The basic function of a resistor is to impede the passage of an electrical current, absorbing energy and dissipating it as heat. The vast majority of resistors in use dissipate less than 500 mW, and the most common are metal-oxide and metal-film types, which (due to their superior accuracy and stability) have superseded carbon composition types. Metal-film resistors have low inherent noise and high stability, and are available in a wide range of values and sizes. Metal-oxide types have better power-dissipation capabilities, and are generally based on the resistive properties of stannic oxide, SnO₂.

A capacitor consists basically of two conductive plates separated by an insulator (dielectric). It has the ability to store a charge of electricity, proportional to its capacitance, which for general use may range from 1 pF to 10 000 μF, and may be more for special applications like clock back-up stores in videorecorders. Capacitors are broadly divided into two classes, non-polarised and electrolytic.

Inductance concerns the magnetic properties of a current-carrying conductor; all conductors are surrounded by magnetic fields. Practical inductors concentrate the magnetic field by winding the conductor into a coil with (usually) a magnetic core of ferrite or laminated iron. A basic property of an inductor is its ability to turn electrical energy into magnetic energy and vice versa. Examples are solenoids, relays, recording heads and loudspeakers in the one case, and replay heads, ferrite-rod aerials, phono pick-ups and VCR-motor PG/FG generators in the other. Transformers convert an alternating current into a strong, ‘tight’ magnetic field which induces a current in the secondary winding, usually at a different voltage: transformation ratio is proportional to wire-turns ratio.

The diode is the simplest form of semiconductor, and consists of a single PN junction with the basic characteristic of conducting in one direction only. Most general-purpose diodes are based on silicon, with a forward voltage drop of about 700 mV and a very high reverse resistance.

A transistor is a semiconductor device whose output can be controlled by the signal applied to one or more input electrodes, in the form of current in the base-emitter junction (bipolar type) or voltage at the gate (field-effect type). Most transistors are based on silicon, and have three terminals, base/emitter/collector or gate/drain/source. Basically transistors are classified by their semiconductor material (germanium, Ge; or silicon, Si) and their polarity (PNP or NPN). Within these categories there is a very wide range of types: general purpose, for linear or switching applications up to about 3 MHz at about 500 mW dissipation; power devices, typically used in audio amplifier output stages, whose main characteristic is an ability to dissipate heat; high-voltage types, for, for example, RGB output stages driving picture-tube cathodes, and (combined with high power capability) for PSU switching and line deflection; high-frequency devices with short transit times and often low-noise characteristics for use in VHF, UHF, and SHF front-ends; low-noise types for amplification of very small baseband signals; Darlington pairs which give very high power gain; switching transistors for fast pulse or logic signal handling; and complementary pairs, matched NPN/PNP devices generally used for audio class B power amplification. These categories are the main ones encountered in TVs and VCRs.

Most of the components described so far (but primarily semiconductor devices) can be formed on a silicon wafer substrate in subminiature form with very high density to form integrated circuits (ICs), whose advent and development is alone responsible for the very advanced state of consumer electronics, and the low – in real terms – cost of equipment.