Solved question paper for MATHS-1 May-2018 (B-TECH electronics and communication engineering 1st-2nd)

Question paper 1

1. Section A

   1. a) Find asymptotes, parallel to axes, of the curve: y = 

   Answer:

   (a) yx² - y = x² + 1

   || to x axis

             X²=0

             X = 0                    No asymptote || to x axis

   || to y axis

           X²-1 = 0

               X² = 1

               X = 1

2. b) Write a formula to find the volume of the solid generated by the revolution, about
   x-axis, of the area bounded by the curve y = f(x), the x-axis and the ordinates
   x = a and x = b.

   Answer:

   (b) Volume will be given by integrating the terms

                =  

                =  

3. c) Find the value of  , where x = rcosθ & y = rsinθ .

   Answer:

   

   

4. d) If an error of 1% is made in measuring the major and minor axes of an ellipse, what is the
   percentage error in its area?

   Answer:

   (d) let x and y be semi major and semi minor axes of an ellipse.

                                           Area of ellipse = A=

                                           Log A = Logπ + Log x +Log y

   

    1+1=2

                                            Error in area = 2 %

6. e) Is the function  ? If yes, what is its degree?

   Answer:

   Yes, Degree = 2

7. f) What is the value of   over the positive quadrant of the circle x² + y² = 1?

   Answer:

   

   

   

   

   

   =

8. g) Give geometrical interpretation of  

   Answer:

   

   

    

     =  

     =    

     =    

     =   2

9. h) Show that for the vector field  (x² - y² + x)  — (2xy + y)   = 0.

   Answer:

   

       =

          =

           = -2y + 2y

              [  ]

11. i) Show that the vector field  = (-x² + yz)   + (4y — z²x) + (2xz — 4z)  is solenoidal.

    Answer:

    For solenoidal function

    div 

    div f =   

    = -2x + 4 + 2x -4

    = 0

    So it is solenoidal

12. j) State Green’s theorem in plane.

    Answer:

    Green’s theorem in plane:-

    Let R bed closed region of x-y plane bounded by a simple closed cense c and let M and N be continuous function of x and y having continuous partial derivative  and  in R then:

    

13. Section B

    2. Trace the following curves by giving their salient feature:
    a) y² (a — x) = x² (a + x).
    b) r = a (1 — cosθ)

    Answer:

    (a) Symmetry:  Symmetrical about x-axis

    Origin: passes through origin and tangent at origin

           y= x and y =-x   therefore origin is a node.

          Asymptotes x = a

     Points:  it crones the Ares at (0,0) and  (-a,0 )

          When x >a  or  <-a    y is imaginary

    Shape of curve is strophoid      

    (b) Given figure is a cardioid and symmetrical about q = 0 i.e. initial line.

    q  varies from (0-π/2 ) or (0-180).

     

14. 3. a) Find the whole length of the curve  x^2/3  + y^2/3 = a^2/3 .

    b) Use definite integral to find the area of ellipse  

    Answer:

    (a) Given curve is asteroid. Which is symmetrical about x-axis and y-axis therefore entries length of curve is four times the length of one part.

       Diff given curve w.r.t x

    2/3x^-1/3+ 2/3y^-1/3dy/dx =0

              2/3y^-1/3dy/dx = -2/3x^-1/3

    dy/dx=-(y/x)^1/3

    total length = 4    = 4 

    

     = 4 

    

    = 6a

    (b)   

          Therefore area of ellipse = 4x area of ellipse in I quadrant.

            =

            =

    =

     

    Therefore required area = area of region PQRS

     = 4 x area of region OFPB in the first quadrant

    
      =

      = 

      = 

16. 4. a) lf u = log (x³ +y³ +z³ —3xyz), show that  =   -9(x+y+z)^-2

    b) State Euler’s theorem for homogeneous functions and apply it to show that
      ,   where sin u  =

    Answer:

    (a) 

           =

    

    

     

                                            = 

                                            =

                                            =

    

    (b)  Euler’s theorem  

                  If H= f (x, y, z)is ahomogeneous function of x, y and z of degree n, then

    

    U= sin^-1(x²+y²/x+y)

           Sin u = x²+y²/x+y

          F =   x²+y²/x+y

    Which is homogeneous of degree 1.

