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1201 |
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}
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IIT 1996 |
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1202 |
PQ and PR are two infinite rays, QAR is an arc. 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. 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) 
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IIT 2005 |
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1203 |
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
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IIT 1989 |
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1204 |
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. If P is a point on C1 and Q is another point on C2, then is equal to a) 0.75 b) 1.25 c) 1 d) 0.5
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. If P is a point on C1 and Q is another point on C2, then is equal to a) 0.75 b) 1.25 c) 1 d) 0.5
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IIT 2006 |
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1205 |
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. The positive value of k for which has only one root is a)  b) 1 c) e d) ln2
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. The positive value of k for which has only one root is a)  b) 1 c) e d) ln2
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IIT 2007 |
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1206 |
Let . Find the intervals in which λ should lie in order that f(x) has exactly one minimum and exactly one maximum. a)  b)  c)  d) 
Let . Find the intervals in which λ should lie in order that f(x) has exactly one minimum and exactly one maximum. a)  b)  c)  d) 
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IIT 1985 |
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1207 |
Consider a circle with centre lying on the focus of the parabola such that it touches the directrix of the parabola. Then a point of intersection of the circle and parabola is a) or  b)  c)  d) 
Consider a circle with centre lying on the focus of the parabola such that it touches the directrix of the parabola. Then a point of intersection of the circle and parabola is a) or  b)  c)  d) 
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IIT 1995 |
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1208 |
Find the equation of the plane at a distance from the point and containing the line .
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IIT 2005 |
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1209 |
Let the complex numbers are vertices of an equilateral triangle. If be the circumcentre of the triangle, then prove that 
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IIT 1981 |
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1210 |
A two metre long object is fired vertically upwards from the mid-point of two locations A and B, 8 metres apart. The speed of the object after t seconds is given by metres per second. Let α and β be the angles subtended by the objects A and B respectively after one and two seconds. Find the value of cos(α − β). a)  b)  c)  d) 
A two metre long object is fired vertically upwards from the mid-point of two locations A and B, 8 metres apart. The speed of the object after t seconds is given by metres per second. Let α and β be the angles subtended by the objects A and B respectively after one and two seconds. Find the value of cos(α − β). a)  b)  c)  d) 
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IIT 1989 |
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1211 |
The point (α, β, γ) lies on the plane . Let a = . . . . .
The point (α, β, γ) lies on the plane . Let a = . . . . .
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IIT 2006 |
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1212 |
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) 
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IIT 2002 |
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1213 |
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IIT 2006 |
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1214 |
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 
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IIT 1986 |
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1215 |
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 = 
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IIT 1989 |
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1216 |
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 . . .
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IIT 2006 |
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1217 |
Prove that for complex numbers z and ω, iff z = ω or .
Prove that for complex numbers z and ω, iff z = ω or .
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IIT 1999 |
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1218 |
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) 
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IIT 1994 |
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1219 |
Points A, B, C lie on the parabola . The tangents to the parabola at A, B, C taken in pair intersect at the points P, Q, R. Determine the ratios of the areas of ΔABC and ΔPQR.
Points A, B, C lie on the parabola . The tangents to the parabola at A, B, C taken in pair intersect at the points P, Q, R. Determine the ratios of the areas of ΔABC and ΔPQR.
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IIT 1996 |
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1220 |
Consider the lines given by L1 : x + 3y – 5 = 0; L2 = 3x – ky – 1 = 0; L3 = 5x + 2y −12 = 0. Match the statement/expressions in column 1 with column 2. | Column 1 | Column 2 | | A. L1, L2, L3 are concurrent, if | p. k = −9 | | B. One of L1, L2, L3 is parallel to at least one of the other two, if | q.  | | C. L1, L2, L3 form a triangle, if | r.  | | D.L1, L2, L3 do not form a triangle, if | s. k = 5 |
Consider the lines given by L1 : x + 3y – 5 = 0; L2 = 3x – ky – 1 = 0; L3 = 5x + 2y −12 = 0. Match the statement/expressions in column 1 with column 2. | Column 1 | Column 2 | | A. L1, L2, L3 are concurrent, if | p. k = −9 | | B. One of L1, L2, L3 is parallel to at least one of the other two, if | q.  | | C. L1, L2, L3 form a triangle, if | r.  | | D.L1, L2, L3 do not form a triangle, if | s. k = 5 |
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IIT 2008 |
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1221 |
is a circle inscribed in a square whose one vertex is . Find the remaining vertices. a)  b)  c)  d) 
is a circle inscribed in a square whose one vertex is . Find the remaining vertices. a)  b)  c)  d) 
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IIT 2005 |
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1222 |
Let a line passing through the fixed point (h, k) cut the X–axis at P and Y–axis at Q. Then find the minimum area of ΔOPQ. a) hk b) h2/k c) k2/h d) 2hk
Let a line passing through the fixed point (h, k) cut the X–axis at P and Y–axis at Q. Then find the minimum area of ΔOPQ. a) hk b) h2/k c) k2/h d) 2hk
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IIT 1995 |
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1223 |
Match the following | Column 1 | Column 2 | | i) Re z = 0 | A) Re = 0 | | ii) Arg z = π/4 | B) Im = 0 | | | C) Re = Im  |
Match the following | Column 1 | Column 2 | | i) Re z = 0 | A) Re = 0 | | ii) Arg z = π/4 | B) Im = 0 | | | C) Re = Im  |
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IIT 1992 |
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1224 |
Let An be the area bounded by the curve y = (tanx)n and the line x = 0, y = 0 and . Prove that for . Hence deduce that
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IIT 1996 |
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1225 |
Consider the circle x2 + y2 = 9 and the parabola y2 = 8x. They intersect P and Q in the first and fourth quadrants respectively. Tangents to the circle at P and Q intersect the X–axis at R and tangents to the parabola at P and Q intersect the X- axis at S. The radius of the incircle of △PQR is a) 4 b) 3 c)  d) 2
Consider the circle x2 + y2 = 9 and the parabola y2 = 8x. They intersect P and Q in the first and fourth quadrants respectively. Tangents to the circle at P and Q intersect the X–axis at R and tangents to the parabola at P and Q intersect the X- axis at S. The radius of the incircle of △PQR is a) 4 b) 3 c)  d) 2
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IIT 2007 |
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