Advertisements
Advertisements
Question
Advertisements
Solution
We have,
\[\left( x^2 - 1 \right)\frac{dy}{dx} + 2\left( x + 2 \right)y = 2\left( x + 1 \right)\]
\[ \Rightarrow \frac{dy}{dx} + \frac{2\left( x + 2 \right)}{x^2 - 1}y = \frac{2\left( x + 1 \right)}{x^2 - 1} \]
\[ \Rightarrow \frac{dy}{dx} + \frac{2\left( x + 2 \right)}{x^2 - 1}y = \frac{2}{x - 1} . . . . . . . . . . . . \left( 1 \right)\]
Clearly, it is a linear differential equation of the form
\[\frac{dy}{dx} + Py = Q\]
where
\[P = \frac{2\left( x + 2 \right)}{x^2 - 1}\]
\[Q = \frac{2}{x - 1}\]
\[ \therefore I . F . = e^{\int P\ dx} \]
\[ = e^{\int\frac{2\left( x + 2 \right)}{x^2 - 1} dx} \]
\[ = e^{\int\frac{2x}{x^2 - 1} + 4\int \frac{1}{x^2 - 1}dx} \]
\[ = e^{log\left| x^2 - 1 \right| + 4 \times \frac{1}{2}\log\left| \frac{x - 1}{x + 1} \right|} \]
\[ = e^{log \left| \left( x^2 - 1 \right) \times \frac{\left( x - 1 \right)^2}{\left( x + 1 \right)^2} \right|} \]
\[ = e^{log\left| \frac{\left( x - 1 \right)^3}{\left( x + 1 \right)} \right|} \]
\[ = \frac{\left( x - 1 \right)^3}{\left( x + 1 \right)}\]
\[\text{ Multiplying both sides of }\left( 1 \right)\text{ by }\frac{\left( x - 1 \right)^3}{\left( x + 1 \right)},\text{ we get }\]
\[\frac{\left( x - 1 \right)^3}{\left( x + 1 \right)} \left( \frac{dy}{dx} + \frac{2\left( x + 2 \right)}{x^2 - 1}y \right) = \frac{\left( x - 1 \right)^3}{\left( x + 1 \right)} \times \frac{2}{x - 1}\]
\[ \Rightarrow \frac{\left( x - 1 \right)^3}{\left( x + 1 \right)}\frac{dy}{dx} - \frac{2\left( x + 2 \right) \left( x - 1 \right)^2}{\left( x + 1 \right)^2}y = \frac{2 \left( x - 1 \right)^2}{\left( x + 1 \right)}\]
Integrating both sides with respect to x, we get
\[\frac{\left( x - 1 \right)^3}{\left( x + 1 \right)}y = \int\frac{2 \left( x - 1 \right)^2}{\left( x + 1 \right)} dx + C\]
\[ \Rightarrow \frac{\left( x - 1 \right)^3}{\left( x + 1 \right)}y = \int2\left\{ \frac{\left( x + 1 \right)^2 - 4x}{\left( x + 1 \right)} \right\} dx + C\]
\[ \Rightarrow \frac{\left( x - 1 \right)^3}{\left( x + 1 \right)}y = \int2\left\{ \left( x + 1 \right) - \frac{4x}{\left( x + 1 \right)} \right\} dx + C\]
\[ \Rightarrow \frac{\left( x - 1 \right)^3}{\left( x + 1 \right)}y = \int2\left\{ \left( x + 1 \right) - \frac{4\left( x + 1 - 1 \right)}{\left( x + 1 \right)} \right\} dx + C\]
\[ \Rightarrow \frac{\left( x - 1 \right)^3}{\left( x + 1 \right)}y = \int2\left\{ \left( x + 1 \right) - 4 + \frac{4}{\left( x + 1 \right)} \right\} dx + C\]
\[ \Rightarrow \frac{\left( x - 1 \right)^3}{\left( x + 1 \right)}y = \int\left( 2x - 6 + \frac{8}{x + 1} \right) dx + C\]
\[ \Rightarrow \frac{\left( x - 1 \right)^3}{\left( x + 1 \right)}y = x^2 - 6x + 8\log \left| x + 1 \right| + C\]
\[ \Rightarrow y = \frac{\left( x + 1 \right)}{\left( x - 1 \right)^3}\left( x^2 - 6x + 8\log \left| x + 1 \right| + C \right)\]
\[\text{Hence, }y = \frac{\left( x + 1 \right)}{\left( x - 1 \right)^3}\left( x^2 - 6x + 8\log\left| x + 1 \right| + C \right)\text{ is the required solution.} \]
APPEARS IN
RELATED QUESTIONS
Find the the differential equation for all the straight lines, which are at a unit distance from the origin.
