differential equations. 1.solve; = (1 + x) + y(1 + x) = (1 + x)(1 + y) integrating which is the...
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![Page 1: Differential Equations. 1.Solve; = (1 + x) + y(1 + x) = (1 + x)(1 + y) Integrating Which is the required solution](https://reader037.vdocuments.us/reader037/viewer/2022103101/56649c7e5503460f9493323f/html5/thumbnails/1.jpg)
Differential Equations
PREPARED BY:R.RAJENDRAN. M.A., M. Sc., M. Ed.,K.C.SANKARALINGA NADAR HR. SEC. SCHOOL,CHENNAI-21
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1.Solve;
= (1 + x) + y(1 + x)
= (1 + x)(1 + y)
xyyxdxdy 1
xyyxdxdy 1
dxxy
dy)1(
1
Integrating
dxxy
dy)1(
1
cx
xy 2
)1log(2
Which is the required solution.
![Page 3: Differential Equations. 1.Solve; = (1 + x) + y(1 + x) = (1 + x)(1 + y) Integrating Which is the required solution](https://reader037.vdocuments.us/reader037/viewer/2022103101/56649c7e5503460f9493323f/html5/thumbnails/3.jpg)
2.Solve;
Put x + y = z
22)( adxdy
yx 22)( a
dxdy
yx
dxdz
dxdy 1
The given eqn becomes
22 1 adxdz
z
1dxdz
dxdy
2
2
1za
dxdz
2
22
2
2
1z
zaza
dxdz
dxdzaz
z 22
2
dxdzaz
aaz
22
222
dxdzaz
a
22
2
1
Integrating
![Page 4: Differential Equations. 1.Solve; = (1 + x) + y(1 + x) = (1 + x)(1 + y) Integrating Which is the required solution](https://reader037.vdocuments.us/reader037/viewer/2022103101/56649c7e5503460f9493323f/html5/thumbnails/4.jpg)
dxdzaz
a22
2
1
dxdzaz
adz 222 1
cxa
z
aaz
12 tan
1
cxa
yxayx
1tan
ca
yxay
1tan
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3. Solve 3ex tan y dx + (1 + ex) sec 2y dy = 0
Given equation is
3ex tan y dx + (1 + ex) sec2y dy = 0
3ex tan y dx = – (1 + ex) sec2y dy
dyyy
dxe
ex
x
tansec
13 2
Integrating
dyyy
dxe
ex
x
tansec
13 2
3 log(1+ex) = – log(tan y) + log c
log(1+ex)3 + log(tan y) = log c
log(1+ex)3(tan y) = log c
(1+ex)3(tan y) = c
Which is the required solution
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4. Solve (x2 – y)dx + (y2 – x)dy = 0, if it passes through the origin.
The given equation is
(x2 – y)dx + (y2 – x)dy = 0
x2 dx – ydx + y2 dy – xdy = 0
x2 dx + y2 dy = ydx + xdy
Integrating,
xdyydxdyydxx 22
)(22 xyddyydxx
cxyyx 33
33
Since it passes through the origin,
0 + 0 = 0 + c
c = 0
The required solution is
xyyx 33
33
xyyx 333
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5. Solve: xxydxdy
cos2cot
xxydxdy
cos2cot
It is a linear diff eqn with
P = cot x, Q = 2cosx
dxP
eIF
dxx
e cot
dxx
x
e
sin
cos
xe sinlog
xsin
The solution is
cdxQy I.F I.F
cdxxxy sincos2sin x
cdxxy 2sinsin x
cx
y 2
cossin x
cx
y 2
cossin x
![Page 8: Differential Equations. 1.Solve; = (1 + x) + y(1 + x) = (1 + x)(1 + y) Integrating Which is the required solution](https://reader037.vdocuments.us/reader037/viewer/2022103101/56649c7e5503460f9493323f/html5/thumbnails/8.jpg)
6. Solve: 22 12)1( xxxydxdy
x
It is a linear diff eqn with
dxP
eIF
dx
x
x
e
1
22
The solution is
cdxQy I.F I.F
cdxxx
xx
y 1
1
111
222
22 12)1( xxxydxdy
x
2
2
2 11
12
xxx
yxx
dxdy
221
,1
2
x
xQ
xx
P
dxx
x
e
1
22
)1log( 2xe 211x
cdxxx
xy
)1(11
2/322
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cdxxx
xy
)1(11
2/322
cdx
xx
xy
)1(2
21
11
2/322
cx
xy
123
)1(2
11
1
12
32
2
cx
xy
21
)1(2
11
1
2
12
2
cxx
y
22
1
11
1
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7. Solve: (1 + y2)dx = (tan–1 y – x )dy
The given equation
(1+y2)dx = (tan–1y – x)dy can be written as
2
1
1tan
yxy
dydx
22
1
11tan
yx
yy
dydx
2
1
2 1tan
1 yy
yx
dydx
It is a linear diff eqn in x with
2
1
2 1tan
,1
1y
yQ
yP
The solution is
cdyQ ) (I.F (I.F)x
cdyy
yx yy e
1
tane
1-1- tan2
1tan
dyP
eIF
dy
ye
1
12
ye1tan
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)1.........( e1
tane
1-1- tan2
1tan
cdyy
yx yy
Put u = tan – 1 y
211ydy
du
dyy
du 211
Eqn (1) becomes
cdux uy uee -1tan
cduuex uuy ee -1tan
ceuex uuy -1tane
ceyex yyy 11-1 tantan1tan tane
cyex yy
)1(tane 1tantan 1-1
It is the required soln.
