Evaluate ∮C(6y−3y2+x)dx+yx3dy where C is the boundary of the parallelogram with vertices A(−1,−1),B(1,1),C(−1,2) and D(1,4)

Evaluate the integral ∬ ????, where ? is the square with vertices (0,0),(1,1), (2,0), and (1,−1),...

Evaluate the integral ∬ ????, where ? is the square with vertices (0,0),(1,1), (2,0), and (1,−1), by carrying out the following steps: a. sketch the original region of integration R in the xy-plane and the new region S in the uv-plane using this variable change: ? = ? + ?,? = ? − ?, b. find the limits of integration for the new integral with respect to u and v, c. compute the Jacobian, d. change variables and evaluate the...

Use Green’s theorem to evaluate the integral: ∫(-x^2y)dx +(xy^2)dy where C is the boundary of the...

Use Green’s theorem to evaluate the integral: ∫(-x^2y)dx +(xy^2)dy where C is the boundary of the region enclosed by y= sqrt(9 − x^2) and the x-axis, traversed in the counterclockwise direction.

Use the given transformation to evaluate the double integral of (x-6y) dA, where R is the...

Use the given transformation to evaluate the double integral of (x-6y) dA, where R is the triangular region with vertices (0, 0), (5, 1), and (1, 5). x = 5u + v, y = u + 5v

Use the given transformation to evaluate the integral. (x − 6y) dA, R where R is...

Use the given transformation to evaluate the integral. (x − 6y) dA, R where R is the triangular region with vertices (0, 0), (5, 1), and (1, 5). x = 5u + v, y = u + 5v

Evaluate ∮C(x^3+xy)dx+(cos(y)+x2)dy∮C(x^3+xy)dx+(cos(y)+x^2)dy where C is the positively oriented boundary of the region bounded by  C:0≤x^2+y^2≤16, x≥0,y≥0C:0≤x^2+y^2≤16,x≥0,y≥0

Evaluate ∮C(x^3+xy)dx+(cos(y)+x2)dy∮C(x^3+xy)dx+(cos(y)+x^2)dy where C is the positively oriented boundary of the region bounded by  C:0≤x^2+y^2≤16, x≥0,y≥0C:0≤x^2+y^2≤16,x≥0,y≥0

Evaluate∫ C F ⋅ d r , where F(x,y,z)={e^−4x,e^2x,1e^z} and C is the boundary of the...

Evaluate∫ C F ⋅ d r , where F(x,y,z)={e^−4x,e^2x,1e^z} and C is the boundary of the part of the plane 3x+7y+5z=3 lying in the first octant, traversed counterclockwise as viewed from above. HINT: Use Stokes' Theorem.

1102) a) intg{dx}=Ax+C. b) intg{x dx}=Bx^D + C. c) intg{(1/x^2)dx}=Ex^F + C. d) intg{7x^8 dx}=Gx^H +...

1102) a) intg{dx}=Ax+C. b) intg{x dx}=Bx^D + C. c) intg{(1/x^2)dx}=Ex^F + C. d) intg{7x^8 dx}=Gx^H + C. Answers: A,B,D,E,F,G,H. ans:7 1104) a) intg{4(x+8) dx}=Ax^2 + Bx + C. b) intg{(8/sqrt(2x)) dx}=Dx^E + C. Answers: A,B,D,E,F,G,H c) intg{sqrt(x)(7x-6) dx}=(Fx+G)x^H + C. ans:7

Evaluate the line integral ∫_c x^2 +y^2 ds where C is the line segment from (1,1)...

Evaluate the line integral ∫_c x^2 +y^2 ds where C is the line segment from (1,1) to (2,3).

2. Use Green’s Theorem to evaluate R C F · Tds, where C is the square...

2. Use Green’s Theorem to evaluate R C F · Tds, where C is the square with vertices (0,0),(1,0),(1,1) and (0,1) in the xy plane, oriented counter-clockwise, and F(x,y) = hx 3 ,xyi. (Please give a numerical answer here.)

Evaluate Integral (subscript c) z dx + y dy − x dz, where the curve C...

Evaluate Integral (subscript c) z dx + y dy − x dz, where the curve C is given by c(t) = t i + sin t j + cost k for 0 ≤ t ≤ π.