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1201 |
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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1202 |
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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1203 |
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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1204 |
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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1205 |
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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1206 |
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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1207 |
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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1208 |
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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1209 |
Investigate for maxima and minima the function
 a) Local maximum at x = 1, 7/5, 2 b) Local minimum at x = 1, 7/5, 2 c) Local maximum at x = 1, 2. Local minimum at x = 7/5 d) Local maximum at x = 1. Local minimum at x = 7/5
Investigate for maxima and minima the function
a) Local maximum at x = 1, 7/5, 2 b) Local minimum at x = 1, 7/5, 2 c) Local maximum at x = 1, 2. Local minimum at x = 7/5 d) Local maximum at x = 1. Local minimum at x = 7/5
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IIT 1988 |
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1210 |
Sides a, b, c of a triangle ABC are in arithmetic progression and  then
Sides a, b, c of a triangle ABC are in arithmetic progression and then
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IIT 2006 |
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1211 |
A window of perimeter (including the base of the arch) is in the form of a rectangle surmounted by a semicircle. The semi-circular portion is fitted with coloured glass while the rectangular part is fitted with clear glass. The clear glass transmits three times as much light per square meter as the coloured glass. What is the ratio for the sides of the rectangle so that the window transmits the maximum light? a)  b)  c)  d) 
A window of perimeter (including the base of the arch) is in the form of a rectangle surmounted by a semicircle. The semi-circular portion is fitted with coloured glass while the rectangular part is fitted with clear glass. The clear glass transmits three times as much light per square meter as the coloured glass. What is the ratio for the sides of the rectangle so that the window transmits the maximum light? a) b) c) d)
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IIT 1991 |
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1212 |
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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1213 |
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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1214 |
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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1215 |
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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1216 |
 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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1217 |
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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1218 |
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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1219 |
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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1220 |
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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1221 |
ABCD is a rhombus. The diagonals AC and BD intersect at the point M and satisfy BD = 2AC. If the points D and M represent the complex numbers 1 + i and (2 – i) respectively then find the complex number x + iy represented by A. a)  b)  c)  d) 
ABCD is a rhombus. The diagonals AC and BD intersect at the point M and satisfy BD = 2AC. If the points D and M represent the complex numbers 1 + i and (2 – i) respectively then find the complex number x + iy represented by A. a) b) c) d)
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IIT 1993 |
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1222 |
Find all possible values of b > 0, so that the area of the bounded region enclosed between the parabolas  and  is maximum. a) b = 1 b) b ≥ 1 c) b ≤ 1 d) 0 < b < 1
Find all possible values of b > 0, so that the area of the bounded region enclosed between the parabolas and is maximum. a) b = 1 b) b ≥ 1 c) b ≤ 1 d) 0 < b < 1
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IIT 1997 |
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1223 |
Let f(x) = sinx and g(x) = ln|x|. If the ranges of the composition function fog and gof are R1 and R2 respectively then a)  b)  ,  c)  d) 
Let f(x) = sinx and g(x) = ln|x|. If the ranges of the composition function fog and gof are R1 and R2 respectively then a) b) , c) d)
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IIT 1994 |
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1224 |
Let C1 and C2 be the graph of the function y = x2 and y = 2x respectively. Let C3 be the graph of the function
y = f (x), 0 ≤ x ≤ 1, f (0) = 0. Consider a point P on C1. Let the lines through P, parallel to the axes meet C2 and C3 at Q and R respectively (see figure). If for every position of P (on C1) the area of the shaded regions OPQ and OPR are equal, determine the function f(x). 
a) x2 – 1 b) x3 – 1 c) x3 – x2 d) 1 + x2 + x3
Let C1 and C2 be the graph of the function y = x2 and y = 2x respectively. Let C3 be the graph of the function
y = f (x), 0 ≤ x ≤ 1, f (0) = 0. Consider a point P on C1. Let the lines through P, parallel to the axes meet C2 and C3 at Q and R respectively (see figure). If for every position of P (on C1) the area of the shaded regions OPQ and OPR are equal, determine the function f(x).
a) x2 – 1 b) x3 – 1 c) x3 – x2 d) 1 + x2 + x3
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IIT 1998 |
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1225 |
A hemispherical tank of radius 2 meters is initially full of water and has an outlet of 12cm2 cross section area at the bottom. The outlet is opened at some instant. The flow through the outlet is according to the law  where g(t) and h(t) are respectively the velocity of the flow through the outlet and the height of the water level above the outlet at the time t, and g is the acceleration due to gravity. Find the time it takes to empty the tank. (Hint: Form a differential equation by relating the decrease of water level to the outflow). a)  b)  c)  d) 
A hemispherical tank of radius 2 meters is initially full of water and has an outlet of 12cm2 cross section area at the bottom. The outlet is opened at some instant. The flow through the outlet is according to the law where g(t) and h(t) are respectively the velocity of the flow through the outlet and the height of the water level above the outlet at the time t, and g is the acceleration due to gravity. Find the time it takes to empty the tank. (Hint: Form a differential equation by relating the decrease of water level to the outflow). a) b) c) d)
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IIT 2001 |
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