimum values, that is, where is a particle moving along the ellipse moving the fastest and slowest? Your answer will be vectors. (b) At what positions does the curvature have maximum and minimum values? Your answer will be vectors.