Bel

For the Mesopotamian deity, see Bel (god)

A bel (symbol B) is a unit of measure of ratios of power levels, i.e. relative power levels. It is mostly used in telecommunication, electronics and acoustics. Invented by engineers of the Bell Telephone Laboratory, it was originally called the transmission unit or TU, but was renamed in 1923 or 1924 in honour of the laboratory's founder and telecommunications pioneer Alexander Graham Bell.

The bel is a logarithmic measure. The number of bels for a given ratio of power levels is calculated by taking the logarithm, to the base 10, of the ratio. Therefore, one bel corresponds to a ratio of 10:1. Mathematically, the number of bels is calculated as B = log₁₀(P ₁/P ₂) where P ₁ and P ₂ are power levels. The neper is a similar unit which uses the natural logarithm.

The bel is too large for everyday use, so the decibel (dB), equal to 0.1B, is more commonly used. 1dB is equivalent to a ratio of about 1.259:1. It is defined as 10 log₁₀(P ₁/P ₂) where P ₁ and P ₂ are the powers.

The decibel is not an SI unit, although the CIPM has recommended its inclusion in the SI system.

Table of contents

1 Uses

1.1 Optics
1.2 Acoustics
1.3 Electronics
1.4 Telecommunications
1.5 Seismology

2 Typical abbreviations
3 Common Misconceptions

3.6 +3dB means "times two"

4 References

Uses

Optics

In an optical link, if a known amount of optical power, in dBm (decibel.milliwatts), is launched into a fiber, and the losses, in dB (decibels), of each component (e.g. connectors, splices, and lengths of fiber) are known, the overall link loss may be quickly calculated by simple addition and subtraction of decibel quantities.

Acoustics

The decibel is often used in acoustics to quantify sound levels relative to some 0 dB reference. The reference may be defined as a sound pressure level (SPL), commonly 20 micropascal (20 μPa). To avoid confusion with other decibel measures, the term dB(SPL) is used for this. The reference can also be defined as the sound intensity at the threshold of human hearing, which is conventionally taken to be one picowatt per square metre (1 pW/m²), roughly the sound of a mosquito flying 10 feet (3 m) away.

The reason for using the decibel is that the ear is capable of hearing a very large range of sound pressures. The ratio of the sound pressure that causes permanent damage from short exposure to the limit that (undamaged) ears can hear is more than a million. Because the power in a sound wave is proportional to the square of the pressure, the ratio of the maximum power to the minimum power is more than one trillion. To deal with such a range, logarithmic units are useful: the log of a trillion is 12, so this ratio represents a difference of 120 dB.

Psychologists have found that our perception of loudness is roughly logarithmic, see Weber-Fechner Law. In other words, you have to multiply the sound intensity by the same factor to have the same increase in loudness. This is why the numbers around the volume control dial on a typical audio amplifier are related not to the absolute power amplification, but to its logarithm.

Various frequency weightings are used for acoustical measurements to approximate the changes in sensitivity of the ear to different frequencies at different levels. These include the dB(A), dB(B), and dB(C) weightings.

Sounds above 85 decibels are considered harmful, while 120 dB is unsafe and 150 db causes physical damage to the human body. Windows break at 163 dB. Jet airplanes are 165 dB. Eardums pop at 190 to 198 dB. Shock waves and sonic booms are 194 dB. Sounds around 200 db can cause death to humans and are generated near bomb explosions. The space shuttle is around 215 dB. Nuclear bombs are 240 to 258 dB. Even louder are earthquakes, tornados, hurricanes and volcanoes.

Todo: these example SPLs could do with distances from source...

Electronics

The decibel is used rather than arithmetic ratios or percentages because when certain types of circuits, such as amplifiers and attenuators, are connected in series, expressions of power level in decibels may be arithmetically added and subtracted.

In radio electronics, the decibel is used to describe the ratio between two measurements of electrical power. It can also be combined with a suffix to create an absolute unit of electrical power. For example, it can be combined with "m" for "milliwatt" to produce the "dBm". 0 dBm is one milliwatt, and 1dBm is one decibel greater than 0 dBm, or about 1.259 mW.

dBm - dB(mV/m²) - millivolts per square metre - signal strength of a radio signal
dBμ or dBu - dB(μV/m²) - microvolts per square metre - strength of a radio signal
dBf - dB(fW) - femtowatts - amount of power required to drive a radio receiver
dBW - dB(W) - watts - amount of power transmitted by a low-power radio station
dBk - dB(kW) - kilowatts - amount of power transmitted by a broadcast radio station
dBV - dB(V) - volts - amplitude of an audio signal in a wire
dBv or dBu - dB(0.775V) - same as dBV but referenced to 0.775 volts instead of 1 volt
dBm - dB(mW@600Ω) - in analogue audio, milliwatts into a 600-ohm load

Relative measurements:

dBA, dBB, or dBC - different weightings of the human ear's response to sound
dBd - dB(dipole) - effective radiated power compared to a dipole antenna
dBi - dB(isotropic) - effective radiated power compared to an imaginary isotropic antenna
dBfs or dBFS - dB(full scale) - amplitude of a signal (usually audio) compared to the maximum which a device can handle before clipping occurs

Common Misconceptions

+3dB means "times two"

Not exactly. As stated above, decibels are defined so that +10dB means "ten times the power". From this, we calculate that +3dB actually multiplies the power by 10^(3/10). The Microsoft (R) Calculator reports that this is a ratio of 1.9952623149688796013524553967395. This is about 0.25% different from the *2 ratio that is sometimes assumed. +6dB would be 3.9810717055349725077025230508775, about 0.5% different from *4.

To contrive a more serious example, consider converting a large decibel figure into its linear ratio, for example 120dB. This is correctly calculated as a ratio of 10^12 or one trillion. But if we use the assumption that 3dB means *2, we would calculate a ratio of 2^(120/3) = 2^40 = 1099511627776, for a 10% error.

References

Martin, W. H., "DeciBel – The New Name for the Transmission Unit", Bell System Technical Journal, January 1929.