Study Hall

Supported By

In The Studio: Preventing Hum And RFI

A handy guide to greatly reduce the likelihood of hum and radio frequency interference (RFI) in your studio system

You patch in a piece of audio equipment, and there it is: HUM!

This annoying sound is a common occurrence in sound systems. Hum is an unwanted 60 Hz tone—50 Hz in Europe—maybe with harmonics. If the harmonics are especially strong, the hum becomes an edgy buzz.

Your sound system also might be plagued by RFI (Radio Frequency Interference). It’s heard as buzzing, clicks, radio programs, or “hash” in the audio signal.

RFI is caused by CB transmitters, computers, lightning, radar, radio and TV transmitters, industrial machines, cell phones, auto ignitions, stage lighting, and other sources. This article looks at some causes and cures of hum and RFI. Following these suggestions goes a long way in keeping your audio clean.

Hum And Cables
One cause of hum is audio cables picking up magnetic and electrostatic hum fields radiated by power wiring in the walls of a room. Magnetic hum fields can couple by magnetic induction to audio cables, and electrostatic hum fields can couple capacitively to audio cables. Magnetic hum fields are directional and electrostatic hum fields are not.

Most audio cables are made of one or two insulated conductors (wires) surrounded by a fine-wire mesh shield that reduces electrostatically induced hum. The shield drains induced hum signals to ground when the cable is plugged in. Outside the shield is a plastic or rubber insulating jacket.

Cables are either balanced or unbalanced. A balanced line is a cable that uses two conductors to carry the signal, surrounded by a shield (Figure 1). On each end of the cable is an XLR (3-pin pro audio) connector or TRS (tip-ring-sleeve) phone plug.

Figure 1. A 2-conductor shielded, balanced line.

Each conductor has equal impedance to ground, and they are twisted together so they occupy about the same position in space on the average.

Hum fields from power wiring radiate into each conductor equally, generating equal hum signals on the two conductors (more so if they are a twisted pair). Those two hum signals cancel out at the input of your mixer, because it senses the difference in voltage between those two conductors—which is zero volts if the two hum signals are equal. That’s why balanced cables tend to pick up little or no hum.

An unbalanced line has a single conductor surrounded by a shield (Figure 2). At each end of the cable is a phone plug or RCA (phono) plug. The central conductor and the shield both carry the signal.

They are at different impedances to ground, so they pick up different amounts of hum from nearby power wiring. There’s a relatively big hum signal between hot and ground that results in more hum than you get with a balanced line of the same length.

Figure 2. A 1-conductor shielded, unbalanced line.

Sometimes it’s impossible to avoid long unbalanced cables, and some cables used between pieces of equipment are unbalanced. An unbalanced line less than 10 feet long usually does not pick up enough hum to be a problem.

Wherever you can, use balanced cables going into balanced equipment. Keep unbalanced cables as short as possible (but long enough so that you can service them). Check inside cable connectors to make sure that the shield and conductors are soldered to the connector terminals. Route mic cables and patch cords away from power cords; separate them vertically where they cross. This prevents the power cords from inducing hum into the mic cables.

Read More
In The Studio: Mid-Side Microphone Recording Basics

Also keep audio equipment and cables away from computer monitors, power amplifiers, lighting dimmers and power transformers.

Supported By

Celebrating over 50 years of audio excellence worldwide, Audio-Technica is a leading innovator in transducer technology, renowned for the design and manufacture of microphones, wireless microphones, headphones, mixers, and electronics for the audio industry.

Church Audio Tech Training Available Through Church Sound University. Find Out More!