Find the vector in ℝ3 from point A=(x,y,z) to B=(−7,−2,−8).. AB→= The vector v⃗  in 2-space of...

Find the flux of the vector field F(x, y, z) = x, y, z through the...

Find the flux of the vector field F(x, y, z) = x, y, z through the portion of the parabaloid z = 16 - x^2-y^2  above the plane ? = 7 with upward pointing normal.

A space curve C is parametrically parametrically defined by x(t)=e^t^(2) −10, y(t)=2t^(3/2) +10, z(t)=−π, t∈[0,+∞). (a)...

A space curve C is parametrically parametrically defined by x(t)=e^t^(2) −10, y(t)=2t^(3/2) +10, z(t)=−π, t∈[0,+∞). (a) What is the vector representation r⃗(t) for C ? (b) Is C a smooth curve? Justify your answer. (c) Find a unit tangent vector to C . (d) Let the vector-valued function v⃗ be defined by v⃗(t)=dr⃗(t)/dt Evaluate the following indefinite integral ∫(v⃗(t)×i^)dt. (cross product)

Vector A has magnitude of 8.0 at an angle of 20.0deg from the x-axis. Vector B...

Vector A has magnitude of 8.0 at an angle of 20.0deg from the x-axis. Vector B has magnitude of 7.0 at an angle of -10.0 deg from the x-axis. Let C=A+B. Let D=A-B. Let V=2*A-B. 1.What is the x-component of vector C? 2.What is the y-component of vector C? 3.What is the x-component of vector D? 4.What is the y-component of vector D? 5.What is the x-component of vector V? 6.What is the y-component of vector V?

Let F(x, y, z) = z tan−1(y^2)i + z^3 ln(x^2 + 7)j + zk. Find the...

Let F(x, y, z) = z tan−1(y^2)i + z^3 ln(x^2 + 7)j + zk. Find the flux of F across S, the part of the paraboloid x^2 + y^2 + z = 29 that lies above the plane z = 4 and is oriented upward.

1.Let y=6x^2. Find a parametrization of the osculating circle at the point x=4. 2. Find the...

1.Let y=6x^2. Find a parametrization of the osculating circle at the point x=4. 2. Find the vector OQ−→− to the center of the osculating circle, and its radius R at the point indicated. r⃗ (t)=<2t−sin(t), 1−cos(t)>,t=π 3. Find the unit normal vector N⃗ (t) of r⃗ (t)=<10t^2, 2t^3> at t=1. 4. Find the normal vector to r⃗ (t)=<3⋅t,3⋅cos(t)> at t=π4. 5. Evaluate the curvature of r⃗ (t)=<3−12t, e^(2t−24), 24t−t2> at the point t=12. 6. Calculate the curvature function for r⃗...

1. (5pts.) Compute the derivative dy/dx for y = 7√ 9π + x ^5 /6 +...

1. (5pts.) Compute the derivative dy/dx for y = 7√ 9π + x ^5 /6 + 27e^x . 3. (5pts.) Write the equation of the tangent line to the graph of y = 3 + 8 ln x at the point where x = 1. 4. (5pts.) Determine the slope of the tangent line to the curve 2x^3 + y^3 + 2xy = 14 at the point (1, 2). 5. (5pts.) Compute the derivative dw/dz of the function w =...

Find the distance from the point <8,−3,5> to the line x=−9−3∗t,y=8−3∗t,z=−4−8∗t

Find the distance from the point <8,−3,5> to the line x=−9−3∗t,y=8−3∗t,z=−4−8∗t

Find the length of the curve defined by the parametric equations x=(3/4)t y=3ln((t/4)2−1) from t=5 to...

Find the length of the curve defined by the parametric equations x=(3/4)t y=3ln((t/4)2−1) from t=5 to t=7.

Your task will be to derive the equations describing the velocity and acceleration in a polar...

Your task will be to derive the equations describing the velocity and acceleration in a polar coordinate system and a rotating polar vector basis for an object in general 2D motion starting from a general position vector. Then use these expressions to simplify to the case of non-uniform circular motion, and finally uniform circular motion. Here's the time-dependent position vector in a Cartesian coordinate system with a Cartesian vector basis: ⃗r(t)=x (t) ̂ i+y(t) ̂ j where x(t) and y(t)...