Anna university old question papers for EEE

Hi buddy I am doing my graduation in Electrical & Electronics Engineering (EEE) from Anna university, so this time I need old question paper for prepration of its exam, so from where can I collect B.E Electrical & Electronics Engineering (EEE) old exam paper of electrical machines 1 paper for this university?

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I am doing eee 5th sem, my sem s near but i couldn't find proper question bank since we are under coimbatore anna univ so please help me.

hi i am doing my BE -EEE in sasurie college of engg so i need previous and all 7th semester question papers of anna university coimbatore immediatly

here I am giving you old question paper for Electrical & Electronics Engineering (EEE) course offered by Anna university with it so you can get it easily..

some questions are given below :
NUMERICAL METHIODS

Unit I : Solution of equations and eigen value problems
Part A

1. If g(x) is continuous in [a,b] then under what condition the iterative method x = g(x) has unique solution in [a,b].

2. Find inverse of A = 7231 by Gauss – Jordan method.

3. Why Gauss Seidel iteration is a method of successive corrections.

4. Compare Gauss Jacobi and Gauss Siedel methods for solving linear system of the form AX = B.

5. State the conditions for convergence of Gauss Siedel method for solving a system of equations.

6. Compare Gaussian elimination method and Gauss-Jordan method.

7. What type of eigen value can be obtained using power method.

8. Find the dominant eigen value of A = 4321 by power method.

9. How is the numerically smallest eigen value of A obtained.

10. State two difference between direct and iterative methods for solving system of equations.

Part B
1. Find all the eigen values of the matrix 210121012 by power method (Apply only 3 iterations).

2. Use Newton’s backward difference formula to construct an interpolating polynomial of degree 3 for the data: f( - 0.75) = - 0.0718125, f( - 0.5) = - 0.02475, f( - 0.25) = - 0.3349375 and f(0) = 1.101. Hence find f (-31).

6. Solve the system of equations using Gauss Seidel iterative methods. 20x – y – 2z = 17, 3x + 20y – z = -18, 2x – 3y +20z = 25.

7.Find the largest eigen values and its corresponding vector of the matrix 1041423131 by power method.

8. Using Gauss- Jordan obtain the inverse of the matrix 531112322

9. Using Gauss Seidel method solve the system of equations starting with the values x = 1 , y = -2 and z = 3, x + 3y + 5z = 173.61, x – 27y + 2z = 71.31, 41x – 2y + 3z = 65.46

10. Solve the following equations by Jacobi’s iteration method x + y + z = 9, 2x – 3y + 4z = 13, 3x + 4y + 5z = 40.

Unit II : Interpolation and Approxiamtion
Part A
1. Construct a linear interpolating polynomial given the points (x0,y0) and (x1,y1).

2. Obtain the interpolation quadratic polynomial for the given data by using Newton’s forward difference formula. X : 0 2 4 6 Y : -3 5 21 45

3. Obtain the divided difference table for the following data. X : -1 0 2 3 Y : -8 3 1 12

4. Find the polynomial which takes the following values. X : 0 1 2 Y : 1 2 1

5. Define forward, backward, central differences and divided differences.

6. Evaluate 10(1-x) (1-2x) (1-3x)--------(1-10x), by taking h=1.

7. Show that the divided difference operator is linear.

8. State the order of convergence of cubic spline.

9. What are the natural or free conditions in cubic spline.

10. Find the cubic spline for the following data X : 0 2 4 6 Y : 1 9 21 41

11. State the properties of divided differences.

12. Show that abcdabcd1)1(3.

13. Find the divided differences of f(x) = x3 + x + 2 for the arguments 1,3,6,11.

14. State Newton’s forward and backward interpolating formula.

15. Using Lagranges find y at x = 2 for the following X : 0 1 3 4 5 Y : 0 1 81 256 625

Part B
1. Using Lagranges interpolation formula find y(10) given that y(5) = 12, y(6) = 13, y(9) = 14 and y(11) = 16.

2. Find the missing term in the following table x : 0 1 2 3 4 y : 1 3 9 - 81

3. From the data given below find the number of students whose weight is between 60 to 70. Wt (x) : 0-40 40-60 60-80 80-100 100-120

No of students : 250 120 100 70 50

4. From the following table find y(1.5) and y’(1) using cubic spline. X : 1 2 3 Y : -8 -1 18

5. Given sin 450 = 0.7071, sin 500 = 0.7660, sin 550 = 0.8192, sin 600 = 0.8660, find sin 520 using Newton’s forward interpolating formula.

6. Given log 10 654 = 2.8156, log 10 658 = 2.8182, log 10 659 = 2.8189, log 10 661 = 2.8202, find using Lagrange’s formula the value of log 10 656.

7. Fit a Lagrangian interpolating polynomial y = f(x) and find f(5) x : 1 3 4 6 y : -3 0 30 132

8. Find y(12) using Newton’ forward interpolation formula given x : 10 20 30 40 50 y : 46 66 81 93 101

9. Obtain the root of f(x) = 0 by Lagrange’s inverse interpolation given that f(30) = -30, f(34) = -13, f(38) = 3, f(42) = 18.

