Find f′ 5 from the following table: Sol.. So we use Newton’s divide difference formula... Here, the arguments are not equally spaced and therefore we shall apply Newton’s divided differ
Trang 1Here, x n 2.04,h 0.02u x x n du 1atx 2.03
−
∴ u=2.03 2.040.02− = −0.010.02= −12
Then, by Newton’s backward formula, we have
Differentiating w.r.t x, we have
( ) 1 2 1 2 3 2 6 2 3 4 3 18 2 22 6 4
h
( )
2
y
24
+
=50 0.0090 0.000008 0.000017[− + + ]= −0.44875 Ans
Again differentiating equation (2) w.r.t x,
2
h
2
2
(0.02)
y
=2500[−0.0002 0.0001 0.00012− − ]
y′′(2.03)= −1.05. Ans
Example 9 Find f′( )5 from the following table:
Sol Here the arguments are not equally spaced So we use Newton’s divide difference formula
Trang 2Difference table
x f x( ) ∆f x( ) ∆2f x( ) ∆3f x( ) ∆4f x( )
1
3
3
1 144
−
16
−
6 3
Newton’s divided difference formula is given by:
2
f x = f x + −x x ∆f x + −x x x x− ∆ f x + −x x x x− x x−
f x x x x x x x x x f x
Differentiating (1) w.r.t x, we get
f x′ = ∆f x + x x− −x ∆ f x + x x− x x− + −x x x x− + −x x x x− ∆ f x +
At x = 5
1 (5) 1 (10 1 2) [(5 2)(5 4) ((5 1)(5 4) (5 1)(5 2)] 0
3
[(5 2)(5 4)(5 8) (5 1)(5 4)(5 8) (5 1)(5 2)(5 8) (5 1)(5 2)(5 4)] 1
144
−
1 7 1 1 [ 9 12 36 12] 1 7 45
Hence f′(5) 3.6458.= Ans
Example 10 Find f′′′(5) from the data given below:
Sol Here, the arguments are not equally spaced and therefore we shall apply Newton’s divided
difference formula
2
f x = f x + −x x ∆f x + −x x x x− ∆ f x + −x x x x− x x−
f x x x x x x x x x f x
Trang 3x f (x) ∆f x( ) ∆ 2f x( ) ∆ 3f x( ) ∆ 4f x( ) ∆ 5f x( ) ∆ 6f x( )
644
2119372
Substituting values in eqn (1), we get
f x( )=57 (+ −x 2)(644) (+ −x 2)(x−4)(1765) (+ −x 2)(x−4)(x−9)(556)
+ −(x 2)(x−4)(x−9)(x−13)(45) (+ −x 2)(x−4)(x−9)(x−13)(x−16)(1)
=57 644(+ x− +2) 1765(x2−6x+ +8) 556(x3−15x2+62x−72)
+45(x4−28x3+257x2−878x+936)+x5−44x4+705x3−4990x2
+14984x−14976
f x′ = + x− + x − x+ + x − x + x−
+5x4−176x3+2115x2−9980x+14984
2
f′′′x = + x− + x − x+ =60x2+24x+6
Where x = 5;
2
f′′′ = + + = Ans
Example 11 Find f′ (4) from the following data:
( )
Sol Though this problem can be solved by Newton’s divided difference formula, we are giving here, as an alternative, Lagrange’s method Lagrange’s polynomial, in this case, is given by
Trang 4e j e j
( 0)( 2)( 1)(125) ( 0)( 2)( 5)(1)
x− x− x− x− x− x−
4( 3 6 2 5 ) 25( 3 3 2 2 ) 1( 3 7 2 10 ) 3
∴ f x′( ) 3= x2
When x = 4, f′(4) = 3(4)2 = 48 Ans
Example 12 Find f′(0.6)and f′′(0.6)from the following table:
( )
Sol Here, the derivatives are required at the central point x = 0.6, so we use Stirling’s
formula
Difference table
u x f (x) ∆f x( ) ∆ 2f x( ) ∆ 3f x( ) ∆ 4f x( )
0.2138
0.3235
Here we have x0 0.6,h 0.1,u x x0 at x 0.6,u 0
h
−
Stirling’s formula is
( )
Differentiating (1) w.r.t x, we get
h
Trang 5e j e j
Using difference table, we have
∆ =y0 0.2468,∆y−1=0.2833, ∆2y−1=0.0365, ∆3y−1=0.0035,
∆3y−2=0.0037, ∆4y−2=0.0002,
0.2468 0.2833 1 0.0035 0.0037 1
=10[0.26505 0.0006]−
= f’(0.6) = 2.6445 Ans
Again differentiating (1), we get
2
h
2
12 (0.1)
=100[0.0365 0.000016]− Hence, f′′(0.6)=3.6484 Ans
Example 13 Find f′(93)from the following table:
( )
Sol Difference table
( )
f x
( )
f x
( )
f x
∆
–3.2
Here we have x0 =90,x=93,h=15
x x u h
Trang 6Now using Stirling’s formula
f x = =y y +u∆ + ∆ − + ∆ y− + − ∆ − + ∆ − + − ∆ y− +
Differentiating (1) w.r.t x, we get
h
Putting the values of x = 93, u = 0.2, h = 15 and
We get,
1.46
×
1 1.35 1.46 0.30065 0.1334 15
(93) 0.03627
Example 14 Find x for which y is maximum and find this value of y
Sol The Difference table is as follows:
1.2 0.9320
0.0316
0.0021 1.6 0.9996
Trang 7Let y0=0.9320 and a = 1.2
By Newton’s forward difference formula
0 0 2 0
2
u u
y=y + ∆ +u y − ∆ y +
0.9320 0.0316 ( 1)(–0.0097)
2
u u
= + + (Neglecting higher differences)
dy du=0.0316+ 2u2−1(–0.0097)
At a maximum,
dy 0
du=
2
∴ x=x0+hu=1.2 (0.1)(3.76) 1.576+ =
To find ymax,we use backward difference formula,
x = x n + hu
(1.576) ( 1) 2 ( 1)( 2) 3
0.9996 (0.24 0.0021) (–0.24)(1 – 0.24)(–0.0099)
2
=0.9999988 0.9999= nearly
∴ Maximum y = 0.9999 (Approximately) Ans
Example 15 From the following table, for what value of x, y is minimum Also find this value of y.
