Suppose you wish to make a special cylindrical can holding a volume of 1 liter. If...

Find the dimensions and volume of the box of maximum volume that can be constructed. The...

Find the dimensions and volume of the box of maximum volume that can be constructed. The rectangular box having a top and a square base is to be constructed at a cost of $4. If the material for the bottom costs $0.10 per square foot, the material for the top costs $0.35 per square foot, and the material for the sides costs $0.25 per square foot,

A cylindrical can open at the top is to have volume 24, 000π cm3 . The...

A cylindrical can open at the top is to have volume 24, 000π cm3 . The material for the base of the can costs three times as much as the material for the rest of the can. What are the dimensions of the can of minimum cost?

A cylinder shaped can needs to be constructed to hold 400 cubic centimeters of soup. The...

A cylinder shaped can needs to be constructed to hold 400 cubic centimeters of soup. The material for the sides of the can costs 0.04 cents per square centimeter. The material for the top and bottom of the can need to be thicker, and costs 0.05 cents per square centimeter. Find the dimensions for the can that will minimize production cost. Helpful information: h : height of can, r : radius of can Volume of a cylinder: V=πr2^h Area of...

Suppose you want to build a hollow rectangular box with volume 2000 cm^3. If the material...

Suppose you want to build a hollow rectangular box with volume 2000 cm^3. If the material for the top costs $3/cm^2 and the material for the side and bottom faces cost $1/cm^2, what are the dimensions of the cheapest box? (Here, we ignore the thickness of the faces of the box.)

240 square cm of metal is available to make a cylindrical can, closed on the top...

240 square cm of metal is available to make a cylindrical can, closed on the top and bottom. The can-making process is so efficient that it can use all of the metal. What are the radius and height of the can with the largest possible volume? Give exact answers and approximate answers. Volume of a cylinder: V = πr2h Surface area of a cylinder: 2πr2 + 2πrh

A cargo container in the shape of a rectangular box must have a volume of 480...

A cargo container in the shape of a rectangular box must have a volume of 480 cubic feet. If the bottom of the container costs $4 per square foot to construct, and the sides and top of the container cost $3 per square foot to construct, find the dimensions of the cheapest container which will have a volume of 480 cubic feet.

A rectangular box is to have a square base and a volume of 20 ft3. If...

A rectangular box is to have a square base and a volume of 20 ft3. If the material for the base costs $0.17/ft2, the material for the sides costs $0.06/ft2, and the material for the top costs $0.13/ft2, (a) determine the dimensions (in ft) of the box that can be constructed at minimum cost. (b) Which theorem did you use to find the answer?

You need a box with a volume of 1000cm3. The top and the bottom of the...

You need a box with a volume of 1000cm3. The top and the bottom of the box are square and each cost $.20 per square centimeter, whereas the sides each cost $.05 per square centimeter. What are the dimensions of the box that will minimize the cost?

A storage company must design a large rectangular container with a square base. The volume is...

A storage company must design a large rectangular container with a square base. The volume is 24576ft324576⁢ft3. The material for the top costs $12$⁢12 per square foot, the material for the sides costs $2$⁢2 per square foot, and the material for the bottom costs $12$⁢12 per square foot. Find the dimensions of the container that will minimize the total cost of material.

a closed rectangular container with a square base is to have a volume of 2400 cubic...

a closed rectangular container with a square base is to have a volume of 2400 cubic cm. it costs three times as much per square cm for the top and bottom as it does for for the side. find the dimensions of the container of least cost.