10. Fit a natural cubic spline for the following data x : 0 1 2 3 y : 1 4 0 -2

11. Derive Newton’s divided difference formula.

12. The following data are taken from the steam table: Temp0 c : 140 150 160 170 180 Pressure : 3.685 4.854 6.502 8.076 10.225 Find the pressure at temperature t = 1420 and at t = 1750

13. Find the sixth term of the sequence 8,12,19,29,42.

14. From the following table of half yearly premium for policies maturing at different ages, estimate the premium for policies maturing at the age of 46. Age x : 45 50 55 60 65 Premium y : 114.84 96.16 83.32 74.48 68.48

15. Form the divided difference table for the following data x : -2 0 3 5 7 8 y : -792 108 -72 48 -144 -252

Unit III Differentiation and Integration
Part A
1. What the errors in Trapezoidal and Simpson’s rule.

2. Write Simpson’s 3/8 rule assuming 3n intervals.

3. Evaluate 1141xdx using Gaussian quadrature with two points.

4. In Numerical integration what should be the number of intervals to apply Trapezoidal, Simpson’s 1/3 and Simpson’s 3/8.

5. Evaluate 11421xdxx using Gaussian three point quadrature formula.

6. State two point Gaussian quadratue formula to evaluate 11)(dxxf.

7. Using Newton backward difference write the formula for first and second order derivatives at the end value x = x0 upto fourth order.

8. Write down the expression for dxdy and 22dxyd at x = x0 using Newtons forward difference formula.

9. State Simpson’s 1/3 and Simpson’s 3/8 formula.

10. Using trapezoidal rule evaluate 0sinxdx by dividing into six equal parts.

Part B
1. Using Newton’s backward difference formula construct an interpolating polynomial of degree three and hence find f(-1/3) given f(-0.75) = - 0.07181250, f(-0.5) = - 0.024750, f(-0.25) = 0.33493750, f(0) = 1.10100.

2. Evaluate yxdxdy1 by Simpson’s 1/3 rule with yx= 0.5 where 0
3. Evaluate I = 2121yxdydx by using Trapezoidal rule, rule taking h= 0.5 and h=0.25. Hence the value of the above integration by Romberg’s method.

4. From the following data find y’(6) X : 0 2 3 4 7 9 Y: 4 26 58 112 466 922

5. Evaluate 212122yxdydx numerically with h= 0.2 along x-direction and k = 0.25 along y direction.

6. Find the value of sec (31) from the following data )(degree: 31 32 33 34 Tan : 0.6008 0.6249 0.6494 0.6745

7. Find the value of x for which f(x) is maxima in the range of x given the following table, find also maximum value of f(x). X: 9 10 11 12 13 14 Y : 1330 1340 1320 1250 1120 930

8. The following data gives the velocity of a particle for 20 seconds at an interval of five seconds. Find initial acceleration using the data given below Time(secs) : 0 5 10 15 20 Velocity(m/sec): 0 3 14 69 228

9. Evaluate 7321xdx using Gaussian quadrature with 3 points.

10. For a given data find dx
dy
and
2
2
dx
y d
at x = 1.1 X : 1.0 1.1 1.2 1.3 1.4 1.5 1.6 Y: 7.989 8.403 8.781 9.129 9.451 9.750 10.031

NUMERICAL METHODS UNIT – IV : INITIAL VALUE PROBLEMS FOR ORDINARY DIFFERENTIAL EQUATIONS
PART – A
1. By Taylor series, find y(1.1) given y = x + y, y(1) = 0.

2. Find the Taylor series upto x3 term satisfying 1)0(,12yxyy.

3. Using Taylor series method find y at x = 0.1 if 1)0(,12yyxdxdy.

4. State Adams – Bashforth predictor and corrector formula.

5. What is the condition to apply Adams – Bashforth method ?

6. Using modified Euler’s method, find )1.0(y if 1)0(,22yxydxdy.

7. Write down the formula to solve 2nd order differential equation using Runge-Kutta method of 4th order.

8. In the derivation of fourth order Runge-Kutta formula, why is it called fourth order.

9. Compare R.K. method and Predictor methods for the solution of Initial value problems.

10. Using Euler’s method find the solution of the IVP 2)0(),log(yyxdxdy at2.0x taking 2.0h.

PART-B

11. The differential equation 2xydxdy is satisfied by1.7379 y(0.6) 1.46820, y(0.4) 1.12186,y(0.2) 1, y(0).Compute the value of y(0.8) by Milne’s predictor - corrector formula.

12. By means of Taylor’s series expension, find y at x = 0.1,and x = 0.2 correct to three decimals places, given xeydxdy32 , y(0) = 0.