Sol Difference table
0.035
–0.026
Trang 8Now taking x0 = 3, we have y0 =0.205, ∆ =y0 0.035, ∆2y0= −0.016 and ∆3y0=0.
Therefore, Newton’s forward interpolation formula gives
0.205 (0.035) ( 1)( 0.016)
2
u u
(1)
Differentiating (1), w.r.t u, we get
0.035 2 1(–0.016)
2
du
−
For y to be minimum put dy 0
du=
⇒ 0.035 – 0.008(2u− =1) 0
⇒ u=2.6875
Therefore, x=x0+uh
= +3 2.6875 1 5.6875× =
Hence, y is minimum when x = 5.6875.
Putting u = 2.6875 in (1), we get the minimum value of y given by
0.205 2.6875 0.035 1(2.6875 1.6875)(–0.016)
2
= 0.2628 Ans
PROBLEM SET 6.1
1 Find f′(6) from the following table:
( )
x
[Ans –23]
2 Use the following data to find f ′(3):
( )
x
[Ans 1.8828]
3 Use the following data to find f ′(5):
( )
x
f x
[Ans 2097.69]
4 From the table, find dy
dx at x = 1, x = 3 and x = 6:
( )
x
f x
[Ans 0.3952, 0.3341, 0.2719]
Trang 95 Find f ′(5) and f ′′(5) from the following data:
( )
x
f x
6 Using Newton’s Divided Difference Formula, find f ′(10) from the following data:
( )
x
[Ans 232.869]
7 From the table below, for what value of x, y is minimum? Also find this value of y.
x
[Ans 5.6875, 0.2628]
8 A slider in a machine moves along a fixed straight rod Its distance x (in cm.) along the rod is given at various times t (in secs.)
t
x
Evaluate dx
dt at t = 0.1 and at t = 0.5 [Ans 32.44166 cm/sec.; −24.05833 cm/sec.]
9 A rod is rotating in a plane The following table gives the angle θ (radians) through which
the rod has turned for various values of the time t (seconds).
t
θ
Calculate the angular velocity and acceleration of the rod when t = 0.6 sec.
[Ans (i) 3.82 radians/sec (ii) 6.75 radians/sec2]
10 The table given below reveals the velocity ‘v’ of a body during the time ‘t’ specified Find its acceleration at t = 1.1.
t v
[Ans 44.92]
Trang 106.3 NUMERICAL INTEGRATION
Like numerical differentiation, we need to seek the help of numerical integration techniques in the following situations:
1 Functions do not possess closed from solutions Example:
2
– 0 ( )
x t
f x =C e∫ dt
2 Closed form solutions exist but these solutions are complex and difficult to use for calculations
3 Data for variables are available in the form of a table, but no mathematical relationship between them is known as is often the case with experimental data
Let y= f x( ) be a function, where y takes the values y0, y1, y2, y n for x = x0, x1, x2, x n We want to find the vaule of ( )
b
a
I=∫f x dx
Let the interval of integration (a, b) be divided into n equal subintervals of width h b a
n
−
= so that x0=a x, 1= +x0 h x, 2= +x0 2hT, ,x n= + =x0 nh b
∴ 0
0
nh
x b
+
Newton’s forward interpolation formula is given by
Where x x0
u h
−
=
∴ du 1dx dx hdu
h
∴ Equation (1) becomes,
0
n
I=h y + ∆ +u y − ∆ y + − − ∆ y + du
∫
2
up to( 1) terms
∴
0
2
n
x
x
This is called general quadrature formula