Find the rate of change of the area of a circle with respect to its radius \(r\) when
(a) \(r = 3\text{ cm}\)
(b) \(r = 4\text{ cm}\)
(a) \(6\pi\ \text{cm}^2/\text{cm}\)
(b) \(8\pi\ \text{cm}^2/\text{cm}\)
The volume of a cube is increasing at the rate of \(8\ \text{cm}^3/\text{s}\). How fast is the surface area increasing when the length of an edge is \(12\text{ cm}\)?
\(\frac{8}{3}\ \text{cm}^2/\text{s}\)
The radius of a circle is increasing uniformly at the rate of \(3\ \text{cm}/\text{s}\). Find the rate at which the area of the circle is increasing when the radius is \(10\text{ cm}\).
\(60\pi\ \text{cm}^2/\text{s}\)
An edge of a variable cube is increasing at the rate of \(3\ \text{cm}/\text{s}\). How fast is the volume of the cube increasing when the edge is \(10\text{ cm}\) long?
\(900\ \text{cm}^3/\text{s}\)
A stone is dropped into a quiet lake and waves move in circles at the speed of \(5\ \text{cm}/\text{s}\). At the instant when the radius of the circular wave is \(8\text{ cm}\), how fast is the enclosed area increasing?
\(80\pi\ \text{cm}^2/\text{s}\)
The radius of a circle is increasing at the rate of \(0.7\ \text{cm}/\text{s}\). What is the rate of increase of its circumference?
\(1.4\pi\ \text{cm}/\text{s}\)
The length \(x\) of a rectangle is decreasing at the rate of \(5\ \text{cm}/\text{minute}\) and the width \(y\) is increasing at the rate of \(4\ \text{cm}/\text{minute}\). When \(x = 8\text{ cm}\) and \(y = 6\text{ cm}\), find the rates of change of
(a) the perimeter, and
(b) the area of the rectangle.
(a) \(-2\ \text{cm}/\text{min}\)
(b) \(2\ \text{cm}^2/\text{min}\)
A balloon, which always remains spherical on inflation, is being inflated by pumping in \(900\) cubic centimetres of gas per second. Find the rate at which the radius of the balloon increases when the radius is \(15\text{ cm}\).
\(\frac{1}{\pi}\ \text{cm}/\text{s}\)
A balloon, which always remains spherical has a variable radius. Find the rate at which its volume is increasing with the radius when the later is \(10\text{ cm}\).
\(400\pi\ \text{cm}^3/\text{cm}\)
A ladder \(5\text{ m}\) long is leaning against a wall. The bottom of the ladder is pulled along the ground, away from the wall, at the rate of \(2\text{ cm}/\text{s}\). How fast is its height on the wall decreasing when the foot of the ladder is \(4\text{ m}\) away from the wall?
\(\frac{8}{3}\ \text{cm}/\text{s}\)
A particle moves along the curve \(6y = x^3 + 2\). Find the points on the curve at which the \(y\)-coordinate is changing 8 times as fast as the \(x\)-coordinate.
\((4, 11)\) and \((-4, -\frac{31}{3})\)
The radius of an air bubble is increasing at the rate of \(\frac{1}{2}\ \text{cm}/\text{s}\). At what rate is the volume of the bubble increasing when the radius is \(1\text{ cm}\)?
\(2\pi\ \text{cm}^3/\text{s}\)
A balloon, which always remains spherical, has a variable diameter \(\frac{3}{2}(2x+1)\). Find the rate of change of its volume with respect to \(x\).
\(\frac{27}{8}\pi(2x+1)^2\)
Sand is pouring from a pipe at the rate of \(12\ \text{cm}^3/\text{s}\). The falling sand forms a cone on the ground in such a way that the height of the cone is always one-sixth of the radius of the base. How fast is the height of the sand cone increasing when the height is \(4\text{ cm}\)?
\(\frac{1}{48\pi}\ \text{cm}/\text{s}\)
The total cost \(C(x)\) in Rupees associated with the production of \(x\) units of an item is given by
\(C(x) = 0.007x^3 - 0.003x^2 + 15x + 4000\).
Find the marginal cost when \(17\) units are produced.
