The area bounded by [x] +[y] = 8 such that x, y > 0 is .... sq. units
Where [.] is G.I.F.
Area of 9 unit squares = 9 sq.units
Let f : [0, ∞)→ R be a continuous and strictly increasing function such that The area enclosed by y = f (x), the x-axis and the ordinate at x = 3, is
Given, f3(x) = ∫(0 to x)tf(t)dt
Differentiating throughout w.r.t x,
3f2(x) f′(x) = xf2(x)
⇒ f′(x)= x/3
So, f(x)=∫(0 to x) x/3 dx = (x2)/6
Area = ∫f(x)dx=∫(0 to 3) (x2)/6 dx
= {(x3)/18}(0 to 3)
= 3/2
The area bounded by x = x1, y = y1 and y = -(x + 1)2 where x1, y1 are the values of x, y satisfying the equation sin-1x + sin-1y = -π will be, (nearer to origin)
Area bounded between the curves
and
be two functions and let f1(x) = max {f(t), 0 < t < x, 0 < x <} and g1(x) = min {g(t), 0 < t < x, 0 < x < 1}. Then the area bounded by f1(x) < 0, g1(x) < 0 and x-axis is
The values of the parameter a(a > 1) for which the area of the figure bounded by the pair of straight lines y2 – 3y + 2 = 0 and the curves is greatest is.
(Here [.] denotes the greatest integer function).
The curves represent parabolas which are symmetric about yaxis. The equation y2 – 3y + 2 = 0 gives a pair of straight lines y = 1, y = 2 which are parallel to x-axis. The shaded region in figure determines the area bounded by the two parabolas and two lines. Let us slice this region into horizontal strips. For the approximating rectangle shown in figure. We have Length = x2 – x1, width = Δy, Area = (x2 - x1)dy
AT it can move vertically y = 1 and y = 2. So, Required area
Area of region bounded by x2 + y2 < 4 and (|x| + |y|) < 2 is ____ square units.
Using circles representation, required area = 8 sq. units
The area of a circle is A1 and the area of a regular pentagon inscribed in the circle is A2 .Then A1 : A2 is
The area bounded by the curve and x-axis is
the area of the region bounded by y = x and y = x+ sin x is
The area bounded by the curves y = x2, y = [x+1], x < 1 and the y - axis, where[.] denotes the greatest integer not exceeding x, is
The area of the smaller region in which the curve denotes the greatest integer function, divides the circle (x – 2)2 + (y + 1)2 = 4, is equal to
Circle has (2, -1) as its centre and radius of this circle is 2.
Thus if P(x, y) be any point on it, then x ∈ [0, 4].
The g(x) is increasing in [0, 4]
The area bounded by the curves y = 2- |x -1| , y = sin x ; x = 0 and x =2 is
A curve passes through the point (0,1)and has the property that the slope of the curve at every point P is twice the y–coordinate of P . If the area bounded by the curve, the axes of coordinates and the line
The area bounded by the curve (y – arc sinx)2 = x – x2, is
The area of the region enclosed by the curve 5x2 + 6xy + 2y2 + 7x + 6y + 6 = 0 is
Comparing the given equation with the general equation of second degree i.e.
ax2 + 2hxy + by2 + 2gx + 2fy + c = 0,
We have, abc + 2fgh – af2 – bg2 – ch2 = 60 – 45
And h2 – ab = 9 – 10 < 0.
So, the given equation represents an ellipse.
Rewriting the given equation as a quadratic in y, we obtain
Clearly, the values of y are real for x ∈ [1, 3]
When x = 1, we get y = -3 and x = 3 ⇒ y = -6.
Let f(x) be a continuous function such that the area bounded by the curve y = f(x), the xaxis and the two ordinates x = 0 and
Differentiating both sides w.r.t. a, we get
The area enclosed between the curves y = sin4x cos3x, y = sin2xcos3x between x = 0 and
Required area is equal to
The area of the region bounded by the curves which contains (1, 0) point in its interior is
We observe that all powers of x in the above equation are even, so it is symmetric about y-axis. The curve intersects y-axis at (0, 1). Also,
Therefore, as x → ∞, y → -1 i.e. y = -1 is an asymptote to the curve.
This means that x is imaginary for y > 1 or y < -1 i.e. the curve lies between y = -1 and y = 1. At (0, 1) the tangent to the curve
Area bounded by the curves y = ex , y= loge x and the lines x = 0, y = 0, y = 1 is
Area = Area of rectangle
A circular arc of radius ‘1’ subtends an angle of ‘x’ radians, as shown in the figure. The point ‘R’ is the point of intersection of the two tangent lines at P & Q. Let T(x) be the area of triangle PQR and S(x) be area of the shaded region. Then
A point P moves inside a triangle formed by such that min {PA, PB, PC} = 1. The area formed by the curve traced by P is ....... sq. units
Re quired area = Area of equilateral
Area of the triangle formed by the tangent and normal at (1, 1) on the curve and the y-axis is
Find equation of the tangent and normal and then put x=0 to evaluate vertices of triangle.
Then find area of triangle .
Area bounded by the curve and area bounded by latus rectum of
Area bounded by C1 & C2 is λ1 = 16/3 sq.units
λ2 = Area bounded by C1 & its latus rectum = 8/3 sq.units
The area of the part of circle x2 + y2 - 2x - 4y -1 = 0 above 2x - y = 0 is ...... sq. units
Required area = Area of semi-circle
Since given line is diameter of circle
The area bounded by the curves y = |x| – 1 and y – |x| 1is
Area of closed curve 3(x -1)2 + 4(y2 - 3) = 0 is where [.] is G.I.F
Let f(x) = x + sin x. The area bounded by y = f-1 (x), y = x, x ∈ [0, π] is
The curves given by y = x + sin x and y = f-1(x) are images of each other in the line y = x.
Hence required area
The area of the region bounded by the curves |x + y| < 2, |x – y| < 2 and 2x2 + 6y2 > 3 is
2x2 + 6y2 > 3. . . . . . (1) area of ellipse
Area enclosed by the closed curve 5x2 + 6xy + 2y2 + 7x + 6y + 6 = 0 is
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