DBm

Last updated
A schematic showing the relationship between dBu (the voltage source) and dBm (the power dissipated as heat by the 600 O resistor) Relationship between dBu and dBm.svg
A schematic showing the relationship between dBu (the voltage source) and dBm (the power dissipated as heat by the 600 Ω resistor)

dBm or dBmW (decibel-milliwatts) is a unit of level used to indicate that a power level is expressed in decibels (dB) with reference to one milliwatt (mW). It is used in radio, microwave and fiber-optical communication networks as a convenient measure of absolute power because of its capability to express both very large and very small values in a short form. dBW is a similar unit, referenced to one watt (1,000 mW).

Contents

The decibel (dB) is a dimensionless unit, used for quantifying the ratio between two values, such as signal-to-noise ratio. The dBm is also dimensionless, [1] [2] but since it compares to a fixed reference value, the dBm rating is an absolute one.

The dBm is not a part of the International System of Units (SI) and therefore is discouraged from use in documents or systems that adhere to SI units (the corresponding SI unit is the watt). However, the unit decibel (dB), without the 'm' suffix, is permitted for relative quantities, but not accepted for use directly alongside SI units. Ten decibel-milliwatts may be written 10 dB (1 mW) in SI. [3] :7.4

In audio and telephony, dBm is typically referenced relative to a 600-ohm impedance, [4] while in radio-frequency work dBm is typically referenced relative to a 50-ohm impedance. [5]

Unit conversions

A power level of 0 dBm corresponds to a power of 1 milliwatt. A 10 dB increase in level is equivalent to a ten-fold increase in power. Therefore, a 20 dB increase in level is equivalent to a 100-fold increase in power. A 3 dB increase in level is approximately equivalent to doubling the power, which means that a level of 3 dBm corresponds roughly to a power of 2 mW. Similarly, for each 3 dB decrease in level, the power is reduced by about one half, making −3 dBm correspond to a power of about 0.5 mW.

To express an arbitrary power P in mW as x in dBm, the following expression may be used: [6]

Conversely, to express an arbitrary power level x in dBm, as P in mW:

Table of examples

Below is a table summarizing useful cases:

Power levelPowerNotes
526 dBm3.6×1049 W Black hole collision, the power radiated in gravitational waves following the collision GW150914, estimated at 50 times the power output of all the stars in the observable universe. [7] [8]
420 dBm1×1039 W Cygnus A, one of the most powerful radio sources in the sky
296 dBm3.846×1026 WTotal power output of the Sun [9]
120 dBm1 GW = 1,000,000,000 WExperimental high-power microwave (HPM) generation system, 1 GW at 2.32 GHz for 38 ns [10]
105 dBm32 MW AN/FPS-85 Phased Array Space Surveillance Radar, claimed by the US Space Force as the most powerful radar in the world. [11]
95.5 dBm3,600 kW High-frequency Active Auroral Research Program maximum power output, the most powerful shortwave station in 2012
80 dBm100 kWTypical transmission power of FM radio station with 50-kilometre (31 mi) range
62 dBm1.588 kW1.5 kW is the maximum legal power output of a US ham radio station. [12]
60 dBm1 kW = 1,000 WTypical combined radiated RF power of microwave oven elements
55 dBm~300 WTypical single-channel RF output power of a Ku band geostationary satellite
50 dBm100 WTypical total thermal radiation emitted by a human body, peak at 31.5 THz (9.5 μm)

Typical maximum output RF power from a ham radio HF transceiver without power amplifier

40 dBm10 WTypical power-line communication (PLC) transmission power
37 dBm5 WTypical maximal output RF power from a handheld ham radio VHF/UHF transceiver
36 dBm4 WTypical maximal output power for a citizens band radio station (27 MHz) in many countries
33 dBm2 WMaximal output from a UMTS/3G mobile phone (power class 1 mobiles)

Maximal output from a GSM850/900 mobile phone

30 dBm1 W = 1000  mW

DCS or GSM 1,800/1,900 MHz mobile phone. EIRP IEEE 802.11a (20 MHz-wide channels) in either 5 GHz subband 2 (5,470–5,725 MHz) provided that transmitters are also IEEE 802.11h-compliant, or U-NII-3 (5,725–5,825 MHz). The former is EU only, the latter is US only. Also, maximal power allowed by the FCC for American amateur radio licensees to fly radio-controlled aircraft or operate RC models of any other type on the amateur radio bands in the US. [13]

29 dBm794 mW
28 dBm631 mW
27 dBm500 mWTypical cellular phone transmission power

Maximal output from a UMTS/3G mobile phone (power class 2 mobiles)

26 dBm400 mW
25 dBm316 mW
24 dBm251 mWMaximal output from a UMTS/3G mobile phone (power class 3 mobiles)

1,880–1,900 MHz DECT (250 mW per 1,728 kHz channel). EIRP for wireless LAN IEEE 802.11a (20 MHz-wide channels) in either the 5 GHz subband 1 (5,180–5,320 MHz) or U-NII-2 and -W ranges (5,250–5,350 MHz & 5,470–5,725 MHz, respectively). The former is EU only, the latter is US only.

