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Solution:
We have,
(x - 1)(dy/dx) = 2xy
dy/y = [2x/(x - 1)]dx
On integrating both sides,
∫(dy/y) = ∫[2x + (x - 1)]dx
log(y) = ∫[2 + 2/(x - 1)]dx
log(y) = 2x + 2log(x - 1) + c (Where 'c' is integration constant)
Solution:
We have,
(x2 + 1)dy = xydx
(dy/y) = [x/(x2 + 1)]dx
On integrating both sides
∫(dy/y) = ∫[x/(x2 + 1)]dx
log(y) = (1/2)∫[2x/(x2 + 1)]dx
log(y) = (1/2)log(x2 + 1) + c (Where 'c' is integration constant)
Solution:
We have,
(dy/dx) = (ex + 1)y
(dy/y) = (ex + 1)dx
On integrating both sides
∫(dy/y) = ∫(ex + 1)dx
log(y) = (ex + x) + c (Where 'c' is integration constant)
Solution:
We have,
(x - 1)(dy/dx) = 2x3y
(dy/y) = [2x3/(x - 1)]dx
On integrating both sides
∫(dy/y) = ∫[2x3/(x - 1)]dx
∫(dy/y) = 2∫[x2 + x + 1 + 1/(x - 1)]dx
log(y) = (2/3)(x3) + x2 + 2x + 2log(x - 1) + c (Where 'c' is integration constant)
Solution:
We have,
xy(y + 1)dy = (x2 + 1)dx
y(y + 1)dy = [(x2 + 1)/x]dx
(y2 + y)dy = xdx + (dx/x)
On integrating both sides,
∫(y2 + y)dy = ∫xdx + (dx/x)
(y3/3) + (y2/2) = (x2/2) + log(x) + c (Where 'c' is integration constant)
Solution:
We have,
5(dy/dx) = exy4
5(dy/y4) = ex
On integrating both sides,
5∫(dy/y4) = ∫ex
-(5/3)(1/y3) = ex + c (Where 'c' is integration constant)
Solution:
We have,
xcosydy = (xexlogx + ex)dx
cosydy = ex(logx + 1/x)dx
On integrating both sides,
∫cosydy = ∫ex(logx + 1/x)dx
Since, ∫[f(x) + f'(x)]exdx] = exf(x)
siny = exlogx + c (Where 'c' is integration constant)
Solution:
We have,
(dy/dx) = ex+y + x2ey
(dy/dx) = exey + x2ey
dy = ey(ex + x2)dx
e-ydy = (ex + x2)dx
On integrating both sides,
∫e-ydy = ∫(ex + x2)dx
-e-y = ex + (x3/3) + c (Where 'c' is integration constant)
Solution:
We have,
x(dy/dx) + y = y2
x(dy/dx) = y2 - y
[1/(y2 - y)]dy = dx/x
On integrating both sides,
∫[1/(y2 - y)]dy = ∫dx/x
∫[1/(y - 1) - 1/y]dy = ∫(dx/x)
log(y-1) - log(y) = logx + logc
log[(y - 1)/y] = log[xc]
(y - 1)/y = xc
(y-1) = yxc (Where 'c' is integration constant)
Solution:
We have,
(ey + 1)cosxdx + eysinxdy = 0
(cosx/sinx)dx = -[ey/(ey + 1)]dy
On integrating both sides,
∫(cosx/sinx)dx = -∫[ey/(ey + 1)]dy
log(sinx) = -log(ey + 1) + log(c)
log(sinx) + log(ey + 1) = log(c)
log[sinx(ey + 1)] = log(c)
sinx(ey + 1) = c (Where 'c' is integration constant)
Solution:
We have,
xcos2ydx = ycos2xdy
(x/cos2x)dx = (y/cos2y)dy
xsec2xdx = ysec2ydy
On integrating both sides,
∫xsec2xdx = ∫ysec2ydy
xtanx - ∫tanxdx = ytany - ∫tanydy
xtanx - log(secx) = ytany - log(secy) + c (Where 'c' is integration constant)
Solution:
We have,
xydy = (y - 1)(x + 1)dx
[y/(y - 1)]dy = [(x + 1)/x]dx
On integrating both sides,
∫[y/(y - 1)]dy = ∫[(x + 1)/x]dx
∫[1 + 1/(y - 1)]dy = ∫[(x + 1)/x]dx
y + log(y - 1) = x + log(x) + c
y - x = log(x) - log(y - 1) + c (Where 'c' is integration constant)
Solution:
We have,
x(dy/dx) + coty = 0
x(dy/dx) = -coty
dy/coty = -(dx/x)
tanydy = -(dx/x)
On integrating both sides,
∫tanydy = -∫(dx/x)
log(secy) = -log(x) + log(c)
log(secy) + log(x) = log(c)
log(xsecy) = log(c)
x/cosy = c
