Alternating current (AC) is the type of electric current that flows in a sinusoidal pattern, meaning it changes direction periodically. It’s the kind of electricity that powers your home, TV, and phone charger. In physics, we describe AC with the simple equation \$x = x0 \sin(\omega t)\$, where \$x\$ could be voltage or current, \$x0\$ is the maximum value (amplitude), \$\omega\$ is the angular frequency, and \$t\$ is time.
Unlike direct current (DC) that flows in one direction, AC reverses direction many times per second. Think of it like a wave of water in a bathtub: the water level rises and falls smoothly, just as the voltage or current rises and falls.
The basic AC waveform is a sine wave:
\$x = x_0 \sin(\omega t)\$
Imagine a playground swing. When you push it, the swing goes forward and then backward in a smooth, repeating motion. That’s like an AC sine wave: it goes forward (positive voltage/current), then backward (negative), and repeats.
Example: Calculate the RMS voltage of a 120 V peak AC supply.
Using the formula \$x{\text{rms}} = \dfrac{x0}{\sqrt{2}}\$:
\$x_{\text{rms}} = \frac{120}{\sqrt{2}} \approx 85 \text{ V}\$
So the effective voltage that would produce the same heating effect as a DC supply is about 85 V.
| Parameter | Symbol | Formula / Description | Example Value |
|---|---|---|---|
| Amplitude | \$x_0\$ | Peak value of voltage or current | 120 V (peak) |
| Frequency | \$f\$ | Cycles per second (Hz) | 50 Hz (UK) |
| Angular Frequency | \$\omega\$ | \$\omega = 2\pi f\$ | \$314 \text{ rad/s}\$ (for 50 Hz) |
| Period | \$T\$ | \$T = 1/f\$ | \$0.02 \text{ s}\$ (for 50 Hz) |
| RMS Value | \$x_{\text{rms}}\$ | \$x{\text{rms}} = \dfrac{x0}{\sqrt{2}}\$ | \$85 \text{ V}\$ (for 120 V peak) |