     By Euler’s theorem  

    

    

    

              =

17. 5. a) The temperature T at any point (x, y, z) in space is T = 400xyz² . Find the highest
    temperature on the surface of the unit sphere x² + y² + z²= 1.

    b) If f(x,y) = tan^-1 xy, compute f(0.9, –1.2) approximately.

    Answer:

    (a) Temperature at any point on sphere is given by

                  T= 400 xy (1-x²-y²)

      = 400y -400y³-1200x²y

    400x – 1200xy²-400x³

     For critical points

    400y-400y³-1200x²y

      400x(1-3y²-x²)=0

    critical points after solution above equation are

    (0,0),(±1,0),(0, ±1),( ±1/2, ±1/2) out of which first three given the value of T to be zero. For other four point (±1/2, ±1/2). Now A = =  2400 xy, B =   = 400-1200y²-1200x², C= = -2400xy

    At (1/2,1/2,) A= -600 <  0, B= -200, C = -600 so that AC-B²= 320000> 0

    ∴  T is maximum at(1/2,1/2)

                                          Whose maximum value will be given by

                                   = 400 ¼(1 -1/4 - 1/4) = 100 x ½ =50

     

    (b)  f(x,y) = tan^-1xy

       Let x=0.9  , y=-1

    X+δx= 0.9      1+δx=0.9                =δx=-1            =   

         -y+ δy=-1.2       δy=-1.2+1            = δy = -0.2

    df=                        = y/1+x²y²  dx + x/1+x²y²dy = ydx+xdy/1+x²y²

        When x =1

                   Y = -1

    df =

                           =   =   = 

    

18. Section C

    6. a) Evaluate the following integral by changing the order of integration:

    

    b) Evaluate the triple integral   

    Answer:

    (a) Given region of integration

             0

    it is a circle of radius 1

    we will introduce a vertical strip which will vary from

    order to change the order into integration

    

    

    

    

    = 2

    (b)   =

                     = 

                     = 

                     = 

                    = 

                    = 

                    = 

19. 7. a) Find a unit vector normal to the surface x²+y²+z²= 9 at the point (2, -1, 2) .

    b) If u = x2+y2+z2 & Show that Ñ.  = 5u

    Answer:

    (a) f(x,y,z) = x²+y²+z² = 9

    =2x

     = 2y

     = 2z

                      Vector =

         A point (2,-1,2)

    = 

    =

     Unit vector normal to it =      

    

    (b) u= x²+y²+z²

    

    (by identity)

    

    )

             =

                    [ ]

21. 8. a) If   evaluate,  where C is the curve in the xy-plane y = 2x²
    from (0,0) to (1,2).

    (b) Compute  , where   and S is the triangular surface with vertices (2, 0,0), (0, 2, 0) and (0, 0, 4).

    Answer:

    (a)    where

                  y =

       and  

    

    

     

    (b)   

    Equation of given plane x/2+y/z+z/4=1

    

    

    

    Let R be orthogonal projection of x+y +z/2=1in XoY plane i.e. z=0 given by x+y=1

    Therefore R=0{(x.y):0≤ y≤ 1-x;0≤ x≤ 1}

    =x +yx

    =(x )
    
    ds =

                                     [Put x=2,y=2,z=neglected ]

22. 9. State Gauss Divergence theorem and verify it for    taken over
    the cube bounded by x = 0, x = 1, y = 0, y = 1, z = 0, z = 1.

    Answer:

    Surface contains six faces

     (i) OABC faces Z = 0,

     .

    

    (ii) On face DEFG Z = 1,

    

    (iii) On face OAFG y = 0,

    

    (iv) On face DEBC y = 0,

    

    (v) On face ABEF x = 1,

    

    (vi) On face OCDG x = 0,

    

    

    Gauss Divergence theorem

    If   be a vector point function having continuous first partial derivative in reason v bounded by surface (s).

    Then