Perform two iterations of the gradient search method on f(x,y)= x2+4xy+2y2+2x+2y. Use (0,0) as a starting...

2. Perform 2 iterations of Newton’s method on f(x,y)=x^4+4x^2*y+4y^2+2x+2y starting at(1,1).

2. Perform 2 iterations of Newton’s method on f(x,y)=x^4+4x^2*y+4y^2+2x+2y starting at(1,1).

For the function, f (x) = X2-4X + 2XY + 2Y2 + 2Y +14 Plot the...

For the function, f (x) = X2-4X + 2XY + 2Y2 + 2Y +14 Plot the surface function for X over [5 6]. and Y over [-4. -2],. Draw the contour plot for X over [0 10]. and Y over [-4. -2] and values for the contours of V=[1 1.25 1.5 2 2.5 3]; Write an m-file to find the minimum of the function using the gradient descent method. Use a starting value of [4. -4].

The paraboloid z = 3x2 + 2y2 + 1 and the plane 2x – y +...

The paraboloid z = 3x2 + 2y2 + 1 and the plane 2x – y + z = 4 intersect in a curve C. Find the points on C that have a maximum and minimum distance from the origin. The point on C is the maximum distance from the origin is (___ , ____ , ____).    The point on C is the minimum distance from the origin is (____ , ____ , ____). So for this question I get...

find the directional derivative of f(x,y) = x^2y^3 +2x^4y at the point (3,-1) in the direction...

find the directional derivative of f(x,y) = x^2y^3 +2x^4y at the point (3,-1) in the direction theta= 5pi/6 the gradient of f is f(x,y)= the gradient of f (3,-1)= the directional derivative is:

Consider the function f(x, y) = sin(2x − 2y) (a) Solve and find the gradient of...

Consider the function f(x, y) = sin(2x − 2y) (a) Solve and find the gradient of the function. (b) Find the directional derivative of the function at the point P(π/2,π/6) in the direction of the vector v = <sqrt(3), −1>   (c) Compute the unit vector in the direction of the steepest ascent at A (π/2,π/2)

You are given that the function f(x,y)=8x2+y2+2x2y+3 has first partials fx(x,y)=16x+4xy and fy(x,y)=2y+2x2, and has second...

You are given that the function f(x,y)=8x2+y2+2x2y+3 has first partials fx(x,y)=16x+4xy and fy(x,y)=2y+2x2, and has second partials fxx(x,y)=16+4y, fxy(x,y)=4x and fyy(x,y)=2. Consider the point (0,0). Which one of the following statements is true? A. (0,0) is not a critical point of f(x,y). B. f(x,y) has a saddle point at (0,0). C. f(x,y) has a local maximum at (0,0). D. f(x,y) has a local minimum at (0,0). E. The second derivative test provides no information about the behaviour of f(x,y) at...

Find the absolute maximum value and absolute minimum value of f(x,y) = x2 +2y2−2x−4y+1 on the...

Find the absolute maximum value and absolute minimum value of f(x,y) = x2 +2y2−2x−4y+1 on the region D = {(x,y) ∈ R2 : 0 ≤ x ≤ 2,|y−1.5|≤ 1.5}

Use Lagrange multipliers to find the extremal values of f(x,y,z)=2x+2y+z subject to the constraint x2+y2+z2=9.

Use Lagrange multipliers to find the extremal values of f(x,y,z)=2x+2y+z subject to the constraint x2+y2+z2=9.

A firm produces two commodities, A and B. The inverse demand functions are: pA = 900−2x−2y,...

A firm produces two commodities, A and B. The inverse demand functions are: pA = 900−2x−2y, pB = 1400−2x−4y respectively, where the firm produces and sells x units of commodity A and y units of commodity B. Its costs are given by: CA = 7000 + 100x + x^2 and CB = 10000 + 6y^2 (a) Show that the firms total profit is given by: π(x,y) = −3x2 −10y2 −4xy + 800x + 1400y−17000. (b) Assume π(x,y) has a maximum...

A firm produces two commodities, A and B. The inverse demand functions are: pA =900−2x−2y, pB...

A firm produces two commodities, A and B. The inverse demand functions are: pA =900−2x−2y, pB =1400−2x−4y respectively, where the firm produces and sells x units of commodity A and y units of commodity B. Its costs are given by: CA =7000+100x+x^2 and CB =10000+6y^2 where A, a and b are positive constants. (a) Show that the firms total profit is given by: π(x,y)=−3x^2 −10y^2 −4xy+800x+1400y−17000. (b) Assume π(x, y) has a maximum point. Find, step by step, the production...