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Question: Find parametric equations for the tangent line


Find parametric equations for the tangent line to the curve with the given parametric equations at the specified point. Illustrate by graphing both the curve and the tangent line on a common screen.
x = t, y = e-t, z = 2t - t2; (0, 1, 0)


> Match the parametric equations with the graphs (labeled I–VI). Give reasons for your choices. x = t cos t, y = t, z = t sin t, t > 0 ZA

> (a). Find the arc length function for the curve measured from the point P in the direction of increasing t and then reparametrize the curve with respect to arc length starting from P, and (b). find the point 4 units along the curve (in the direction of

> (a). Find the arc length function for the curve measured from the point P in the direction of increasing t and then reparametrize the curve with respect to arc length starting from P, and (b). find the point 4 units along the curve (in the direction of

> Find the derivative of the vector function. r (t) = sin2at i + tebt j + cos2ct k

> Find a vector equation and parametric equations for the line segment that joins P to Q. P (a, b, c), Q (u, v, w)

> Find a vector equation and parametric equations for the line segment that joins P to Q. P (0, -1, 1), Q ( 1 2 , 1 3 , 1 4 )

> Find a vector equation and parametric equations for the line segment that joins P to Q. P (-1, 2, -2), Q (-3, 5, 1)

> Find a vector equation and parametric equations for the line segment that joins P to Q. P (2, 0, 0), Q (6, 2, -2)

> Find the limit. lim ( te, 1 + t ,t sin 2t3 –

> Find the limit. 1 + t? lim -e-21 1- t2' tant, t

> Find the limit. -i+ /t + 8 j + t sin rt k In t lim

> Find the limit. 12 j+ cos 2t k sin't lim (e-3'i

> Find the derivative of the vector function. r (t) = t sin t i + et cos t j + sin t cos t k

> Find the domain of the vector function. 1 k t - 2 r(t) = cos ti + In tj +

> Find the domain of the vector function. г() — ( In(r + 1), - 2' V9 – t²

> Use the formula in Exercise 63(d) to find the torsion of the curve Exercise 63(d): (r' X r") · r" |r' X r"| (d) т r() = (. 늘?. ).

> Use the Frenet-Serret formulas to prove each of the following. (Primes denote derivatives with respect to t. Start as in the proof of Theorem 10.) (a) r" = s"T + K(s')²N (b) r' X r" = K(s')'B (c) r™ = [s" – k°(s')*]T + [3xs's" + k'(s')*]N + KT(s')°B

> Show that the curvature is related to the tangent and normal vectors by the equation dT KN ds

> Find the vectors T, N, and B, at the given point. r(t) = (r?.3r", t), (1.7, 1)

> Use the formula in Exercise 42 to find the curvature. Formula in Exercise 42: x = et cos t, y = et sin t |ty – yx|| K = [t? + y? ]/2

> Use the formula in Exercise 42 to find the curvature. Formula in Exercise 42: x = a cos wt, y = b sin wt |ty – yx|| K = [t? + y? ]/2

> Use the formula in Exercise 42 to find the curvature. Formula in Exercise 42: x = t2, y = t3 |ty – yx|| K = [t? + y? ]/2

> Use Theorem 10 to show that the curvature of a plane parametric curve x = f (t), y = g (f) is where the dots indicate derivatives with respect to t. |ty – yx|| K = [t? + y? ]/2

> Use a graphing calculator or computer to graph both the curve and its curvature function k (x) on the same screen. Is the graph of  what you would expect? y = x-2

> Use a graphing calculator or computer to graph both the curve and its curvature function k (x) on the same screen. Is the graph of  what you would expect? y = x4 - 2x2

> If u(t) = r(t) ∙ [r'(t) × r''(t)], show that u'(t) – r(t) ∙ [r'(t) × r'''(t)]

> If a curve has the property that the position vector r(t) is always perpendicular to the tangent vector r'(t), show that the curve lies on a sphere with center the origin.

> Show that if r is a vector function such that r'' exists, then d - [r() X г()] — г() X г"() dt

> Find an equation of a parabola that has curvature 4 at the origin.

> At what point does the curve have maximum curvature? What happens to the curvature as x →∞ ? y = ex

> Use Formula 11 to find the curvature. y = xex

> Use Formula 11 to find the curvature. y = tan x

> Sketch the curve with the given vector equation. Indicate with an arrow the direction in which t increases. r(t) = cos t i - cos t j + sin t k

> Use Formula 11 to find the curvature. y = x4

> Prove Formula 6 of Theorem 3.