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8. Solve (D2 – 13D + 12)y = e –2x
The given equation is(D2 – 13D + 12)y = e –2x
The characteristic equation is p2 – 13p + 12 = 0(p – 12)(p – 1) = 0 p = 1, 12The complementary function isCF = A ex + B e 12x
Particular integral is
xeDD
PI 22 1213
1
xe 22 12)2(13)2(
1
xe 2
122641
xe 2
421
The general solution is
y = CF + PIxxx eBeAey 212
421
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9. Solve (D2 + 6D + 8)y = e –2x
The given equation is(D2 + 6D + 8)y = e –2x
The characteristic equation is p2 + 6p + 8 = 0(p + 2)(p + 4) = 0 p = – 2, – 4The complementary function isCF = A e–2x + B e– 4x
Particular integral is
xeDD
PI 22 86
1
xeDD
2
)2)(4(1
xeD
2
)2)(42(1
xx ex
xe 22
221
The general solution is
y = CF + PIxxx e
xBeAey 242
2
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10. Solve (D2 – 4D + 13)y = e –3x
The given equation is
(D2 – 4D + 13)y = e –3x
The characteristic equation is
p2 – 4p + 13 = 0
xeDD
PI 32 134
1
xe 32 13)3(4)3(
1
The general solution is
y = CF + PI
xx exBxAey 32
341
)3sin3cos(
12
1314)4()4( 2
p
252164 p
2364
ii
322
64
CF = e2x(Acos3x + B sin3x)
34131291 3
3x
x ee
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11. Solve (D2 – 4)y = sin2x
The given equation is(D2 – 4)y = sin2xThe characteristic equation is p2 – 4 = 0(p – 2)(p + 2) = 0 p = –2, 2The complementary function isCF = A e –2x + B e 2x
Particular integral is
xD
PI 2sin4
12
x2sin)42(
12
82sin
x
The general solution is
y = CF + PI
xBeAey xx 2sin4122
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12. Solve (D2 – 2D – 3)y = sinx cosx
The given equation is(D2 – 2D – 3)y = sinx cosxThe characteristic equation is p2 – 2p – 3 = 0(p – 3)(p + 1) = 0 p = –1, 3The complementary function isCF = A e –x + B e 3x
Particular integral is
32cossin
2
DDxx
PI
322sin
21
2
DDx
)322(22sin
2
Dx
)72(22sin
D
x
)72)(72(22sin)72(
DD
xD
)494(22sin)72(
2 D
xD
![Page 17: Differential Equations. 1.Solve; = (1 + x) + y(1 + x) = (1 + x)(1 + y) Integrating Which is the required solution](https://reader037.vdocuments.us/reader037/viewer/2022103101/56649c7e5503460f9493323f/html5/thumbnails/17.jpg)
xDD
2sin)494(2
)72(2
)49)2(4(22sin7)2(sin2
2 xxD
)4916(22sin72cos4
xx
)2sin72cos4(130
1xx
The general solution is
y = CF + PI
)2sin72cos4(130
13 xxBeAey xx
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13. Solve (D2 + 14D + 49)y = e–7x + 4
The given equation is(D2 + 14D + 49)y = e–7x + 4The characteristic equation is p2 + 14p + 49 = 0(p + 7)(p + 7) = 0 p = – 7, – 7 CF = (Ax + B)e–7x
Particular integral is
49144
2
7
DDe
PIx
2
0
2
7
)7(4
)7(
De
De xx
2
072
)70(4
2
xx eex
494
2
72
xex
The general solution is
y = CF + PI
494
2)(
727
xx ex
eBAxy
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14. Solve (D2 – 13D + 12)y = e–2x + 5ex
The given equation is(D2 – 13D + 12)y = e–2x + 5ex
The characteristic equation is p2 – 13p + 12 = 0(p – 12)(p – 1) = 0 p = 12, 1 CF = A e12x + B ex
Particular integral is
12135
2
2
DDee
PIxx
)1)(12(5
12132
2
DDe
DDe xx
)1)(121(
5
12264
2
D
ee xx
11
5
42
2 xx xee
The general solution is
y = CF + PI
11
5
42
212
xxxx xee
BeAey
11
5
42
2
xx xee
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15. Solve (D2 + 4D + 13)y = cos3x
The given equation is
(D2 + 4D + 13)y = cos 3x
The characteristic equation is