₹ 20.967
The total revenue in Rupees received from the sale of \(x\) units of a product is given by
\(R(x) = 13x^2 + 26x + 15\).
Find the marginal revenue when \(x = 7\).
₹ 208
The rate of change of the area of a circle with respect to its radius \(r\) at \(r = 6\text{ cm}\) is
(A) \(10\pi\)
(B) \(12\pi\)
(C) \(8\pi\)
(D) \(11\pi\)
B
The total revenue in Rupees received from the sale of \(x\) units of a product is given by
\(R(x) = 3x^2 + 36x + 5\).
The marginal revenue, when \(x = 15\) is
(A) 116
(B) 96
(C) 90
(D) 126
D
Show that the function given by \(f(x) = 3x + 17\) is increasing on \(\mathbb{R}\).
Show that the function given by \(f(x) = e^{2x}\) is increasing on \(\mathbb{R}\).
Show that the function given by \(f(x) = \sin x\) is
(a) increasing in \((0, \frac{\pi}{2})\)
(b) decreasing in \((\frac{\pi}{2}, \pi)\)
(c) neither increasing nor decreasing in \((0, \pi)\).
Find the intervals in which the function \(f\) given by \(f(x) = 2x^2 - 3x\) is
(a) increasing
(b) decreasing.
(a) \((\frac{3}{4}, \infty)\)
(b) \((-\infty, \frac{3}{4})\)
Find the intervals in which the function \(f\) given by \(f(x) = 2x^3 - 3x^2 - 36x + 7\) is
(a) increasing
(b) decreasing.
(a) \((-\infty, -2)\) and \((3, \infty)\)
(b) \((-2, 3)\)
Find the intervals in which the following functions are strictly increasing or decreasing:
(a) \(x^2 + 2x - 5\)
(b) \(10 - 6x - 2x^2\)
(c) \(-2x^3 - 9x^2 - 12x + 1\)
(d) \(6 - 9x - x^2\)
(e) \((x + 1)^3 (x - 3)^3\)
(a) decreasing for \(x < -1\) and increasing for \(x > -1\)
(b) decreasing for \(x > -\frac{3}{2}\) and increasing for \(x < -\frac{3}{2}\)
(c) increasing for \(-2 < x < -1\) and decreasing for \(x < -2\) and \(x > -1\)
(d) increasing for \(x < -\frac{9}{2}\) and decreasing for \(x > -\frac{9}{2}\)
(e) increasing in \((1, 3)\) and \((3, \infty)\), decreasing in \((-\infty, -1)\) and \((-1, 1)\)
Show that \(y = \log(1 + x) - \frac{2x}{2 + x}\), \(x > -1\), is an increasing function of \(x\) throughout its domain.
Find the values of \(x\) for which \(y = [x(x - 2)]^2\) is an increasing function.
\(0 < x < 1\) and \(x > 2\)
Prove that \(y = \frac{4\sin \theta}{2 + \cos \theta} - \theta\) is an increasing function of \(\theta\) in \([0, \frac{\pi}{2}]\).
Prove that the logarithmic function is increasing on \((0, \infty)\).
Prove that the function \(f\) given by \(f(x) = x^2 - x + 1\) is neither strictly increasing nor decreasing on \((-1, 1)\).
Which of the following functions are decreasing on \((0, \frac{\pi}{2})\)?
(A) \(\cos x\)
(B) \(\cos 2x\)
(C) \(\cos 3x\)
(D) \(\tan x\)
A, B
On which of the following intervals is the function \(f\) given by \(f(x) = x^{100} + \sin x - 1\) decreasing?
(A) \((0, 1)\)
(B) \((\frac{\pi}{2}, \pi)\)
(C) \((0, \frac{\pi}{2})\)
(D) None of these
D
For what values of \(a\) the function \(f\) given by \(f(x) = x^2 + ax + 1\) is increasing on \([1, 2]\)?
\(a > -2\)
Let \(I\) be any interval disjoint from \([-1, 1]\). Prove that the function \(f\) given by \(f(x) = x + \frac{1}{x}\) is increasing on \(I\).