> Prove Formula 3 of Theorem 3.

> Prove Formula 1 of Theorem 3.

> Evaluate the integral. t 1 k) dt 1 - t j+ V1 – 12

> Evaluate the integral. (sec?t i + t(t? + 1)°j + t² In t k) dt

> Evaluate the integral. /

> Sketch the curve with the given vector equation. Indicate with an arrow the direction in which t increases. r(t) = t2 i + t4 j + t6 k

> Evaluate the integral. 1 i + t + 1 j+ t2 + 1 k dt 1² + 1

> Evaluate the integral. S (22 i+ (t + 1)/F k) đt 3/2

> Evaluate the integral. S (ti - r'j+ 3r°k) dt Jo

> Use Theorem 10 to find the curvature. r(t) = 6 t2 i + 2t j + 2t3 k

> Use Theorem 10 to find the curvature. r(t) = t i + t2 j + et k

> Use Theorem 10 to find the curvature. r(t) = t3 j + t2 k

> (a). Find the unit tangent and unit normal vectors T(t) and N(t). (b). Use Formula 9 to find the curvature. r(t) = (r, }r°, r²)

> Find parametric equations for the tangent line to the curve with the given parametric equations at the specified point. Illustrate by graphing both the curve and the tangent line on a common screen. x = 2 cos t, y = 2 sin t, z = 4 cos 2t; ( 3 , 1, 2)

> Sketch the curve with the given vector equation. Indicate with an arrow the direction in which t increases. r(t) = 2 cos t i + 2 sin t j + k

> (a). Find the unit tangent and unit normal vectors T(t) and N(t). (b). Use Formula 9 to find the curvature. r(t) = (/2t, e', e-)

> Find parametric equations for the tangent line to the curve with the given parametric equations at the specified point. /t2 + 3, y= ln(t² + 3), z = t; (2, In 4, 1) X =

> Suppose you start at the point (0, 0, 3) and move 5 units along the curve x = 3 sin t, y = 4t, z = 3 cos t in the positive direction. Where are you now?

> Find the unit tangent vector T (t) at the point with the given value of the parameter t. r (t) = cos t i + 3t j + 2 sin 2t k, t = 0

> Let C be the curve of intersection of the parabolic cylinder x2 = 2y and the surface 3z = xy. Find the exact length of C from the origin to the point (6, 18, 36).

> Find the unit tangent vector T (t) at the point with the given value of the parameter t. r(t) = (r² – 21, 1 + 3t, + ), t= 2

> Find the derivative of the vector function. r (t) = t a × (b + t c)

> Find the derivative of the vector function. r (t) = a + t b + t2 c

> Find the length of the curve. r(t) = t2 i + 9t j + 4t3/2 k, 1 < t < 4

> Find the derivative of the vector function. 1 r(t) 1 +t -i + 1 + t j + k 1 + t

> Find the derivative of the vector function. r (t) = t2 i + cos (t2) j + sin2t k

> Find the derivative of the vector function. r(t) = (Vi – 2,3, 1/r²)

> The figure shows a curve C given by a vector function r (t). (a). Draw the vectors r (4.5) &acirc;&#128;&#147; r (4) and r (4.2) &acirc;&#128;&#147; r (4). (b). Draw the vectors (c). Write expressions for r' (4) and the unit tangent vector T (4). (d).

> Find parametric equations and symmetric equations for the line. The line through (-6, 2, 3) and parallel to the line 1 2 x – 1 3 y = z + 1

> If a = i - 2k and b = j + k, find a × b. Sketch a, b, and a × b as vectors starting at the origin.

> Find the cross product a × b and verify that it is orthogonal to both a and b. a = t i + cos t j + sin tk, b = i - sin t j + cos tk

> Find the cross product a × b and verify that it is orthogonal to both a and b. a = 1 2 i + 1 3 j + 1 4 k, b = i + 2 j – 3k

> Show that |a × b |2 = |a |2 | b |2 - (a ∙ b)2.

> (a). Let P be a point not on the line L that passes through the points Q and R. Show that the distance d from the point P to the line L is (b). Use the formula in part (a) to find the distance from the point P (1, 1, 1) to the line through Q (0, 6, 8)

> (a). Find all vectors v such that 1, 2, 1 × v = 3, 1, −5 (b). Explain why there is no vector v such that 1, 2, 1 × v = 3, 1, 5

> Find the unit vectors that are parallel to the tangent line to the parabola y − x2 at the point (2, 4).

