curvature of (t, 3 cos(t), sin(t))

Consider the following vector function. r(t) = 6t2, sin(t) − t cos(t), cos(t) + t sin(t)...

Consider the following vector function. r(t) = 6t2, sin(t) − t cos(t), cos(t) + t sin(t) ,    t > 0 (a) Find the unit tangent and unit normal vectors T(t) and N(t). T(t) = N(t) = (b) Use this formula to find the curvature. κ(t) =

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))

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 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.

r(t)=[cos(t),sin(t),cos(3t)] r(t)=[tcos(t),tsin(t),t) r(t)=[cos(t),sin(t),t2] r(t)=[t2cos(t),t2sin(t),t] r(t)=[cos(t),t,sin(t)] Sketch the graphs.

r(t)=[cos(t),sin(t),cos(3t)] r(t)=[tcos(t),tsin(t),t) r(t)=[cos(t),sin(t),t2] r(t)=[t2cos(t),t2sin(t),t] r(t)=[cos(t),t,sin(t)] Sketch the graphs.

If u(t) = sin(6t), cos(2t), t and v(t) = t, cos(2t), sin(6t) , use Formula 4...

If u(t) = sin(6t), cos(2t), t and v(t) = t, cos(2t), sin(6t) , use Formula 4 of this theorem to find d dt u(t) · v(t) .

Differential equations Given that x1(t) = cos t is a solution of (sin t)x′′ − 2(cos...

Differential equations Given that x1(t) = cos t is a solution of (sin t)x′′ − 2(cos t)x′ − (sin t)x = 0, find a second linearly independent solution of this equation.

A particle is moving according to the given data a(t) = sin t + 3 cos...

A particle is moving according to the given data a(t) = sin t + 3 cos t, x(0) = 0, v(0) = 2. where a(t) represents the acceleration of the particle at time t. Find v(t), the velocity of the particle at time t, and x(t), the position of the particle at time t.

Solve the initial value problem 2(sin(t)dydt+cos(t)y)=cos(t)sin^3(t) for 0<t<π0<t<π and y(π/2)=13.y(π/2)=13. Put the problem in standard form....

Solve the initial value problem 2(sin(t)dydt+cos(t)y)=cos(t)sin^3(t) for 0<t<π0<t<π and y(π/2)=13.y(π/2)=13. Put the problem in standard form. Then find the integrating factor, ρ(t)= and finally find y(t)=

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.