💀broo

Very good 😂

As per Euler's e^jx = cos (x) + j sin (x). And e^-jx = cos (x) - j sin (x) If you just consider the magnitude then that is equal to sqrt (cos^2 x + sin^2 x) for both the cases. For example, if you have a complex number A + j B, then its magnitude is sqrt (A^2 + B^2) So, similarly, | e^-jwt| = sqrt (cos^2 (wt) + sin^2 (wt)) = 1

​@@ALLABOUTELECTRONICS Thanks a lot for quick ve detailed answer!

Why are you using "j" to represent imaginary number Didn't the representation of imaginary number "i" comes from the term "imaginary" Using "j" just doesn't make any sense

Because i used for current, j used for imajinary in electrical engineering. By the way, I prefer in-phase (I) and quadrature (Q) as an electrical engineer because there is no imaginary thing in real world. Mathematicians loves abstraction so they call it imaginary.

You can refer fundamental of electric circuits by Sadiku for this topic.

The Laplace Transform will be useful when we are dealing with a source which is not DC or sinusoidal signal. (e.g ramp signal, exponential decaying signal, step function etc). If the clipper or clamper circuit contains a conventional source like DC, square wave, triangular wave, or sinusoidal wave) then it is better to deal such circuits with the conventional circuit analysis. I have already covered how to analyze clipper and clamper circuits. For more info, you can check those videos and the solved problems related to them.