Osculating Circle: Show that P = 1/n. If r(t) is the position vector associated with the curve, write OC in terms of r, p and N. Consider the helix of parametric equations x = 2sin3t, y=t z=2cos3t Find the equation of the plane containing the osculating circle to the curve at the point (0, pi, -2).

Show transcribed image text Osculating Circle: Show that P = 1/n. If r(t) is the position vector associated with the curve, write OC in terms of r, p and N. Consider the helix of parametric equations x = 2sin3t, y=t z=2cos3t Find the equation of the plane containing the osculating circle to the curve at the point (0, pi, -2).

Let P be a point on a curve C with parametrization r(t) and let ?P be the curvature at point P. If ?P 0, then there is a unique circle through P, called the osculating circle, denoted OscP, which has the following properties. OscP and C have the same tangent line and unit normal vectors at P. Both OscP and C have the same curvature kP at P. The osculating circle is the circle that "best fits" the curve at P, whose radius is R = kP-1. The value R is called the radius of curvature at P. The center of OscP should be located at a distance R from P in the normal direction, and so it is located at r(t0) + kP-1 N(t0). In addition, the osculating circle lies on the plane spanned by the unit tangent and unit normal vectors T(t) and N(t), respectively, named the osculating plane. Figure 1: The osculating circle of f(x) = x2 at x = 0. For r(t) = t2, t, t , find the following. The curvature ?(t). The center of the osculating circle. The equation of the osculating plane.

1) The velocity of a particle can be modeled by v(t) (4t3-15t2 + 1,3-t, 1-t-3 Find the particle's position when its acceleration is(-12.-1.-13), given that at time t-0 the particle's position is (1,-2, 3) 2) Two particles travel along r(t) = (t, t2.t*) and r2(t)-(1 + 2t, 1 + 6t, 1 + 14t). Find the coordinate(s) of their collision and path intersection. If neither is possible, explain why. 3) Find the point(s) where the radius of an osculating circle to the given space curve is 17. Round your final answers to 4 decimals. r(t)-(1 + 21,t2, 3-12》 4) Find vectors u and u such that the vectors are perpendicular to each other and to 《2,-3,7). 5) Consider the curve f(x) = ex. Find the exact x-value where the radius of the osculating circle is a minimum.

1) The velocity of a particle can be modeled by v(t) (4t3-15t2 + 1,3-t, 1-t-3 Find the particle's position when its acceleration is(-12.-1.-13), given that at time t-0 the particle's position is (1,-2, 3) 2) Two particles travel along r(t) = (t, t2.t*) and r2(t)-(1 + 2t, 1 + 6t, 1 + 14t). Find the coordinate(s) of their collision and path intersection. If neither is possible, explain why. 3) Find the point(s) where the radius of an osculating circle to the given space curve is 17. Round your final answers to 4 decimals. r(t)-(1 + 21,t2, 3-12》 4) Find vectors u and u such that the vectors are perpendicular to each other and to 《2,-3,7). 5) Consider the curve f(x) = ex. Find the exact x-value where the radius of the osculating circle is a minimum.