23 dBm200 mW EIRP for IEEE 802.11n wireless LAN 40 MHz-wide (5 mW/MHz) channels in 5 GHz subband 4 (5,735–5,835 MHz, US only) or 5 GHz subband 2 (5,470–5,725 MHz, EU only). Also applies to 20 MHz-wide (10 mW/MHz) IEEE 802.11a wireless LAN in 5 GHz subband 1 (5,180–5,320 MHz) if also IEEE 802.11h-compliant (otherwise only 3 mW/MHz → 60 mW when unable to dynamically adjust transmission power, and only 1.5 mW/MHz → 30 mW when a transmitter also cannot dynamically select frequency).
22 dBm158 mW
21 dBm125 mWMaximal output from a UMTS/3G mobile phone (power class 4 mobiles)
20 dBm100 mW EIRP for IEEE 802.11b/g wireless LAN 20 MHz-wide channels in the 2.4 GHz Wi-Fi/ISM band (5 mW/MHz).

Bluetooth Class 1 radio. Maximal output power from unlicensed AM transmitter per US FCC rules 15.219 [14]

19 dBm79 mW
18 dBm63 mW
17 dBm50 mW
15 dBm32 mWTypical wireless LAN transmission power in laptops
10 dBm10 mW
7 dBm5.0 mWCommon power level required to test the automatic gain control circuitry in an AM receiver
6 dBm4.0 mW
5 dBm3.2 mW
4 dBm2.5 mWBluetooth Class 2 radio, 10 m range
3 dBm2.0 mW
2 dBm1.6 mW
1 dBm1.3 mW
0 dBm1.0 mW = 1000 μWBluetooth standard (Class 3) radio, 1 m range
−1 dBm794 μW
−3 dBm501 μW
−5 dBm316 μW
−10 dBm100 μWMaximal received signal power of wireless network (802.11 variants)
−13 dBm50.12 μWDial tone for the precise tone plan found on public switched telephone networks in North America
−20 dBm10 μW
−30 dBm1.0 μW = 1000  nW
−40 dBm100  nW
−50 dBm10 nW
−60 dBm1.0 nW = 1000  pW The Earth receives one nanowatt per square metre from a magnitude +3.5 star [15]
−70 dBm100 pW
−73 dBm50.12 pW"S9" signal strength, a strong signal, on the S meter of a typical ham or shortwave radio receiver
−80 dBm10 pW
−100 dBm0.1 pWMinimal received signal power of wireless network (802.11 variants)
−111 dBm0.008 pW = 8  fW Thermal noise floor for commercial GPS single-channel signal bandwidth (2 MHz)
−127.5 dBm0.178 fW = 178  aW Typical received signal power from a GPS satellite
−174 dBm0.004 aW = 4  zW Thermal noise floor for 1 Hz bandwidth at room temperature (20 °C)
−192.5 dBm0.056 zW = 56  yW Thermal noise floor for 1 Hz bandwidth in outer space (4  kelvins)
−∞ dBm0 WZero power is not well-expressed in dBm (value is negative infinity)

Standards

The signal intensity (power per unit area) can be converted to received signal power by multiplying by the square of the wavelength and dividing by 4π (see Free-space path loss).

In United States Department of Defense practice, unweighted measurement is normally understood, applicable to a certain bandwidth, which must be stated or implied.

In European practice, psophometric weighting may be, as indicated by context, equivalent to dBm0p, which is preferred.

In audio, 0 dBm often corresponds to approximately 0.775 volts, since 0.775 V dissipates 1 mW in a 600 Ω load. [16] The corresponding voltage level is 0 dBu, without the 600 Ω restriction. Conversely, for RF situations with a 50 Ω load, 0 dBm corresponds to approximately 0.224 volts, since 0.224 V dissipates 1 mW in a 50 Ω load. In general the relationship between the power level P in dBms and the RMS voltage V in volts across a load of resistance R (typically used to terminate a transmission line with impedance Z) is:

Expression in dBm is typically used for optical and electrical power measurements, not for other types of power (such as thermal). A listing by power levels in watts is available that includes a variety of examples not necessarily related to electrical or optical power.

The dBm was first proposed as an industry standard [16] in the paper "A New Standard Volume Indicator and Reference Level". [17]

See also

Related Research Articles

The decibel is a relative unit of measurement equal to one tenth of a bel (B). It expresses the ratio of two values of a power or root-power quantity on a logarithmic scale. Two signals whose levels differ by one decibel have a power ratio of 101/10 or root-power ratio of 10120.