x = c * cosy (Where 'c' is integration constant)
Solution:
We have,
(dy/dx) = (xexlogx + ex)/(xcosy)
xcosydy = (xexlogx + ex)dx
cosydy = ex(logx + 1/x)dx
On integrating both sides,
∫cosydy = ∫ex(logx + 1/x)dx
Since, ∫[f(x) + f'(x)]exdx] = exf(x)
siny = exlogx + c (Where 'c' is integration constant)
Solution:
We have,
(dy/dx) = ex+y + x3ey
(dy/dx) = exey + x3ey
dy = ey(ex + x3)dx
e-ydy = (ex + x3)dx
On integrating both sides,
∫e-ydy = ∫(ex + x3)dx
-e-y = ex + (x4/4) + c
e-y + ex + (x4/4) = c (Where 'c' is integration constant)
Solution:
We have,
y√(1 + x2) + √(1 + y2)(dy/dx) = 0
y√(1 + x2)dx = -x√(1 + y2)dy
On integrating both sides,
Let, 1 + y2 = z2
On differentiating both sides
2ydy = 2zdz
ydy = zdz
=
=
= ∫[z2/(z2 - 1)]dz
= ∫[1 + 1/(z2 - 1)]dz
= z + (1/2)log[(z - 1)/(z + 1)]
On putting the value of z in above equation
=
Similarly,
=
(Where 'c' is integration constant)
Solution:
We have,
√(1 + x2)(dy) + √(1 + y2)dx = 0
On integrating both sides,
log[y + √(1 + y2)] = -log[x + √(1 + x2)] + logclog[y + √(1 + y2)] + log[x + √(1 + x2)] = logc
log([y + √(1 + y2)][x + √(1 + x2)]) = logc
[y + √(1 + y2)][x + √(1 + x2)] = c (Where 'c' is integration constant)
Solution:
We have,
On integrating both sides,
Let, 1 + x2 = z2
On differentiating both sides
2xdx = 2zdz
xdx = zdz
=
=
= -∫[z2/(z2 - 1)]dz
= -∫[1 + 1/(z2 - 1)]dz
= -z - (1/2)log[(z - 1)/(z + 1)]
On putting the value of z in above equation
Let, 1 + y2 = v2
On differentiating both sides
2ydy = 2vdv
ydy = vdv
= ∫(vdv/v)
= v
On putting the value of v in above equation
= √(1 + y2)
=
= (Where 'c' is integration constant)
Solution:
We have,
y(2logy + 1)dy = ex(sin2x + sin2x)dx
On integrating both sides,
∫y(2logy + 1)dy = ∫ex(sin2x + sin2x)dx
Since, ∫ex(sin2x + sin2x)dx = exsin2x
Using property ∫[f(x) + f'(x)]ex = exf(x)
y2log(y) - ∫ydy + y2/2 = exsin2x + c
y2log(y) - y2/2 + y2/2 = exsin2x + c
y2log(y) = exsin2x + c (Where 'c' is integration constant)
Solution:
We have,
(dy/dx) = x(2logx + 1)/(siny + ycosy)
(siny + ycosy)dy = x(2logx + 1)dx
On integrating both sides,
∫(siny + ycosy)dy = ∫x(2logx + 1)dx
∫sinydy + y∫cosydy - ∫{(dy/dy)∫cosydy}dy = 2logx∫xdx - 2∫{∫xdx} + ∫xdx
-cosy + ysiny - ∫sinydy = x2logx - ∫xdx + (x2/2) + c
-cosy + ysiny + cosy = x2logx - (x2/2) + (x2/2) + c
ysiny = x2logx + c (Where 'c' is integration constant)
Exercise 22.7, Set 1 focuses on solving homogeneous differential equations of the first order. These equations are characterized by the right-hand side being expressible as a function of y/x. The problems range from simple rational expressions to more complex forms involving quadratic terms. Students are asked to find both general and particular solutions. The primary method used to solve these equations involves the substitution y = vx, where v is a new function of x, which transforms the homogeneous equation into a separable one. This exercise helps students recognize homogeneous forms, apply the appropriate substitution, and solve the resulting separable equations.
