In continuous wave (CW) radio transmission, also called radiotelegraphy, or wireless telegraphy (W/T) or on-off keying and designated by the International Telecommunication Union as emission type A1A, information is transmitted by pulses of unmodulated radio carrier wave which spell out text messages in Morse code. The different length pulses of carrier, called "dots" and "dashes" or "dits" and "dahs", are produced by the operator switching the transmitter on and off rapidly using a switch called a telegraph key. The first type of transmission was generated using a spark, since the spark fired at around 1000 times a second (when the telegraph key was pressed). The resulting damped waves (ITU Class B) could be received on a basic crystal set employing a diode detector and an ear phone as a spark rate tone. It was only with the introduction of tube transmitters that were able to create streams of continuous radio frequency carrier, that a BFO was required. The alternative was to modulate the carrier with an audio tone around 800 Hz and key the modulated carrier to permit use of the basic diode detector in the receiver, a method used for medium frequency (MF) marine communications up to 2000 (emission type A2A). Radio transmission using tubes started to replace spark transmitters at sea from 1920 onwards but were not totally eliminated before 1950^{[citation needed]}.

Since the pulses of carrier have no audio modulation, a CW signal received by an AM radio receiver simply sounds like "clicks". Sometimes, when the carrier pulses are strong enough to block out the normal static atmospheric "hiss" in the receiver, CW signals could be heard without a BFO as "pulses" of silence. However this was not a reliable method of reception. In order to make the carrier pulses audible in the receiver, a beat frequency oscillator is used. The BFO is a radio frequency electronic oscillator that generates a constant sine wave at a frequency f_BFO that is offset from the intermediate frequency f_IF of the receiver. This signal is mixed with the IF before the receiver's second detector (demodulator). In the detector the two frequencies add and subtract, and a beat frequency (heterodyne) in the audio range results at the difference between them: f_audio = |f_IF - f_BFO| which sounds like a tone in the receiver's speaker. During the pulses of carrier, the beat frequency is generated, while between the pulses there is no carrier so no tone is produced. Thus the BFO makes the "dots" and "dashes" of the Morse code signal audible, sounding like different length "beeps" in the speaker. A listener who knows Morse code can decode this signal to get the text message.

The first BFOs, used in early tuned radio frequency (TRF) receivers in the 1910s-1920s, beat with the carrier frequency of the station. Each time the radio was tuned to a different station frequency, the BFO frequency had to be changed also, so the BFO oscillator had to be tunable across the entire frequency band covered by the receiver.

Since in a superheterodyne receiver the different frequencies of the different stations are all translated to the same intermediate frequency (IF) by the mixer, modern BFOs which beat with the IF need only have a constant frequency. There may be a switch to turn off the BFO when it is not needed, when receiving other types of signals, such as AM or FM. There is also usually a knob on the front panel to adjust the frequency of the BFO, to change the tone over a small range to suit the operator's preference.

A receiver is tuned to a Morse code signal, and the receiver's intermediate frequency (IF) is f_IF = 45000 Hz. That means the dits and dahs have become pulses of a 45000 Hz signal, which is inaudible.

To make them audible, the frequency needs to be shifted into the audio range, for instance f_audio = 1000 Hz. To achieve that, the desired BFO frequency is f_BFO = 44000 or 46000 Hz.

When the signal at frequency f_IF is mixed with the BFO frequency in the detector stage of the receiver, this creates two other frequencies or heterodynes: |f_IF − f_BFO|, and |f_IF + f_BFO|. The difference frequency, f_audio = |f_IF − f_BFO| = 1000 Hz, is also known as the beat frequency.

The other, the sum frequency, (F_if + F_bfo) = 89000 or 91000 Hz, is unneeded. It can be removed by a lowpass filter, such as the radio's speaker, which cannot vibrate at such a high frequency.

f_BFO = 44000 or 46000 Hz produces the desired 1000 Hz beat frequency and either could be used.

By varying the BFO frequency around 44000 (or 46000) Hz, the listener can vary the output audio frequency; this is useful to correct for small differences between the tuning of the transmitter and the receiver, particularly useful when tuning in single sideband (SSB) voice. The waveform produced by the BFO beats against the IF signal in the mixer stage of the receiver. Any drift of the local oscillator or the beat-frequency oscillator will affect the pitch of the received audio, so stable oscillators are used.^[2]

For single sideband reception, the BFO frequency is adjusted above or below the receiver intermediate frequency, depending on which sideband is used.^[1]

Another form of beat-frequency oscillator is used as an adjustable audio frequency signal generator. The signal from a stable crystal-controlled oscillator is mixed with the signal from a tuneable oscillator; the difference in the audio range is amplified and sent as the output of the signal generator. By using crystal and adjustable frequencies higher than the audio frequency desired, a wide tuning range can be obtained for a small adjustment in the variable oscillator.^[3] Although the beat-frequency oscillator can produce an output with low distortion, the two oscillators must be very stable to maintain a constant output frequency.^[4]

• , NEETS, Module 17--Radio-Frequency Communication Principles. Integrated Publishing, Electrical Engineering Training Series.
• "Voice Modes", ARRL.