A box with a square base and open top must have a volume of 415292 cm. We wish to find the dimensions of the box that minimize the amount of material used. First, find a formula for the surface area of the box in terms of only z, the length of one side of the square base. [Hint: use the volume formula to express the height of the box in terms of T.] Simplify your formula as much as possible. A(1) = Next, find the derivative, A' (T). A'(x) = %3D Now, calculate when the derivative equals zero, that is, when A'(x) 0. [Hint: multiply both sides by z -1 A'(x) = 0 when T = We next have to make sure that this value of x gives a minimum value for the surface area. Let's use the second derivative test. Find A"(x). A"(x) = Evaluate A"(T) at the x-value you gave above. NOTE: Since your last answer is positive, this means that the graph of A(I) is concave up around that value, so the zero of A'(x) must indicate a local minimum for A(x). (Your boss is happy now.)

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A box with a square base and open top must have a volume of 415292 cm. We wish to find the dimensions of the box that minimize the amount of material used. First, find a formula for the surface area of the box in terms of only z, the length of one side of the square base. [Hint: use the volume formula to express the height of the box in terms of T.] Simplify your formula as much as possible. A(1) = Next, find the derivative, A' (T). A"(x) = %3D Now, calculate when the derivative equals zero, that is, when A'(x) 0. [Hint: multiply both sides by z -1 A'(x) = 0 when I = We next have to make sure that this value of x gives a minimum value for the surface area. Let's use the second derivative test. Find A"(x). A"(x) = Evaluate A"(T) at the x-value you gave above. NOTE: Since your last answer is positive, this means that the graph of A(I) is concave up around that value, so the zero of A'(x) must indicate a local minimum for A(x). (Your boss is happy now.)