In physics, power is the amount of energy transferred or converted per unit time. In the International System of Units, the unit of power is the watt, equal to one joule per second. In older works, power is sometimes called activity. Power is a scalar quantity.

<span class="mw-page-title-main">Neper</span> Logarithmic unit for ratios of measurements of physical field and power quantities

The neper is a logarithmic unit for ratios of measurements of physical field and power quantities, such as gain and loss of electronic signals. The unit's name is derived from the name of John Napier, the inventor of logarithms. As is the case for the decibel and bel, the neper is a unit defined in the international standard ISO 80000. It is not part of the International System of Units (SI), but is accepted for use alongside the SI.

<span class="mw-page-title-main">Gain (electronics)</span> Ability of a circuit to increase the power or amplitude of a signal

In electronics, gain is a measure of the ability of a two-port circuit to increase the power or amplitude of a signal from the input to the output port by adding energy converted from some power supply to the signal. It is usually defined as the mean ratio of the signal amplitude or power at the output port to the amplitude or power at the input port. It is often expressed using the logarithmic decibel (dB) units. A gain greater than one, that is, amplification, is the defining property of an active component or circuit, while a passive circuit will have a gain of less than one.

<span class="mw-page-title-main">Gain (antenna)</span> Telecommunications performance metric

In electromagnetics, an antenna's gain is a key performance parameter which combines the antenna's directivity and radiation efficiency. The term power gain has been deprecated by IEEE. In a transmitting antenna, the gain describes how well the antenna converts input power into radio waves headed in a specified direction. In a receiving antenna, the gain describes how well the antenna converts radio waves arriving from a specified direction into electrical power. When no direction is specified, gain is understood to refer to the peak value of the gain, the gain in the direction of the antenna's main lobe. A plot of the gain as a function of direction is called the antenna pattern or radiation pattern. It is not to be confused with directivity, which does not take an antenna's radiation efficiency into account.

<span class="mw-page-title-main">Johnson–Nyquist noise</span> Electronic noise due to thermal vibration within a conductor

Johnson–Nyquist noise is the electronic noise generated by the thermal agitation of the charge carriers inside an electrical conductor at equilibrium, which happens regardless of any applied voltage. Thermal noise is present in all electrical circuits, and in sensitive electronic equipment can drown out weak signals, and can be the limiting factor on sensitivity of electrical measuring instruments. Thermal noise increases with temperature. Some sensitive electronic equipment such as radio telescope receivers are cooled to cryogenic temperatures to reduce thermal noise in their circuits. The generic, statistical physical derivation of this noise is called the fluctuation-dissipation theorem, where generalized impedance or generalized susceptibility is used to characterize the medium.

<span class="mw-page-title-main">Effective radiated power</span> Definition of directional radio frequency power

Effective radiated power (ERP), synonymous with equivalent radiated power, is an IEEE standardized definition of directional radio frequency (RF) power, such as that emitted by a radio transmitter. It is the total power in watts that would have to be radiated by a half-wave dipole antenna to give the same radiation intensity as the actual source antenna at a distant receiver located in the direction of the antenna's strongest beam. ERP measures the combination of the power emitted by the transmitter and the ability of the antenna to direct that power in a given direction. It is equal to the input power to the antenna multiplied by the gain of the antenna. It is used in electronics and telecommunications, particularly in broadcasting to quantify the apparent power of a broadcasting station experienced by listeners in its reception area.

Sound pressure or acoustic pressure is the local pressure deviation from the ambient atmospheric pressure, caused by a sound wave. In air, sound pressure can be measured using a microphone, and in water with a hydrophone. The SI unit of sound pressure is the pascal (Pa).

Sound power or acoustic power is the rate at which sound energy is emitted, reflected, transmitted or received, per unit time. It is defined as "through a surface, the product of the sound pressure, and the component of the particle velocity, at a point on the surface in the direction normal to the surface, integrated over that surface." The SI unit of sound power is the watt (W). It relates to the power of the sound force on a surface enclosing a sound source, in air.

Particle velocity is the velocity of a particle in a medium as it transmits a wave. The SI unit of particle velocity is the metre per second (m/s). In many cases this is a longitudinal wave of pressure as with sound, but it can also be a transverse wave as with the vibration of a taut string.

The decibel watt is a unit for the measurement of the strength of a signal expressed in decibels relative to one watt. It is used because of its capability to express both very large and very small values of power in a short range of number; e.g., 1 milliwatt = −30 dBW, 1 watt = 0 dBW, 10 watts = 10 dBW, 100 watts = 20 dBW, and 1,000,000 W = 60 dBW.

Line level is the specified strength of an audio signal used to transmit analog audio between components such as CD and DVD players, television sets, audio amplifiers, and mixing consoles.

