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1201

In [0, 1], Lagrange’s Mean Value theorem is not applicable to

a)

b)

c)

d)

In [0, 1], Lagrange’s Mean Value theorem is not applicable to

a)

b)

c)

d)

IIT 2003
1202

Let α ε ℝ, then a function f : ℝ → ℝ is differentiable at α if and only if there is a function g : ℝ → ℝ which is continuous at α and satisfies f(x) – f(α) = g(x) (x – α) for all x ε ℝ.

a) True

b) False

Let α ε ℝ, then a function f : ℝ → ℝ is differentiable at α if and only if there is a function g : ℝ → ℝ which is continuous at α and satisfies f(x) – f(α) = g(x) (x – α) for all x ε ℝ.

a) True

b) False

IIT 2001
1203

The area bounded by the angle bisectors of the lines

x2 – y2 + 2y = 1 and the line x + y = 3 is

a) 2

b) 3

c) 4

d) 6

The area bounded by the angle bisectors of the lines

x2 – y2 + 2y = 1 and the line x + y = 3 is

a) 2

b) 3

c) 4

d) 6

IIT 2004
1204

If two functions f and g satisfy the given conditions  x, y ε ℝ, f(x – y) = f(x)g(y) – f(y)g(x) and g(x – y) = g(x) . g(y) + f(x) . f(y).

If the RHD at x = 0 exists for f(x) then find the derivative of g(x) at x = 0.

If two functions f and g satisfy the given conditions  x, y ε ℝ, f(x – y) = f(x)g(y) – f(y)g(x) and g(x – y) = g(x) . g(y) + f(x) . f(y).

If the RHD at x = 0 exists for f(x) then find the derivative of g(x) at x = 0.

IIT 2005
1205

Let

be a real valued function. The set of points where f(x) is not differentiable are

a) {0}

b) {1}

c) {0, 1}

d) {∅}

Let

be a real valued function. The set of points where f(x) is not differentiable are

a) {0}

b) {1}

c) {0, 1}

d) {∅}

IIT 1981
1206

Multiple choice

Let  and

 

Then g(x) has

a) Local maximum at x = 1 + ln2 and local minima at x = e

b) Local maximum at x = 1 and local minima at x = 2

c) No local maximas

d) No local minimas

Multiple choice

Let  and

 

Then g(x) has

a) Local maximum at x = 1 + ln2 and local minima at x = e

b) Local maximum at x = 1 and local minima at x = 2

c) No local maximas

d) No local minimas

IIT 2006
1207

For all x in [0, 1], let the second derivative  of a function f(x) exists and satisfies . If f(0) = f(1) then for all x ε [0, 1]

a)  

b)  

c) None of these

For all x in [0, 1], let the second derivative  of a function f(x) exists and satisfies . If f(0) = f(1) then for all x ε [0, 1]

a)  

b)  

c) None of these

IIT 1981
1208

Match the following

Let the function defined in column 1 have domain  and range ()

Column 1

Column 2

i) 1 + 2x

A) Onto but not one-one

ii) tan x

B) One-one but not onto

C) One-one and onto

D) Neither one

Match the following

Let the function defined in column 1 have domain  and range ()

Column 1

Column 2

i) 1 + 2x

A) Onto but not one-one

ii) tan x

B) One-one but not onto

C) One-one and onto

D) Neither one

IIT 1992
1209

Let f(x) = [x] where [.] denotes the greatest integer function. Then the domain of f is .  .  .  ., points of discontinuity of f are .  .  .  .

a) ∀ x ε I

b) ∀ x ε I − {0}

c) ∀ x ε I – {0, 1}

d) ∀ x ε I – {0, 1, 2}

Let f(x) = [x] where [.] denotes the greatest integer function. Then the domain of f is .  .  .  ., points of discontinuity of f are .  .  .  .

a) ∀ x ε I

b) ∀ x ε I − {0}

c) ∀ x ε I – {0, 1}

d) ∀ x ε I – {0, 1, 2}

IIT 1996
1210

PQ and PR are two infinite rays, QAR is an arc.

U


Points lying in the shaded region excluding the boundary satisfies

a)   |z + 1| > 2; |arg(z + 1)| <

b)   |z + 1| < 2; |arg(z + 1)| <

c)  

d)  

PQ and PR are two infinite rays, QAR is an arc.

U


Points lying in the shaded region excluding the boundary satisfies

a)   |z + 1| > 2; |arg(z + 1)| <

b)   |z + 1| < 2; |arg(z + 1)| <

c)  

d)  

IIT 2005
1211

If  for all positive x where a > 0 and b > 0 then

a) 9ab2 ≥ 4c3

b) 27ab2 ≥ 4c3

c) 9ab2 ≤ 4c3

d) 27ab2 ≤ 4c3

If  for all positive x where a > 0 and b > 0 then

a) 9ab2 ≥ 4c3

b) 27ab2 ≥ 4c3

c) 9ab2 ≤ 4c3

d) 27ab2 ≤ 4c3

IIT 1989
1212

Find the area of the region bounded by the X–axis and the curve defined by
 
 

a) ln2

b) 2ln2

c)

d)

Find the area of the region bounded by the X–axis and the curve defined by
 
 

a) ln2

b) 2ln2

c)

d)

IIT 1984
1213

Let ABCD be a square with side of length 2 units. C2 is the circle through the vertices A, B, C, D and C1 is the circle touching all the sides of the square ABCD. L is a line through A.