13. Given ,0)0(,1)0(,0yyyyxy find the value of y(0.1) by using R.K.method of fourth order.

14. Using Taylor;s series method find y at x = 0.1, if 12yxdxdy, y(0)=1.

15. Given )1(2yxdxdy, y(1) = 1, y(1.1) = 1.233, y(1.2) = 1.548, y(1.3)=1.979, evaluate y(1.4) by Adam’s- Bashforth method.

16. Using Runge-Kutta method of 4th order, solve 2222xyxydxdy with y(0)=1 at x=0.2.

17. Using Milne’s method to find y(1.4) given that 0252yyxgiven that 0143.1)3.4(,0097.1)2.4(,0049.1)1.4(,1)4(yyyy.

18. Given 823516.3)6.0(,990578.2)4.0(,443214.2)2.0(,2)0(,3yy yyyxdxdy find y(0.8)by Milne’s predictor-corrector method taking h = 0.2.

19. Using R.K.Method of order 4, find y for x = 0.1, 0.2, 0.3 given that 1)0(,2yyxydxdy also find the solution at x = 0.4 using Milne’s method.

20. Solve 2xydxdy, y(0) = 1. Find y(0.1) and y(0.2) by R.K.Method of order 4. Find y(0.3) by Euler’s method. Find y(0.4) by Milne’s predictor-corrector method.

21. Solve 0)1(1.02yyyy subject to 1 (0)y 0, y(0) using fourth order Runge-Kutta Method. Find y(0.2)and )2.0(y. Using step size 2.0x.

22. Using 4th order RK Method compute y for x = 0.1 given 21xxyy given y(0) = 1 taking h=0.1.

23. Determine the value of y(0.4) using Milne’s method given 1)0(,2yyxydxdy, use Taylors series to get the value of y at x = 0.1, Euler’s method for y at x = 0.2 and RK 4th order method for y at x=0.3.

24. Consider the IVP 5.0)0(,12yxydxdy (i) Using the modified Euler method, find y(0.2). (ii) Using R.K.Method of order 4, find y(0.4) and y(0.6). (iii) Using Adam- Bashforth predictor corrector method, find y(0.8).

25. Consider the second order IVP int,222Seyyytwith y(0) = -0.4 and y’(0)=-0.6. (i) Using Taylor series approximation, find y(0.1). (ii) Using R.K.Method of order 4, find y(0.2).


NUMERICAL METHODS QUESTION BANK UNIT-5
PART-A

1. Define the local truncation error. 2

. Write down the standard five point formula used in solving laplace equation Uxx+ Uyy= 0 at the point (yjxi,).

3. Derive Crank-Niclson scheme.

4. State Bender Schmidt’s explicit formula for solving heat flow equations

5. Classify x2fxx+ (1-y2) fyy= 0

6. What is the truncation error of the central difference approximation of y'(x)?

7. What is the error for solving Laplace and Poissson’s equation by finite difference method.

8. Obtain the finite difference scheme fore the difference equations 222dxyd + y = 5.

9. Write dowm the implicit formula to solve the one dimensional heat equation.

10. Define the diagonal five point formula .

1. Solve the equqtion Ut= Uxx subject to condition u(x,0) = sinx; 01x,u(0,t) = u(1,t) =0 using Crank- Nicholson method taking h = 1/3 k = 1/36(do on time step)

2. Solve U xx + U yy = 0 for the following square mesh with boundary values 1 2 1 4 2 5 4 5

3. Solve Uxx= Utt with boundary condition u(0,t) = u(4,t) and the initial condition ut(x,0) = 0 , u(x,0)=x(4-x) taking h =1, k = ½ (solve one period)

4. Solve xyII+ y = 0 , y(1) =1,y(2) = 2, h = 0.25 by finite difference method.

5. Solve the boundary value problem xy II -2y + x = 0, subject to y(2) = 0 =y(3).Find y(2.25),y(2.5),y(2.75).

6 . Solve the vibration problem 224xyty subject to the boundary conditions y(0,t)=0,y(8,0)=0 and y(x,0)=21x(8-x).Find y at x=0,2,4,6.Choosing x = 2, t = 2

up compute to 4 time steps.

7. Solve 2u = -4(x + y) in the region given 0,4x 0.4y With all boundaries kept at 00 and choosing x = y = 1.Start with zero vector and do 4 Gauss- Seidal iteration. 0 0 0 0 0 0 0 0 0 0

8. Solve uxx+ uyy= 0 over the square mesh of side 4 units, satisfying the following conditions . u(x,0) =3x for 04x u(x, 4) = x2 for 04x u(0,y) = 0, for 04y u(4,y) = 12+y for 04y

9. Solve tuxu222 = 0, given that u(0,t)=0,u(4.t)=0.u(x,0)=x(4-x).Assume h=1.Find the values of u upto t =5.

10. Solve ytt= 4yxx subject to the condition y(0,t) =0, y(2,t)=o, y(x,o) = x(2-x), 0)0,(xty. Do 4steps and find the values upto 2 decimal accuracy.

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