Vector Field: F(x,y.z) = (-y, 2rz., x²) and Parametric Curve: r(t) = (21, 31, r> Use the parametric curve to convert the vector field into a parametric vector field. F() =(- 21, 3r", 1*) B F(1) = (-21, 61, 1) © F() = (-31, 4r", 41²) F(1) = (21, 31, 1') Now find the derivative of the parametric curve. r() = (21, 31, r') B r) = (2. 3, 3r) © r() = (0, 0, 30)> O r(1) = (2. 3, 1) Now that you have found the parametric vector field and the derivative of the parametric curve, you can use them to find the General Line Integral for this situation. General Line Integral for Vector Fields= F(1) - r'(1) di and Intervat: [0, 1] F(1) . r'(1) di = 3.2 |F) -F) dt = 0.733 © Srm F(1) - r'(1) dt = 1.8 F(1) - r'(1) di = 4.766

Calculus: Early Transcendentals
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Author:James Stewart
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Chapter1: Functions And Models
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We are given a vector field and a parametric curve

Vector Field: F(x,y.z) = (-y, 2rz., x²) and Parametric Curve: r(t) = (21, 31, r>
Use the parametric curve to convert the vector field into a parametric vector field.
F() =(- 21, 3r", 1*)
B F(1) = (-21, 61, 1)
© F() = (-31, 4r", 41²)
F(1) = (21, 31, 1')
Now find the derivative of the parametric curve.
r() = (21, 31, r')
B r) = (2. 3, 3r)
© r() = (0, 0, 30)>
O r(1) = (2. 3, 1)
Now that you have found the parametric vector field and the derivative of the parametric curve, you can use them to find the
General Line Integral for this situation.
General Line Integral for Vector Fields=
F(1) - r'(1) di and Intervat: [0, 1]
F(1) . r'(1) di = 3.2
|F) -F) dt = 0.733
© Srm
F(1) - r'(1) dt = 1.8
F(1) - r'(1) di = 4.766
Transcribed Image Text:Vector Field: F(x,y.z) = (-y, 2rz., x²) and Parametric Curve: r(t) = (21, 31, r> Use the parametric curve to convert the vector field into a parametric vector field. F() =(- 21, 3r", 1*) B F(1) = (-21, 61, 1) © F() = (-31, 4r", 41²) F(1) = (21, 31, 1') Now find the derivative of the parametric curve. r() = (21, 31, r') B r) = (2. 3, 3r) © r() = (0, 0, 30)> O r(1) = (2. 3, 1) Now that you have found the parametric vector field and the derivative of the parametric curve, you can use them to find the General Line Integral for this situation. General Line Integral for Vector Fields= F(1) - r'(1) di and Intervat: [0, 1] F(1) . r'(1) di = 3.2 |F) -F) dt = 0.733 © Srm F(1) - r'(1) dt = 1.8 F(1) - r'(1) di = 4.766
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