Advertisements
Advertisements
प्रश्न
Read the following passage and answer the questions given below.
|
In an elliptical sport field the authority wants to design a rectangular soccer field with the maximum possible area. The sport field is given by the graph of `x^2/a^2 + y^2/b^2` = 1. |
- If the length and the breadth of the rectangular field be 2x and 2y respectively, then find the area function in terms of x.
- Find the critical point of the function.
- Use First derivative Test to find the length 2x and width 2y of the soccer field (in terms of a and b) that maximize its area.
OR
Use Second Derivative Test to find the length 2x and width 2y of the soccer field (in terms of a and b) that maximize its area.
उत्तर
i.
Let (x, y) = `(x, b/a sqrt(a^2 - x^2))` be the upper right vertex of the rectangle.
The area function A = `2x xx 2 b/a sqrt(a^2 - x^2)`
= `(4b)/a x sqrt(a^2 - x^2), x ∈ (0, a)`.
ii. `(dA)/(dx) = (4b)/a [x xx (-x)/sqrt(a^2 - x^2) + sqrt(a^2 - x^2)]`
= `(4b)/a xx (a^2 - 2x^2)/sqrt(a^2 - x^2)`
= `-(4b)/a xx (2(x + a/sqrt(2)) (x - a/sqrt(2)))/sqrt(a^2 - x^2)`
`(dA)/(dx)` = 0
⇒ x = `a/sqrt(2)`
x = `a/sqrt(2)` is the critical point.
iii. For the values of x less than `a/sqrt(2)` and close to `a/sqrt(2), (dA)/(dx) > 0` and for the values of x greater than `a/sqrt(2)` and close to `a/sqrt(2), (dA)/(dx) < 0`.
Hence, by the first derivative test, there is a local maximum at the critical point x = `a/sqrt(2)`. Since there is only one critical point, therefore, the area of the soccer field is maximum at this critical point x = `a/sqrt(12)`
Thus, for maximum area of the soccer field, its length should be `asqrt(2)` and its width should be `bsqrt(2)`.
OR
A = `2x xx 2 b/a sqrt(a^2 - x^2), x ∈ (0, a)`
Squaring both sides, we get
Z = A2 = `(16b^2)/a^2 x^2(a^2 - x^2)`
= `(16b^2)/a^2 (x^2a^2 - 4x^4),x ∈ (0, a)`
A is maximum when Z is maximum.
`(dZ)/(dx) = (16b^2)/a^2 (2xa^2 - 4x^3)`
= `(32b^2)/a^2 x(a + sqrt(2)x)(a - sqrt(2)x)`
`(dZ)/(dx)` = 0
⇒ x = `a/sqrt(2)`
`(d^2Z)/(dx^2) = (32b^2)/a^2 (a^2 - 6x^2)`
`((d^2Z)/(dx^2))_(x = a/sqrt(2)) = (32b^2)/a^2 (a^2 - 3a^2)`
= –64b2 < 0
Hence, by the second derivative test, there is a local maximum value of Z at the critical point x = `a/sqrt(2)`. Since there is only one critical point, therefore, Z is maximum at x = `a/sqrt(2)`, hence, A is maximum at x = `a/sqrt(2)`.
Thus, for the maximum area of the soccer field, its length should be `asqrt(2)` and its width should be `bsqrt(2)`.
APPEARS IN
संबंधित प्रश्न
Find the approximate value of cos (89°, 30'). [Given is: 1° = 0.0175°C]
Show that the height of the cylinder of maximum volume, that can be inscribed in a sphere of radius R is `(2R)/sqrt3.` Also, find the maximum volume.
Find the maximum and minimum value, if any, of the following function given by g(x) = − |x + 1| + 3.
At what points in the interval [0, 2π], does the function sin 2x attain its maximum value?
Find two positive numbers x and y such that x + y = 60 and xy3 is maximum.
A wire of length 28 m is to be cut into two pieces. One of the pieces is to be made into a square and the other into a circle. What should be the length of the two pieces so that the combined area of the square and the circle is minimum?
Prove that the volume of the largest cone that can be inscribed in a sphere of radius R is `8/27` of the volume of the sphere.
The point on the curve x2 = 2y which is nearest to the point (0, 5) is ______.
For all real values of x, the minimum value of `(1 - x + x^2)/(1+x+x^2)` is ______.
Find the maximum and minimum of the following functions : f(x) = 2x3 – 21x2 + 36x – 20
Divide the number 20 into two parts such that their product is maximum.
If f(x) = px5 + qx4 + 5x3 - 10 has local maximum and minimum at x = 1 and x = 3 respectively then (p, q) = ______.
The minimum value of Z = 5x + 8y subject to x + y ≥ 5, 0 ≤ x ≤ 4, y ≥ 2, x ≥ 0, y ≥ 0 is ____________.
Twenty meters of wire is available for fencing off a flowerbed in the form of a circular sector. Then the maximum area (in sq. m) of the flower-bed, is ______
Find all the points of local maxima and local minima of the function f(x) = `- 3/4 x^4 - 8x^3 - 45/2 x^2 + 105`
The coordinates of the point on the parabola y2 = 8x which is at minimum distance from the circle x2 + (y + 6)2 = 1 are ____________.
The function `"f"("x") = "x" + 4/"x"` has ____________.
Let f(x) = 1 + 2x2 + 22x4 + …… + 210x20. Then f (x) has ____________.
The function `f(x) = x^3 - 6x^2 + 9x + 25` has
The point on the curve `x^2 = 2y` which is nearest to the point (0, 5) is
For all real values of `x`, the minimum value of `(1 - x + x^2)/(1 + x + x^2)`
A function f(x) is maximum at x = a when f'(a) > 0.
If p(x) be a polynomial of degree three that has a local maximum value 8 at x = 1 and a local minimum value 4 at x = 2; then p(0) is equal to ______.
A rectangle with one side lying along the x-axis is to be inscribed in the closed region of the xy plane bounded by the lines y = 0, y = 3x and y = 30 – 2x. The largest area of such a rectangle is ______.
A straight line is drawn through the point P(3, 4) meeting the positive direction of coordinate axes at the points A and B. If O is the origin, then minimum area of ΔOAB is equal to ______.
Sum of two numbers is 5. If the sum of the cubes of these numbers is least, then find the sum of the squares of these numbers.
Mrs. Roy designs a window in her son’s study room so that the room gets maximum sunlight. She designs the window in the shape of a rectangle surmounted by an equilateral triangle. If the perimeter of the window is 12 m, find the dimensions of the window that will admit maximum sunlight into the room.
