The discussion focuses on solving the separable differential equation \(\frac{dy}{dx} = e^{3x-3y}\). Participants clarify the integration process, emphasizing the importance of including the constant of integration. The correct approach involves integrating both sides: \(\int e^{3y} dy = \int e^{3x} dx\), leading to the solution \(e^{3x} = e^{3y} + C\). The final forms of the solution can vary based on the placement of the constant, but both forms are valid.
PREREQUISITESStudents studying calculus, particularly those focusing on differential equations, as well as educators seeking to clarify integration techniques and solution verification methods.
OK to here. When you integrate, don't forget the constant of integration.mathor345 said:Homework Statement
\frac{dy}{dx} = e^{3x-3y}
Homework Equations
\int e^{u}du = e^u + C
The Attempt at a Solution
\frac{dy}{dx} = \frac{e^{3x}}{e^{3y}}
e^{3y} dy = e^{3x} dx
mathor345 said:ln (e^{3y}) dy = ln (e^{3x}) dx
mathor345 said:e^{3y} dy = e^{3x} dx
ln (e^{3y}) dy = ln (e^{3x}) dx
LeonhardEuler said:This last step doesn't work. If you tried to take the log of both sides you would get:
\ln{(e^{3y} dy)} = \ln{(e^{3x} dx)}
which doesn't make sense. Try integrating both sides instead.
The above should bemathor345 said:\int e^{3y} dy = \int e^{3x} dx
\frac{e^{3x}}{3} = \frac{e^{3y}}{3}
You're not going to have the same constant on both sides. The best way around having to work with two different constants is to use a single constant on one side, usually the right side.mathor345 said:e^{3x} + C = e^{3y} + C
Or you could do it like you did above. That's fine, too.mathor345 said:e^{3x} + C = e^{3y}
mathor345 said:ln (e^{3x} + C) = ln (e^{3y})
ln (e^{3x} + C) = 3y
\frac{1}{3} ln (e^{3x} + C) = y
... I think this is the right answer, but it could very well be
\frac{1}{3} ln (e^{3y} + C) = x
Depending on where you put the constant of integration?