For the differential equation, find the general solution:
`x log x dy/dx + y= 2/x log x`
For the differential equation, find the general solution:
(1 + x2) dy + 2xy dx = cot x dx (x ≠ 0)
For the differential equation, find the general solution:
`(x + 3y^2) dy/dx = y(y > 0)`
For the differential equation given, find a particular solution satisfying the given condition:
`(1 + x^2)dy/dx + 2xy = 1/(1 + x^2); y = 0` when x = 1
Find the equation of the curve passing through the origin given that the slope of the tangent to the curve at any point (x, y) is equal to the sum of the coordinates of the point.
Find the equation of a curve passing through the point (0, 2) given that the sum of the coordinates of any point on the curve exceeds the magnitude of the slope of the tangent to the curve at that point by 5.
The Integrating Factor of the differential equation `dy/dx - y = 2x^2` is ______.
The population of a village increases continuously at the rate proportional to the number of its inhabitants present at any time. If the population of the village was 20000 in 1999 and 25000 in the year 2004, what will be the population of the village in 2009?
Solve the differential equation `(tan^(-1) x- y) dx = (1 + x^2) dy`
Find the general solution of the differential equation \[\frac{dy}{dx} - y = \cos x\]
Solve the differential equation \[\left( y + 3 x^2 \right)\frac{dx}{dy} = x\]
Solve the following differential equation:- \[\left( \cot^{- 1} y + x \right) dy = \left( 1 + y^2 \right) dx\]
Solve the following differential equation: \[\left( \cot^{- 1} y + x \right) dy = \left( 1 + y^2 \right) dx\] .
Solve the differential equation \[\frac{dy}{dx}\] + y cot x = 2 cos x, given that y = 0 when x = \[\frac{\pi}{2}\] .
Solve the following differential equation:-
\[\left( 1 + x^2 \right)\frac{dy}{dx} - 2xy = \left( x^2 + 2 \right)\left( x^2 + 1 \right)\]
Solve the differential equation: (1 +x2 ) dy + 2xy dx = cot x dx
Solve the differential equation: `(1 + x^2) dy/dx + 2xy - 4x^2 = 0,` subject to the initial condition y(0) = 0.
Solve the following differential equation:
`("x" + 2"y"^3) "dy"/"dx" = "y"`
Solve the following differential equation:
`(1 - "x"^2) "dy"/"dx" + "2xy" = "x"(1 - "x"^2)^(1/2)`
Find the equation of the curve passing through the point `(3/sqrt2, sqrt2)` having a slope of the tangent to the curve at any point (x, y) is -`"4x"/"9y"`.
The integrating factor of `(dy)/(dx) + y` = e–x is ______.
Find the general solution of the equation `("d"y)/("d"x) - y` = 2x.
Solution: The equation `("d"y)/("d"x) - y` = 2x
is of the form `("d"y)/("d"x) + "P"y` = Q
where P = `square` and Q = `square`
∴ I.F. = `"e"^(int-"d"x)` = e–x
∴ the solution of the linear differential equation is
ye–x = `int 2x*"e"^-x "d"x + "c"`
∴ ye–x = `2int x*"e"^-x "d"x + "c"`
= `2{x int"e"^-x "d"x - int square "d"x* "d"/("d"x) square"d"x} + "c"`
= `2{x ("e"^-x)/(-1) - int ("e"^-x)/(-1)*1"d"x} + "c"`
∴ ye–x = `-2x*"e"^-x + 2int"e"^-x "d"x + "c"`
∴ e–xy = `-2x*"e"^-x+ 2 square + "c"`
∴ `y + square + square` = cex is the required general solution of the given differential equation
Integrating factor of `dy/dx + y = x^2 + 5` is ______
The solution of `(1 + x^2) ("d"y)/("d"x) + 2xy - 4x^2` = 0 is ______.
The integrating factor of the differential equation `x (dy)/(dx) - y = 2x^2` is
The integrating factor of differential equation `(1 - y)^2 (dx)/(dy) + yx = ay(-1 < y < 1)`
State whether the following statement is true or false.
The integrating factor of the differential equation `(dy)/(dx) + y/x` = x3 is – x.
If y = y(x) is the solution of the differential equation, `(dy)/(dx) + 2ytanx = sinx, y(π/3)` = 0, then the maximum value of the function y (x) over R is equal to ______.
Let y = f(x) be a real-valued differentiable function on R (the set of all real numbers) such that f(1) = 1. If f(x) satisfies xf'(x) = x2 + f(x) – 2, then the area bounded by f(x) with x-axis between ordinates x = 0 and x = 3 is equal to ______.
If the solution curve y = y(x) of the differential equation y2dx + (x2 – xy + y2)dy = 0, which passes through the point (1, 1) and intersects the line y = `sqrt(3) x` at the point `(α, sqrt(3) α)`, then value of `log_e (sqrt(3)α)` is equal to ______.
The solution of the differential equation `dx/dt = (xlogx)/t` is ______.