Prove that the function \(f\) given by \(f(x) = \log \sin x\) is increasing on \((0, \frac{\pi}{2})\) and decreasing on \((\frac{\pi}{2}, \pi)\).
Prove that the function given by \(f(x) = \log |\cos x|\) is decreasing on \((0, \frac{\pi}{2})\) and increasing on \((\frac{3\pi}{2}, 2\pi)\).
Prove that the function given by \(f(x) = x^3 - 3x^2 + 3x - 100\) is increasing in \(\mathbb{R}\).
The interval in which \(y = x^2 e^{-x}\) is increasing is
(A) \((-\infty, \infty)\)
(B) \((-2, 0)\)
(C) \((2, \infty)\)
(D) \((0, 2)\)
D
Find the maximum and minimum values, if any, of the following functions given by
(i) \(f(x) = (2x - 1)^2 + 3\)
(ii) \(f(x) = 9x^2 + 12x + 2\)
(iii) \(f(x) = -(x - 1)^2 + 10\)
(iv) \(g(x) = x^3 + 1\)
(i) Minimum Value = 3
(ii) Minimum Value = -2
(iii) Maximum Value = 10
(iv) Neither minimum nor maximum value
Find the maximum and minimum values, if any, of the following functions given by
(i) \(f(x) = |x + 2| - 1\)
(ii) \(g(x) = -|x + 1| + 3\)
(iii) \(h(x) = \sin(2x) + 5\)
(iv) \(f(x) = |\sin 4x + 3|\)
(v) \(h(x) = x + 1,\ x \in (-1, 1)\)
(i) Minimum Value = -1; No maximum value
(ii) Maximum Value = 3; No minimum value
(iii) Minimum Value = 4; Maximum Value = 6
(iv) Minimum Value = 2; Maximum Value = 4
(v) Neither minimum nor Maximum Value
Find the local maxima and local minima, if any, of the following functions. Find also the local maximum and the local minimum values, as the case may be:
(i) \(f(x) = x^2\)
(ii) \(g(x) = x^3 - 3x\)
(iii) \(h(x) = \sin x + \cos x,\ 0 < x < \frac{\pi}{2}\)
(iv) \(f(x) = \sin x - \cos x,\ 0 < x < 2\pi\)
(v) \(f(x) = x^3 - 6x^2 + 9x + 15\)
(vi) \(g(x) = \frac{x}{2} + \frac{2}{x},\ x > 0\)
(vii) \(g(x) = \frac{1}{x^2 + 2}\)
(viii) \(f(x) = x\sqrt{1 - x},\ 0 < x < 1\)
(i) local minimum at \(x = 0\), local minimum value = 0
(ii) local minimum at \(x = 1\), local minimum value = -2; local maximum at \(x = -1\), local maximum value = 2
(iii) local maximum at \(x = \frac{\pi}{4}\), local maximum value = \(\sqrt{2}\)
(iv) local maximum at \(x = \frac{3\pi}{4}\), local maximum value = \(\sqrt{2}\); local minimum at \(x = \frac{7\pi}{4}\), local minimum value = \(-\sqrt{2}\)
(v) local maximum at \(x = 1\), local maximum value = 19; local minimum at \(x = 3\), local minimum value = 15
(vi) local minimum at \(x = 2\), local minimum value = 2
(vii) local maximum at \(x = 0\), local maximum value = \(\frac{1}{2}\)
(viii) local maximum at \(x = \frac{2}{3}\), local maximum value = \(\frac{2\sqrt{3}}{9}\)
Prove that the following functions do not have maxima or minima:
(i) \(f(x) = e^x\)
(ii) \(g(x) = \log x\)
(iii) \(h(x) = x^3 + x^2 + x + 1\)
Find the absolute maximum value and the absolute minimum value of the following functions in the given intervals:
(i) \(f(x) = x^3,\ x \in [-2, 2]\)
(ii) \(f(x) = \sin x + \cos x,\ x \in [0, \pi]\)
(iii) \(f(x) = 4x - \frac{1}{2}x^2,\ x \in \left[-2, \frac{9}{2}\right]\)
(iv) \(f(x) = (x - 1)^2 + 3,\ x \in [-3, 1]\)
(i) Absolute minimum value = -8, absolute maximum value = 8
(ii) Absolute minimum value = -1, absolute maximum value = \(\sqrt{2}\)
(iii) Absolute minimum value = -10, absolute maximum value = 8
(iv) Absolute minimum value = 19, absolute maximum value = 3
Find the maximum profit that a company can make, if the profit function is given by
\(p(x) = 41 - 72x - 18x^2\).
