Linear Algebra with Differential Equations/Homogeneous Linear Differential Equations/Imaginary Eigenvalues Method

When eigenvalues become complex, mathematically, there isn't much wrong. However, in certain physical applications (like oscillations without damping) there is a problem in understanding what exactly does an imaginary answer mean? Thus there is a concerted effort to try to "mathematically hide" the complex variables in order to achieve a more approachable answer for physicists and engineers. Essentially, we have a solution that in part looks like this:

${\displaystyle (\alpha +\beta \cdot i)\cdot e^{r+i{\lambda }_1\cdot t}}$

But by Euler's formula:

${\displaystyle (\alpha +\beta \cdot i)\cdot e^r(cos({\lambda }_1\cdot t)+i\cdot sin({\lambda }_1\cdot t))}$

Now we distribute the terms:

${\displaystyle e^r(\alpha \cdot cos({\lambda }_1\cdot t)-\beta \cdot sin({\lambda }_1\cdot t))+i\cdot e^r(\beta \cdot cos({\lambda }_1\cdot t)+\alpha \cdot sin({\lambda }_1\cdot t))}$

Since this is a linear combination of two terms, ${\displaystyle i}$ is a constant (complex, but still a constant), each part is an element of the set of solutions and the general solution can be constructed therein.

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