Question:
Answer:
Question 1: Find the explicit general solution of xdx – (y^2)dy=0.
Xdx – (y^2)dy = 0
Or, xdx = (y^2)dy
integrating both sides we get,
(x^2)/2 + C1 = (y^3)/3 + C2
Or, 3(x^2) + 3C1 – 2(y^3) – 2C2 = 0
Let, 3C1 – 2C2 = C’
Therefore,
3(x^2) – 2(y^3) + C’ = 0
Hence, this is the general solution of the equation.
Question 2: Find the explicit general solution of 2xyy’ – y^2 +x^2 = 0 (Homogeneous Substitution Method)
2xyy’ – y^2 + x^2 = 0
Or, dy/dx = (x^2 – y^2)
By the substitution method,
Let v = y/x
Therefore, y = vx
Or, dy/dx = v + x(dv/dx)
Therefore, by substituting the value we get,
v + x(dv/dx) = {x^2 – (v^2)(x^2)}/2vx^2
Or, dx/x = 2dv/((3v^2)-1)
Integrating both sides we get,
Logx + C1 = 1/3log ((3v^2)-1) + C2
Or, x^3= 3v^2 – 1 + C
Where C is the composite constant
Putting the value of v in the equation, we get,
x^3= {3(y^2)/(x^2)} – 1 + C
Question 3: Find the explicit general solution of xy’ + y + 4 =0.
a) Integrating Factor
xdy/dx + y + 4 = 0
Or, dy/dx + y/x = -4/x
By integrating factor method we get,
P = 1/x
Therefore the integrating factor = e^∫dx/x = e^log x = x
Therefore we are required to multiply on both the sides by the integrating factor, we get
(dy/dx + y/x)xdx = -(4/x)xdx
xy = -4x +c
y = c/x – 4“
b) Exact Equation Method
(y+4) + (x)y’= 0
Now by exact equation method we get
My(x,y) = 1
Nx(x,y) = 1
Fx(x,y) = y + 4
Fy(x,y) = x
Fx’(x,y) = y + h(y)
Fx”(x,y) = h’(y)
h’(y) = 0
h(y) = 0
y + 4 = c1/x
Question 4: Find the explicit general solution of y’ – 3y/x= (x^4) y^(1/3) using Bernoulli’s theorem
Let, a(x) = (-3/x)
f(x) = x^4
n=1/3
z= y^(1-n)
Therefore according to the Bernoulli’s theorem,
dz/dx=(1-n) a(x)y^(1-n) + (1-n)f(x)
or, dz/dx=(1-n) a(x)z + (1-n)f(x)
or, dz/dx = 2/3x^4 – 2z/x
or, dz/dx = (2/3)x^4 – 2z/x
Now approaching the problem with the integrating factor
The integrating factor = x^2
(dz/dx + 2z/x) x^2 = (2x^6)/3
Integrating both sides, we get
(x^2)z = (x^7)/21 + c
(x^2)(y^2/3) = (x^7)/21 + c
Question 5: Find the explicit general solution of y“= -2y` + 4t
Solution to question a
y” + 2y’ = 4t
let y’’ = a^2
therefore
a^2 + 2a = 0
0r a+2 = +-2
Therefore y(t) = c1 e^ -2t +c2 + t^2 + t.
Solution to question b
For y” = 2 and y = 1 and t =0,
c1 + c2 = 1.
Question 6: Find the explicit general solution of (x + y) y’=4
(x + y) y’=4
Let x + y = v
Therefore y= v-x
dy/dx = dv/dx – 1
therefore,
vdv/dx – v = 4
(4+v)/v = dv/dx
dx = vdv/(4+v)
x= v – ln (|v+4|^4) + c
Now putting the value of v we get,
x= x + y – ln (|x+y+4|^4) +c
y = ln (|x+y+4|^4) +c
Question 7: Using Euler’s method for the approximate points on the solution curve; y’= -x/y
Starting point = (0, 1)
h = 0.1
x0 = 0, y0 = 1
x1 = x0 + h = 0.1
x2 = x1 + h = 0.2
x3 = x2 + h = 0.3
x4 = x3 + h = 0.4
y1 = y0 + h f(x0,y0) = 1
y2 = y0 + h f(x1,y1) = .99
y3 = y0 + h f(x2,y2) = .98
y4 = y0 + h f(x3,y3) = .97
| X values | Y values |
| 0.1 | 1 |
| 0.2 | .99 |
| 0.3 | .98 |
| 0.4 | .97 |
Question 8: Find the explicit solution of y’ – 5y = 0
y(0) = 2
L { y’ – 5y = 0}
S Y(S) – 2 + 5 Y(S) = 0
Or, (S+5) Y(S) = 2
Or, Y(S) = 2/(S+5)
L-1{ Y(S) = 2/(S+5)}
Or, Y(t)= 2e^(−5t)
Question 8: Find the explicit solution of y” – 4y = 0
y (0)= 2
y’ (0)= 2
L { y” – 4y = 0}
Or, (S^2) Y(S) – S.2 – 2 + 4Y(S) = 0
Or, ((S^2) + 4) Y(S) = 2S+2
Y(S) = (2S + 2)/ ((S^2) + 4)
L-1{ Y(S) = (2S + 2)/ ((S^2) + 4)}
Or, Y(t) = sin2t + 2cos2t
