Mathematical methods in electronics


Mathematical methods are integral to the study of electronics.

Mathematics in electronics

careers usually include courses in calculus, complex analysis, differential equations, linear algebra and probability. Fourier analysis and Z-transforms are also subjects which are usually included in electrical engineering programs.

Basic applications

A number of electrical laws apply to all electrical networks. These include
Circuit analysis is the study of methods to solve linear systems for an unknown variable.
There are many electronic components currently used and they all have their own uses and particular rules and methods for use.
If you apply a voltage across a capacitor, it 'charges up' by storing the electrical charge as an electrical field inside the device. This means that while the voltage across the capacitor remains initially small, a large current flows. Later, the current flow is smaller because the capacity is filled, and the voltage raises across the device.
A similar though opposite situation occurs in an inductor; the applied voltage remains high with low current as a magnetic field is generated, and later becomes small with high current when the magnetic field is at maximum.
The voltage and current of these two types of devices are therefore out of phase, they do not rise and fall together as simple resistor networks do. The mathematical model that matches this situation is that of complex numbers, using an imaginary component to describe the stored energy.

Signal analysis