p2 + 4p + 13 = 0x
DDPI 3cos
1341
2
CF = e–2x(Acos3x + Bsin3x)Particular integral is
12131444 2
p
252164 p
2364 p
ii
p 322
64
xD
3cos1343
12
xD
3cos44
1
xDD
D3cos
)1)(1(4)1(
![Page 21: Differential Equations. 1.Solve; = (1 + x) + y(1 + x) = (1 + x)(1 + y) Integrating Which is the required solution](https://reader037.vdocuments.us/reader037/viewer/2022103101/56649c7e5503460f9493323f/html5/thumbnails/21.jpg)
xDD
3cos)1(4
)1(2
)13(43cos)3(cos
2 xxD
403cos3sin3
xx
)3cos3sin3(401
xx
The general solution is
y = CF + PI
)3cos3sin3(401
)3sin3cos(2 xxxBxAey x
![Page 22: Differential Equations. 1.Solve; = (1 + x) + y(1 + x) = (1 + x)(1 + y) Integrating Which is the required solution](https://reader037.vdocuments.us/reader037/viewer/2022103101/56649c7e5503460f9493323f/html5/thumbnails/22.jpg)
16. Solve: (D2 – 1)y = cos 2x – 2sin 2x
The given equation is
(D2 – 1)y = cos 2x – 2sin 2x
The characteristic equation is
p2 – 1 = 0
(p – 1)(p + 1) = 0
p = 1, – 1
CF = A ex + B e–x
The particular integral is
)2sin22(cos1
12 xx
DPI
12sin
21
2cos22
D
xD
x
122sin
212
2cos22
xx
52sin
252cos
xx
xx 2sin52
2cos51
The general solution is
y = CF + PI
)2cos2sin2(51
xxBeAey xx
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17. Solve (D2 – 4D + 1)y = x2
The given equation is
(D2 – 4D + 1)y = x2
The characteristic equation is
p2 – 4p + 1 = 0
22 14
1x
DDPI
Particular integral is
12
114)4()4( 2
p
24164
2124
322
324
xx BeAeCF )32()32(
= {1 + (D2 – 4D)}–1 x2 = {1 – (D2 – 4D) + (D2 – 4D)2 – } x2
= {1 – D2 + 4D + 16D2} x2
= x2 – 2 + 4 (2x) + 16(2)= x2 + 30 + 8xThe general solution is y = CF + PI
3082)32()32( xxBeAey xx
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18. Solve (D2 + 3D – 4)y = x2
The given equation is
(D2 + 3D – 4)y = x2
The characteristic equation is
p2 + 3p – 4 = 0
(p + 4)(p – 1) = 0
p = 1, – 4
CF = Aex + Be–4x
The particular integral is
22 43
1x
DDPI
2
2
43
14
1x
DDPI
2
12
43
14
1x
DD
2
222
..4
34
31
41
xDDDD
222
..16
94
31
41
xDDD
22
1612
1613
14
1x
DD
![Page 25: Differential Equations. 1.Solve; = (1 + x) + y(1 + x) = (1 + x)(1 + y) Integrating Which is the required solution](https://reader037.vdocuments.us/reader037/viewer/2022103101/56649c7e5503460f9493323f/html5/thumbnails/25.jpg)
)2(
1612
)2(1613
41 2 xx
xx
23
813
41 2
813
23
41 2 xx
The general solution is
y = CF + PI
813
23
41 24 xxBeAey xx
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19. In a chemical reaction the rate of conversion of a substance at time t is proportional to the quantity of the substance still untransformed at that instant. At the end of one hour, 60grams remain and at the end of 4 hours 21 grams. How many grams of the first substance was there initially?
Let x grams of the substance remain after t hours.
xdtdx xk
dtdx
Where k is constant of proportionality
dtkx
dx Integrating
dtkx
dx
log x = – k t + c1
x = c e– k t …….(1)
When t = 1, x = 60
60 = c e–k ……….(2)
1cktex
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x = c e– k t …….(1)
When t = 4, x = 21
21 = c e–4k ……….(3)
When t = 0, x = c
From (2) e – k = 60/c
Sub in (3) we get
3
446060
21cc
c
43
2160c
taking log
3log c = 4log60 – log21
= 4(1.7782) – 1.3222
= 7.1128 – 1.3222
= 5.7906
log c = 5.7906/3 = 1.9302
c = antilog 1.9302
= 85.15 85
Hence initially there was 85gms of the substance.
