Show that #y=2/3e^x+e^(-2x)# is a solution of the differential equation #y'+2y=2e^x#?
I am having trouble coming up with a method to the solution of this general differential equation without the use of an integration factor. It is the first question in Ch. 9.1 of James Stewart's Calculus. At this point, the integration factor has not been introduced.
Thanks!
I am having trouble coming up with a method to the solution of this general differential equation without the use of an integration factor. It is the first question in Ch. 9.1 of James Stewart's Calculus. At this point, the integration factor has not been introduced.
Thanks!
If you are asked to SHOW that this is a solution, you do not need to solve the DE.
Differentiate
Add
Note
I do not have a copy of Stewart here, but if this is the first exercise in the first section on differential equations, then the point may be to show that this is a solution, not to show how to arrive at this solution.
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See explanation.
Showing that something is a solution to an equation means plugging in the given expression (and any implied expressions necessary) to that equation, and making sure it holds true.
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I don't have that text to refer to, so I will try but depending upon how far you have progressed in solving DE's it may be a out of scope
This is a First Order Linear non-homogeneous Ordinary Differential Equation of the form;
If we had knowledge of the Integrating Factor then we could use:
We could just take the answer and take its derivative and show that it satisfies the differential equation but that is not a method of "coming up with a method to the solution", so let's assume we have no knowledge of the solution.
There are two methods I could use to solve this equation.
Method 1 - Use the fact that it is a linear DE with constant coefficients
We use the same method used to solve a second order (or in fact any order) differential equation with constant coefficients. We can solve the homogeneous equation to find the Complementary Function (CF):
by turning to the Auxiliary Equation. This is made up with the coefficients of the derivatives, viz;
Substitute this into the DE, and we get
Hence the general solution is :
Method 2 -Use an Integrating Factor but from First Principles
We cannot separate the variables for this DE because we cannot find:
Which is now a separable DE which we can just integrate to get:
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To show that ( y = \frac{2}{3}e^x + e^{-2x} ) is a solution of the differential equation ( y' + 2y = 2e^x ), we need to verify that when we substitute ( y ) into the equation, the equation holds true.
First, let's find the derivative of ( y ) with respect to ( x ):
[ y = \frac{2}{3}e^x + e^{-2x} ]
[ y' = \frac{2}{3}\frac{d}{dx}(e^x) + \frac{d}{dx}(e^{-2x}) ]
[ y' = \frac{2}{3}e^x - 2e^{-2x} ]
Now, let's substitute ( y ) and ( y' ) into the given differential equation:
[ y' + 2y = \left(\frac{2}{3}e^x - 2e^{-2x}\right) + 2\left(\frac{2}{3}e^x + e^{-2x}\right) ]
[ y' + 2y = \frac{2}{3}e^x - 2e^{-2x} + \frac{4}{3}e^x + 2e^{-2x} ]
[ y' + 2y = \frac{6}{3}e^x ]
[ y' + 2y = 2e^x ]
As we can see, after simplification, the left-hand side of the equation is indeed equal to the right-hand side. Therefore, ( y = \frac{2}{3}e^x + e^{-2x} ) is a solution of the given differential equation.
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When evaluating a one-sided limit, you need to be careful when a quantity is approaching zero since its sign is different depending on which way it is approaching zero from. Let us look at some examples.
When evaluating a one-sided limit, you need to be careful when a quantity is approaching zero since its sign is different depending on which way it is approaching zero from. Let us look at some examples.
When evaluating a one-sided limit, you need to be careful when a quantity is approaching zero since its sign is different depending on which way it is approaching zero from. Let us look at some examples.
When evaluating a one-sided limit, you need to be careful when a quantity is approaching zero since its sign is different depending on which way it is approaching zero from. Let us look at some examples.
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