> If a ∙ b = 3 and a × b = 1, 2, 2 , find the angle between a and b.

> A wrench 30 cm long lies along the positive y-axis and grips a bolt at the origin. A force is applied in the direction 0, 3, −4 at the end of the wrench. Find the magnitude of the force needed to supply 100 N ∙ m of torque to the bolt.

> Find the cross product a × b and verify that it is orthogonal to both a and b. a = 3i + 3j - 3k, b = 3i - 3j + 3k

> A particle moves according to a law of motion s = f(t), t &acirc;&#137;&yen; 0, where t is measured in seconds and s in feet. (a) Find the velocity at time t. (b) What is the velocity after 1 second? (c) When is the particle at rest? (d) When is the part

> Use the scalar triple product to determine whether the points A (1, 3, 2), B (3, -1, 6), C (5, 2, 0), and D (3, 6, -4) lie in the same plane.

> Use the scalar triple product to verify that the vectors u = i + 5 j - 2 k, v = 3i - j, and w = 5i + 9 j - 4 k are coplanar.

> Find the volume of the parallelepiped with adjacent edges PQ, PR, and PS. P (3, 0, 1), Q (-1, 2, 5), R (5, 1, -1), S (0, 4, 2)

> Find the volume of the parallelepiped with adjacent edges PQ, PR, and PS. P (-2, 1, 0), Q (2, 3, 2), R (1, 4, -1), S (3, 6, 1)

> Find the volume of the parallelepiped determined by the vectors a, b, and c. a = i + j, b = j + k, c = i + j + k

> Find the volume of the parallelepiped determined by the vectors a, b, and c. a = 1, 2, 3 , b = −1, 1, 2 , c = 2, 1, 4

> A crane suspends a 500-lb steel beam horizontally by support cables (with negligible weight) attached from a hook to each end of the beam. The support cables each make an angle of 60&Acirc;&deg; with the beam. Find the tension vector in each support cabl

> (a) Find a nonzero vector orthogonal to the plane through the points P, Q, and R, and (b) find the area of triangle PQR. P (2, -3, 4), Q (-1, -2, 2), R (3, 1, -3)

> (a) Find a nonzero vector orthogonal to the plane through the points P, Q, and R, and (b) find the area of triangle PQR. P (0, -2, 0), Q (4, 1, -2), R (5, 3, 1)

> (a) Find a nonzero vector orthogonal to the plane through the points P, Q, and R, and (b) find the area of triangle PQR. P (0, 0, -3), Q (4, 2, 0), R (3, 3, 1)

> Find the cross product a × b and verify that it is orthogonal to both a and b. a = 2j - 4k, b = 2i + 3j + k

> Find dy/dx by implicit differentiation. y cos x = x2 + y2

> Suppose y = f (x) is a curve that always lies above the x-axis and never has a horizontal tangent, where f is differentiable everywhere. For what value of y is the rate of change of y5 with respect to x eighty times the rate of change of y with respect t

> Find the area of the parallelogram with vertices P (1, 0, 2), Q (3, 3, 3d), R (7, 5, 8), and S (5, 2, 7).

> Prove the property of cross products (Theorem 11). Property 3: a × (b + c) = a × b + a × c

> Prove the property of cross products (Theorem 11). Property 2: (ca) × b = c (a × b) = a × (cb)

> If p(x) is the total value of the production when there are x workers in a plant, then the average productivity of the workforce at the plant is A(x) = p(x) / x (a) Find A’(x). Why does the company want to hire more workers if A’(x) > 0? (b) Show that A’

> Prove the property of cross products (Theorem 11). Property 1: a × b = -b × a

> Show that (a × b) ∙ b = 0 for all vectors a and b in V3.

> Show that 0 × a = 0 = a × 0 for any vector a in V3.

> Find two unit vectors orthogonal to both j - k and i + j.

> Find the cross product a × b and verify that it is orthogonal to both a and b. a = 4, 3, −2 , b = 2, −1, 1

> Find two unit vectors orthogonal to both 3, 2, 1 and −1, 1, 0 .

> If a = 1, 0, 1 , b = 2, 1, −1 , and c = 0, 1, 3 , show that a × (b × c) ≠ (a × b) × c.

> If a = 2, −1, 3 and b = 4, 2, 1 , find a × b and b × a.

2.99

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