Answer:
Dimensions are 2 m by 1 meter by 1 meter,
Minimum cost is $ 18.
Step-by-step explanation:
Let w be the width ( in meters ) of the container,
Since, the length is twice of the width,
So, length of the container = 2w,
Now, if h be the height of the container,
Volume = length × width × height
2 = 2w × w × h
1 = w² × h
[tex]\implies h=\frac{1}{w^2}[/tex]
Since, the area of the base = l × w = 2w × w = 2w²,
Area of the lid = l × w = 2w²,
While the area of the sides = 2hw + 2hl
= 2h( w + l)
[tex]= 2\times \frac{1}{w^2}(w+2w)[/tex]
[tex]=\frac{6w}{w^2}[/tex]
[tex]=\frac{6}{w}[/tex]
Since, Material for the base costs $1 per m². Material for the sides and lid costs $2 per m²,
So, the total cost,
[tex]C(w) = 1\times 2w^2+2\times 2w^2 + 2\times \frac{6}{w}[/tex]
[tex]=2w^2+4w^2+\frac{12}{w}[/tex]
[tex]=6w^2+\frac{12}{w}[/tex]
Differentiating with respect to w,
[tex]C'(w) = 12w -\frac{12}{w^2}[/tex]
Again differentiating with respect to w,
[tex]C''(w) = 12 + \frac{24}{w^3}[/tex]
For maxima or minima,
C'(w) = 0
[tex]\implies 12w -\frac{12}{w^2}=0[/tex]
[tex]\implies 12w^3 - 12=0[/tex]
[tex]w^3-1=0\implies w = 1[/tex]
For w = 1, C''(w) = positive,
Hence, for width 1 m the cost is minimum,
Therefore, the minimum cost is C(1) = 6(1)²+12 = $ 18,
And, the dimension for which the cost is minimum is,
2 m by 1 meter by 1 meter.