Maximum profit = 113 unit.
Find both the maximum value and the minimum value of \(3x^4 - 8x^3 + 12x^2 - 48x + 25\) on the interval \([0, 3]\).
Minima at \(x = 2\), minimum value = -39; Maxima at \(x = 0\), maximum value = 25.
At what points in the interval \([0, 2\pi]\), does the function \(\sin 2x\) attain its maximum value?
At \(x = \frac{\pi}{4}\) and \(\frac{5\pi}{4}\)
What is the maximum value of the function \(\sin x + \cos x\)?
Maximum value = \(\sqrt{2}\)
Find the maximum value of \(2x^3 - 24x + 107\) in the interval \([1, 3]\). Find the maximum value of the same function in \([-3, -1]\).
Maximum at \(x = 3\), maximum value 89; maximum at \(x = -2\), maximum value = 139
It is given that at \(x = 1\), the function \(x^4 - 62x^2 + ax + 9\) attains its maximum value on the interval \([0, 2]\). Find the value of \(a\).
\(a = 120\)
Find the maximum and minimum values of \(x + \sin 2x\) on \([0, 2\pi]\).
Maximum at \(x = 2\pi\), maximum value = \(2\pi\); Minimum at \(x = 0\), minimum value = 0
Find two numbers whose sum is \(24\) and whose product is as large as possible.
12, 12
Find two positive numbers \(x\) and \(y\) such that \(x + y = 60\) and \(xy^3\) is maximum.
45, 15
Find two positive numbers \(x\) and \(y\) such that their sum is \(35\) and the product \(x^2 y^5\) is a maximum.
25, 10
Find two positive numbers whose sum is \(16\) and the sum of whose cubes is minimum.
8, 8
A square piece of tin of side \(18\text{ cm}\) is to be made into a box without top, by cutting a square from each corner and folding up the flaps to form the box. What should be the side of the square to be cut off so that the volume of the box is the maximum possible.
3 cm
A rectangular sheet of tin \(45\text{ cm}\) by \(24\text{ cm}\) is to be made into a box without top, by cutting off square from each corner and folding up the flaps. What should be the side of the square to be cut off so that the volume of the box is maximum?
\(x = 5\text{ cm}\)
Show that of all the rectangles inscribed in a given fixed circle, the square has the maximum area.
Show that the right circular cylinder of given surface and maximum volume is such that its height is equal to the diameter of the base.
Of all the closed cylindrical cans (right circular), of a given volume of \(100\) cubic centimetres, find the dimensions of the can which has the minimum surface area?
Radius = \(\left(\frac{50}{\pi}\right)^{1/3}\) cm and height = \(2\left(\frac{50}{\pi}\right)^{1/3}\) cm
A wire of length \(28\text{ m}\) 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?
\(\frac{112}{\pi + 4}\) m, \(\frac{28\pi}{\pi + 4}\) m
Prove that the volume of the largest cone that can be inscribed in a sphere of radius \(R\) is \(\frac{8}{27}\) of the volume of the sphere.
Show that the right circular cone of least curved surface and given volume has an altitude equal to \(\sqrt{2}\) time the radius of the base.
Show that the semi-vertical angle of the cone of the maximum volume and of given slant height is \(\tan^{-1} \sqrt{2}\).
Show that semi-vertical angle of right circular cone of given surface area and maximum volume is \(\sin^{-1}\left(\frac{1}{3}\right)\).
The point on the curve \(x^2 = 2y\) which is nearest to the point \((0, 5)\) is
\((2\sqrt{2}, 4)\)
\((2\sqrt{2}, 0)\)
\((0, 0)\)
\((2, 2)\)
For all real values of \(x\), the minimum value of \(\frac{1 - x + x^2}{1 + x + x^2}\) is
0
1
3
\(\frac{1}{3}\)
The maximum value of \([x(x - 1) + 1]^{1/3}\), \(0 \le x \le 1\) is
\(\left(\frac{1}{3}\right)^{1/3}\)
\(\frac{1}{2}\)
1
0
Show that the function given by \(f(x) = \frac{\log x}{x}\) has maximum at \(x = e\).