A circle touching the line L and the circle C1 externally such that both the circles are on the same side of the line, then the locus of the centre of circle is

a) Ellipse

b) Hyperbola

c) Parabola

d) Pair of straight lines

Let ABCD be a square with side of length 2 units. C2 is the circle through the vertices A, B, C, D and C1 is the circle touching all the sides of the square ABCD. L is a line through A.

A circle touching the line L and the circle C1 externally such that both the circles are on the same side of the line, then the locus of the centre of circle is

a) Ellipse

b) Hyperbola

c) Parabola

d) Pair of straight lines

IIT 2006
1214

Find three dimensional vectors u1, u2, u3 satisfying
u1.u1 = 4; u1.u2 = −2; u1.u3 = 6; u2.u2  = 2; u2.u3 = −5; u3.u3 = 29

Find three dimensional vectors u1, u2, u3 satisfying
u1.u1 = 4; u1.u2 = −2; u1.u3 = 6; u2.u2  = 2; u2.u3 = −5; u3.u3 = 29

IIT 2001
1215

If a continuous function f defined on the real line ℝ, assumes positive and negative values in ℝ then the equation f(x) = 0 has a root in ℝ. For example, it is known that if a continuous function f on ℝ is positive at some points and its minimum value is negative then the equation f(x) = 0 has a root in ℝ. Consider the function f(x) =  for all real x where k is a real constant.

For k > 0, the set of all values of k for which  has two distinct roots is

a)

b)

c)

d) (0, 1)

If a continuous function f defined on the real line ℝ, assumes positive and negative values in ℝ then the equation f(x) = 0 has a root in ℝ. For example, it is known that if a continuous function f on ℝ is positive at some points and its minimum value is negative then the equation f(x) = 0 has a root in ℝ. Consider the function f(x) =  for all real x where k is a real constant.

For k > 0, the set of all values of k for which  has two distinct roots is

a)

b)

c)

d) (0, 1)

IIT 2007
1216

Let f(x) = x3 – x2 + x + 1 and
 
Discuss the continuity and differentiability of f(x) in the interval (0, 2)

a) Continuous and differentiable in (0, 2)

b) Continuous and differentiable in (0, 2)except x = 1

c) Continuous in (0, 2). Differentiable in (0, 2) except x = 1

d) None of the above

Let f(x) = x3 – x2 + x + 1 and
 
Discuss the continuity and differentiability of f(x) in the interval (0, 2)

a) Continuous and differentiable in (0, 2)

b) Continuous and differentiable in (0, 2)except x = 1

c) Continuous in (0, 2). Differentiable in (0, 2) except x = 1

d) None of the above

IIT 1985
1217

A relation R on the set of complex numbers is defined by iff  is real. Show that R is an equivalence relation.

A relation R on the set of complex numbers is defined by iff  is real. Show that R is an equivalence relation.

IIT 1982
1218

Find the point on the curve 4x2 + a2y2 = 4a2, 4 < a2 < 8 that is farthest from the point (0, −2).

a) (a, 0)

b)

c)

d) (0, - 2)

Find the point on the curve 4x2 + a2y2 = 4a2, 4 < a2 < 8 that is farthest from the point (0, −2).

a) (a, 0)

b)

c)

d) (0, - 2)

IIT 1987
1219

The locus of the mid-point of the line segment joining the focus to a moving point on the parabola y2 = 4ax is another parabola with directrix

a) x = −a

b)

c)

d)

The locus of the mid-point of the line segment joining the focus to a moving point on the parabola y2 = 4ax is another parabola with directrix

a) x = −a

b)

c)

d)

IIT 2002
1220

  

  

IIT 2006
1221

Complex numbers  are the vertices A, B, C respectively of an isosceles right angled triangle with right angle at B. Show that

Complex numbers  are the vertices A, B, C respectively of an isosceles right angled triangle with right angle at B. Show that

IIT 1986
1222

Find all maximum and minimum of the curve y = x(x – 1)2, 0 ≤ x ≤ 2. Also find the area bounded by the curve y = x(x – 2)2, the Y–axis and the line y = 2.

a) Local minimum at x = 1, Local maximum at x = , Area =

b) Local minimum at x = , Local maximum at x =1, Area =

c) Local minimum at x = 2, Local maximum at x = , Area =

d) Local minimum at x = , Local maximum at x =2, Area =

Find all maximum and minimum of the curve y = x(x – 1)2, 0 ≤ x ≤ 2. Also find the area bounded by the curve y = x(x – 2)2, the Y–axis and the line y = 2.

a) Local minimum at x = 1, Local maximum at x = , Area =

b) Local minimum at x = , Local maximum at x =1, Area =

c) Local minimum at x = 2, Local maximum at x = , Area =

d) Local minimum at x = , Local maximum at x =2, Area =

IIT 1989
1223

A line is perpendicular to  and passes through (0, 1, 0). Then the perpendicular distance of this line from the origin is  . . .

A line is perpendicular to  and passes through (0, 1, 0). Then the perpendicular distance of this line from the origin is  . . .

IIT 2006
1224

Prove that for complex numbers z and ω,   iff z = ω or .

Prove that for complex numbers z and ω,   iff z = ω or .

IIT 1999
1225

The curve y = ax3 + bx2 + cx + 5 touches the X – axis at (− 2, 0) and cuts the Y–axis at a point Q where the gradient is 3. Find a, b, c.

a)

b)

c)

d)

The curve y = ax3 + bx2 + cx + 5 touches the X – axis at (− 2, 0) and cuts the Y–axis at a point Q where the gradient is 3. Find a, b, c.

a)

b)

c)

d)

IIT 1994

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