Consider the function ?(?, ?) = 10 ? ? ?^ (−0.3? 2−0.2? 2) A. This function...

Consider the following function. f (x, y)  =  (x − 6) ln(x5y) (a) Find the critical...

Consider the following function. f (x, y)  =  (x − 6) ln(x5y) (a) Find the critical point of  f. If the critical point is (a, b) then enter 'a,b' (without the quotes) into the answer box. (b) Using your critical point in (a), find the value of D(a, b) from the Second Partials test that is used to classify the critical point. (c) Use the Second Partials test to classify the critical point from (a). one of: relative max, relative...

f(x)=x^3-4x^2+5x-2 Find all critical numbers of the function, then use the second derivative test on each...

f(x)=x^3-4x^2+5x-2 Find all critical numbers of the function, then use the second derivative test on each critical number to determine if it is a local maximum or minimum. Show your work.

consider the 2 variable function f(x,y) = 4 - x^2 - y^2 - 2x - 2y...

consider the 2 variable function f(x,y) = 4 - x^2 - y^2 - 2x - 2y + xy a.) find the x,y location of all critical points of f(x,y) b.) classify each of the critical points found in part a.)

Please use the second derivative test to determine whether each point is local min/max or saddle...

Please use the second derivative test to determine whether each point is local min/max or saddle of the function f(x,y)=x^3-xy+y^3

Consider the function f(x) = x^2/x-1 with f ' (x) = x^2-2x/ (x - 1)^2 and...

Consider the function f(x) = x^2/x-1 with f ' (x) = x^2-2x/ (x - 1)^2 and f '' (x) = 2 / (x - 1)^3 are given. Use these to answer the following questions. (a) [5 marks] Find all critical points and determine the intervals where f(x) is increasing and where it is decreasing, use the First Derivative Test to fifind local extreme value if any exists. (b) Determine the intervals where f(x) is concave upward and where it is...

Consider the following function. g(x, y)  =  e− 4x^2 + 4y^2 + 8 √ 8y (a)...

Consider the following function. g(x, y)  =  e− 4x^2 + 4y^2 + 8 √ 8y (a) Find the critical point of g. If the critical point is (a, b) then enter 'a,b' (without the quotes) into the answer box. (b) Using your critical point in (a), find the value of D(a, b) from the Second Partials test that is used to classify the critical point. (c) Use the Second Partials test to classify the critical point from (a). A) Saddle...

Consider the function f(x,y) = -8x^2-8y^2+x+y Select all that apply: 1. The function has two critical...

Consider the function f(x,y) = -8x^2-8y^2+x+y Select all that apply: 1. The function has two critical points 2. The function has a saddle point 3. The function has a local maximum 4. The function has a local minimum 5. The function has one critical point *Please show your work so I can follow along*

- Suppose f is a function such that f′(x) = (x+ 1)(x−2)2(x−3), so that f has...

- Suppose f is a function such that f′(x) = (x+ 1)(x−2)2(x−3), so that f has the critical points x=−1,2,3. Determine the open intervals on which f is increasing/decreasing. - Let f be the same function as in Problem 9. Determine which, if any, of the critical points is the location of a local extremum, and indicate whether each extremum is a maximum or minimum. Im confused on how to figure out if a function is increasing and decreasing and...

consider the function f(x)=3x-5/sqrt x^2+1. given f'(x)=5x+3/(x^2+1)^3/2 and f''(x)=-10x^2-9x+5/(x^2+1)^5/2 a) find the local maximum and minimum...

consider the function f(x)=3x-5/sqrt x^2+1. given f'(x)=5x+3/(x^2+1)^3/2 and f''(x)=-10x^2-9x+5/(x^2+1)^5/2 a) find the local maximum and minimum values. Justify your answer using the first or second derivative test . round your answers to the nearest tenth as needed. b)find the intervals of concavity and any inflection points of f. Round to the nearest tenth as needed. c)graph f(x) and label each important part (domain, x- and y- intercepts, VA/HA, CN, Increasing/decreasing, local min/max values, intervals of concavity/ inflection points of f?

Consider the nonlinear second-order differential equation 4x"+4x'+2(k^2)(x^2)− 1/2 =0, where k > 0 is a constant....

Consider the nonlinear second-order differential equation 4x"+4x'+2(k^2)(x^2)− 1/2 =0, where k > 0 is a constant. Answer to the following questions. (a) Show that there is no periodic solution in a simply connected region R={(x,y) ∈ R2 | x <0}. (Hint: Use the corollary to Theorem 11.5.1>> If symply connected region R either contains no critical points of plane autonomous system or contains a single saddle point, then there are no periodic solutions. ) (b) Derive a plane autonomous system...