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20. For a postmortem report, a doctor requires to know approximately the time of death of the deceased. He records the first temperature at 10.00am to be 93.4F. After 2 hours he finds the temperature to be 91.4F. If the room temperature is 72F, estimate the time of death. (Assume that the normal temperature of a human body to be 98.6F). Given
Let T be the temperature of the body at any time t
The temperature difference is T – 72
By Newton’s law of cooling,
00945.04.216.26
log and 0426.04.214.19
log ee
72 TdtdT
)72( TkdtdT
Where k is constant of proportionality
![Page 29: Differential Equations. 1.Solve; = (1 + x) + y(1 + x) = (1 + x)(1 + y) Integrating Which is the required solution](https://reader037.vdocuments.us/reader037/viewer/2022103101/56649c7e5503460f9493323f/html5/thumbnails/29.jpg)
dtkT
dT
72
Integrating
dtkT
dT
72
log (T – 72) = – k t + c1
T = 72 + c e– k t …….(1)
Initially, t = 0, T = 93.4F
93.4F = 72 + c e0
c = 93.4 – 72 = 21.4F
T = 72 + 21.4 e–k t ……(2)
172 ckteT
When, t = 120, T = 91.4F
91.4F = 72 + 21.4 e– 120k
21.4e– 120k = 91.4 – 72
21.4e– 120k = 19.4
4.214.19120 ke
4.214.19
log120 k
4.214.19
log120
1k
41055.3)0426.0(120
1 k
![Page 30: Differential Equations. 1.Solve; = (1 + x) + y(1 + x) = (1 + x)(1 + y) Integrating Which is the required solution](https://reader037.vdocuments.us/reader037/viewer/2022103101/56649c7e5503460f9493323f/html5/thumbnails/30.jpg)
When T = 98.6F, t = t1
98.6F = 72 + 21.4 e–k t1
21.4 e–k t1 = 98.6 – 72 = 26.6
4.216.26
1 kte
4.216.26
log1 ekt
4.21
6.26log
11 ekt
)0945.0(1055.3
141
t
)0945.0(55.3
104
1
t
min26655.3
9451
t
4hours 26min before the first recorded temperature
The approximate time of death = 10 – 4:26 = 5:34am
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21. The number of bacteria in a yeast culture grows at a rate which is proportional to the number present. If the population of a colony of yeast bacteria triples in 1hour. Show that the number of bacteria at the end of five hours will be 35 times of the population at initial time.
Let x be the number of bacteria present in the yeast culture at any time t
xdtdx xk
dtdx
Where k is constant of proportionality
dtkx
dx Integrating
dtkx
dx
log x = k t + c1
x = c e k t …….(1)
When t = 0, x = x0
x0 = c e0
c = x0
1cktex
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Sub in eqn (1) we get
x = x0 e k t………(2)
Given x = 3x0, when t = 1
3x0 = x0 ek
e k = 3……..(3)
When t = 5, let x = x1
x1 = x0 e 5k
= x0 (ek)5 = x0 35
= 35 times of the population at initial time
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22. The sum of Rs. 1000 is compounded continuously, the nominal rate of interest being four percent per annum. In how many years will the amount be twice the original principal? (loge2 = 0.6931)
Let x be the principal
xdtdx
of %4
xdtdx
04.0
dtx
dx 04.0
Integrating
dtx
dx 04.0
log x = 0.04 t + c1
x = c e 0.04 t …….(1)
When t = 0, x = 1000
1000 = c e0
c = 1000
x = 1000e 0.04t……..(2)
104.0 ctex
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x = 1000 e 0.04 t …….(2)
When x = 2000, t = ?
2000 = 1000 e0.04t
e0.04t = 2
0.04t = loge2
0.04t = 0.6931
1732.1704.0
6931.0 t
In 17 years the amount will be twice the original principal
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23. Radium disappears at a rate proportional to the amount present. If 5% of the original amount disappears in 50years, how much will remain at the end of 100years. (Take A0 as the initial amount.)
Let A be the amount of radium disappears at any time t.
AdtdA Ak
dtdA
Where k is constant of proportionality
dtkA
dA Integrating
dtkA
dA
log A = –k t + c1
1ckteA ktceA
Initially, t = 0 and A = A0
A0 = c e0 c = A0
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kteAA 0
When t = 50years, A = 95% of A0 = 0.95A0
0.95A0 = A0 e –50k
e – 50k = 0.95
When t = 100 years, A = A1
A1 = A0 e – 100k = A0 (e – 50k)2
= A0 (0.95)2 = 0.9025A0
Amount of radium at the end of 100years = 0.9025A0
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