Ohm's Law, which states that the current through a conductor between two points is directly proportional to the voltage across the two points, is applicable to linear elements like resistors. However, when dealing with non-linear elements, Ohm's Law in its simple form is not directly applicable.
Non-linear elements, such as diodes, transistors, and some semiconductor devices, do not obey Ohm's Law. Instead, their behavior is described by non-linear equations, making their current-voltage relationship more complex.
However, small-signal models can be used to extend Ohm's Law and analyze the behavior of non-linear elements around their operating points. Small-signal models approximate the non-linear element's behavior using linear approximations within a small range of operation around a given bias point (or quiescent point).
The small-signal model takes the form of linear equations, enabling the use of linear circuit analysis techniques. This is particularly useful in electronic design, as it allows engineers to predict and analyze the linearized response of a circuit containing non-linear elements.
For example, in the case of a diode, a small-signal model can be used to describe its behavior around the DC bias point, assuming the signal variations around that point are small enough to be approximated linearly. This allows us to analyze the diode's response to small variations in voltage and current.
It's important to note that while small-signal models are valuable for understanding the linearized behavior of non-linear elements, they are limited in their applicability. When the signal variations become large or if the non-linearity of the element is too strong, the small-signal model may no longer be accurate, and more advanced analysis techniques, like numerical simulations, are required.