![MCQs [2024]](https://engineeringinterviewquestions.com/wp-content/uploads/2021/02/Interview-Questions-2.png)
Integrating Factor Formula
Calculate the [mu] : Multiply the differential equation with integrating factor on both sides in such a way; [mu frac{dy}{dx} + mu P(x)y = mu Q(x)] In this way, on the left-hand side, we obtain a particular differential form.
The first step is to calculate and find out the integrating factor, let us say μ. Now we have to make the whole differential function in a product form with the integrating factor on both the LHS and RHS that is for example-
[mu frac{di}{dz} + mu R(x)y = mu T(x)].
This is the process of integrating factor method and the consecutive steps to use the integrating factor method formula.
How To Find Integrating Factor
The general form of representing the linear differential equations is-
y’ + G y=K
or
dy/dz + G(z) y =K(z)
Where y’ or dy/dz is the first derivative. Also, the functions G and K are the functions of z only.
There are mainly two methods which are utilized to solve the linear first-order differential equations: In mathematical calculus, two main methods which are used to equate the linear first-order differential equation are-
-
Separable Method
-
Integrating Factor Method
Now we will see and understand how we can apply these two methods and calculate the integrating factor accurately.
Integrating Factor Method technique of solving applied to solve the first and second-order differential equations.
Integrating Factor Method
We now know what integrating factor means, and it is to be calculated to solve the inexact differential equation. This method is generally used in the case of linear differential equations and sometimes can be used for higher differential calculus as well.
When the differential equation is in the form of:
[frac{(dy)}{(dx)} + P(x)(y) = Q(x)]
then the integrating factor can be defined as:
Solving Differential Equations Using Integrating Factor
First order-
We need to Compare the given equation with the differential equation form and find the value of G(z).
Now we need to start Calculating the integrating factor μ by multiplying the differential equation with the integrating factor.
By multiplying the differential equation with integrating factor on both LHS and RHS in a prescribed way, we get-
[mu frac{dy}{dz} + mu P(z)(y) = mu K(z)]
By calculating like this, on the LHS, we get a particular differential form. Which is[frac{d}{dz} (mu y) = mu K(z)].
At last, we should integrate the differential equation we have calculated using the basic formulas of integration and obtain the necessary result to the equation which is already given:
μ y = [int mu G(z)dz] + Constant term.
Solving Differential Equation Using Integrating Factor For Second Order
The integrating factor method can be easily used to solve the second-order differential equation.
Let the provided differential equation be written as:
y” + G(z) y’ = K(z);
The second-order equation given above can be easily solved by the integrating factor method.
Substitute y’ = v; so that the equation becomes similar to the first-order equation as shown:
v’ + G(z) v = K(z)
Now, this equation is required to be arranged and solved by integrating factor method as elaborated in the subheading placed above for first-order equations, and we finally get the equation: μ v=∫μG(z)dz + Constant term
Find the value of v from the resulted equation.
Since v = y’, hence to find the value of y, integrate the equation. In this way, we get the required solution.
Therefore, to find out the exact value of y, we need to integrate the resulted equation again. By following the above-mentioned methods, we can get the necessary result for the given equation.
Solved Examples
Solve the differential equation using the integrating factor method formula: [(frac{dz}{dx}) – (frac{3z}{x+1}) = (x+1)^{4}]
Solution:
Given: [(frac{dz}{dx}) – (frac{3z}{x+1}) = (x+1)^{4}]
First, we need to find the integrating factor by using the concepts of
[mu = eint g(x)dx]
[mu = eint (frac{-3}{x+1})dx]
[int (frac{-3}{x+1})dx = -3 log(x+1)^{-3}]
therefore, we get
[mu = e log(x+1)^{-3}]
[mu = frac{1}{(x+1)^{3}}]
Now, we need to multiply the integrating factor on both the LHS and RHS of the provided differential equation:
[[frac{1}{(x+1)^{3}}] [frac{dz}{dx}] – [frac{3z}{(x+1)^{4}}]] = (x+1)
Integrating both the sides, we get:
[[frac{z}{(x+1)^{3}}] = [(frac{1}{2})x^{2} + x + text{constant term}]]
Therefore, the general solution of the provided differential equation is
[z = [(x+1)^{3}] = [(frac{1}{2})x^{2} + x + text{constant term}]].