The two equal sides of an isosceles triangle with fixed base \(b\) are decreasing at the rate of \(3\) cm per second. How fast is the area decreasing when the two equal sides are equal to the base?
\(b\sqrt{3}\ \text{cm}^2/\text{s}\)
Find the intervals in which the function \(f\) given by
\(f(x) = \frac{4\sin x - 2x - x\cos x}{2 + \cos x}\)
is (i) increasing (ii) decreasing.
(i) \(0 \le x \le \frac{\pi}{2}\) and \(\frac{3\pi}{2} < x < 2\pi\)
(ii) \(\frac{\pi}{2} < x < \frac{3\pi}{2}\)
Find the intervals in which the function \(f\) given by \(f(x) = x^3 + \frac{1}{x^3},\ x \ne 0\) is
(i) increasing
(ii) decreasing.
(i) \(x < -1\) and \(x > 1\)
(ii) \(-1 < x < 1\)
Find the maximum area of an isosceles triangle inscribed in the ellipse
\(\frac{x^2}{a^2} + \frac{y^2}{b^2} = 1\)
with its vertex at one end of the major axis.
\(\frac{3\sqrt{3}}{4}ab\)
A tank with rectangular base and rectangular sides, open at the top, is to be constructed so that its depth is \(2\) m and volume is \(8\,m^3\). If building of tank costs Rs \(70\) per sq metre for the base and Rs \(45\) per square metre for sides, what is the cost of least expensive tank?
Rs 1000
The sum of the perimeter of a circle and square is \(k\), where \(k\) is some constant. Prove that the sum of their areas is least when the side of square is double the radius of the circle.
A window is in the form of a rectangle surmounted by a semicircular opening. The total perimeter of the window is \(10\) m. Find the dimensions of the window to admit maximum light through the whole opening.
Length = \(\frac{20}{\pi + 4}\) m, Breadth = \(\frac{10}{\pi + 4}\) m
A point on the hypotenuse of a triangle is at distance \(a\) and \(b\) from the sides of the triangle. Show that the minimum length of the hypotenuse is
\(\left(a^{2/3} + b^{2/3}\right)^{3/2}\).
Find the points at which the function \(f\) given by \(f(x) = (x - 2)^4 (x + 1)^3\) has
(i) local maxima
(ii) local minima
(iii) point of inflexion.
(i) local maxima at \(x = \frac{2}{7}\)
(ii) local minima at \(x = 2\)
(iii) point of inflexion at \(x = -1\)
Find the absolute maximum and minimum values of the function \(f\) given by \(f(x) = \cos^2 x + \sin x,\ x \in [0, \pi]\).
Absolute maximum = \(\frac{5}{4}\), Absolute minimum = 1
Show that the altitude of the right circular cone of maximum volume that can be inscribed in a sphere of radius \(r\) is \(\frac{4r}{3}\).
Let \(f\) be a function defined on \([a, b]\) such that \(f'(x) > 0\), for all \(x \in (a, b)\). Then prove that \(f\) is an increasing function on \((a, b)\).
Show that the height of the cylinder of maximum volume that can be inscribed in a sphere of radius \(R\) is \(\frac{2R}{\sqrt{3}}\). Also find the maximum volume.
Maximum volume = \(\frac{4\pi R^3}{3\sqrt{3}}\)
Show that height of the cylinder of greatest volume which can be inscribed in a right circular cone of height \(h\) and semi vertical angle \(\alpha\) is one-third that of the cone and the greatest volume of cylinder is
\(\frac{4}{27}\pi h^3 \tan^2 \alpha\).
A cylindrical tank of radius \(10\) m is being filled with wheat at the rate of \(314\) cubic metre per hour. Then the depth of the wheat is increasing at the rate of
\(1\) m/h
\(0.1\) m/h
\(1.1\) m/h
\(0.5\) m/h