<span class="mw-page-title-main">VU meter</span> Audio signal level measurement device

A volume unit (VU) meter or standard volume indicator (SVI) is a device displaying a representation of the signal level in audio equipment.

<span class="mw-page-title-main">AC power</span> Power in alternating current systems

In an electric circuit, instantaneous power is the time rate of flow of energy past a given point of the circuit. In alternating current circuits, energy storage elements such as inductors and capacitors may result in periodic reversals of the direction of energy flow. Its SI unit is the watt.

In electromagnetics, the antenna factor is defined as the ratio of the electric field E to the voltage V induced across the terminals of an antenna:

dBc is the power ratio of a signal to a carrier signal, expressed in decibels. For example, phase noise is expressed in dBc/Hz at a given frequency offset from the carrier. dBc can also be used as a measurement of Spurious-Free Dynamic Range (SFDR) between the desired signal and unwanted spurious outputs resulting from the use of signal converters such as a digital-to-analog converter or a frequency mixer.

dBm0 is an abbreviation for the power in dBm measured at a zero transmission level point (ZLP).

<span class="mw-page-title-main">Attenuator (electronics)</span> Type of electronic component

An attenuator is an electronic device that reduces the power of a signal without appreciably distorting its waveform.

The log-distance path loss model is a radio propagation model that predicts the path loss a signal encounters inside a building or densely populated areas over distance.

The watt is the unit of power or radiant flux in the International System of Units (SI), equal to 1 joule per second or 1 kg⋅m2⋅s−3. It is used to quantify the rate of energy transfer. The watt is named in honor of James Watt (1736–1819), an 18th-century Scottish inventor, mechanical engineer, and chemist who improved the Newcomen engine with his own steam engine in 1776. Watt's invention was fundamental for the Industrial Revolution.

References

PD-icon.svg This article incorporates public domain material from Federal Standard 1037C. General Services Administration. Archived from the original on 2022-01-22. (in support of MIL-STD-188).

  1. Green, Lynne D. (2019). Fiber Optic Communications. CRC Press. p. 181. ISBN   9781000694512.
  2. Kosatsky, Tom (2013). Radiofrequency Toolkit for Environmental Health Practitioners (PDF). British Columbia Centre for Disease Control. p. 8. Archived (PDF) from the original on 2022-10-09.
  3. Thompson and Taylor 2008, Guide for the Use of the International System of Units (SI), NIST Special Publication SP811 Archived 2016-06-03 at the Wayback Machine .
  4. Bigelow, Stephen (2001). Understanding Telephone Electronics . Newnes. pp.  16. ISBN   978-0750671750.
  5. Carr, Joseph (2002). RF Components and Circuits . Newnes. pp.  45–46. ISBN   978-0750648448.
  6. Sobot, Robert (2012). Wireless Communication Electronics: Introduction to RF Circuits and Design. Springer. p. 252. ISBN   9783030486303.
  7. "OBSERVATION OF GRAVITATIONAL WAVES FROM A BINARY BLACK HOLE MERGER" (PDF). LSC (Ligo Scientific Collaboration). Caltech. 2015. Archived (PDF) from the original on 2022-10-09. Retrieved 10 April 2021.
  8. "Found! Gravitational Waves, or a Wrinkle in Spacetime". National Geographic. 2016-02-11. Archived from the original on February 24, 2021. Retrieved 2021-04-10.
  9. "Ask Us: Sun". Cosmicopia. NASA. 2012. Archived from the original on 2000-08-16. Retrieved 13 July 2017.
  10. Li, Wei; Li, Zhi-qiang; Sun, Xiao-liang; Zhang, Jun (2015-11-01). "A reliable, compact, and repetitive-rate high power microwave generation system". Review of Scientific Instruments. 86 (11): 114704. Bibcode:2015RScI...86k4704L. doi:10.1063/1.4935500. ISSN   0034-6748. PMID   26628156.
  11. "AN/FPS-85". US Air Force Fact Sheet. United States Dept. of Defense. Retrieved May 19, 2017.
  12. "Part 97 - Amateur Radio". ARRL. Archived from the original on 2012-10-09. Retrieved 2012-09-21.
  13. Archived 2016-12-22 at the Wayback Machine FCC Part 97 Amateur Radio Service - Rule 97.215, Telecommand of model craft, section (c).
  14. FCC Web Documents citing 15.219 Archived 2011-11-06 at the Wayback Machine .
  15. "Radiant Flux of a Magnitude +3.5 Star". Archived from the original on 2012-06-30. Retrieved 2009-07-22.
  16. 1 2 Davis, Gary (1988). The Sound Reinforcement Handbook. Yamaha. p. 22. ISBN   0881889008.
  17. Chinn, H. A.; D. K. Gannett; R. M. Moris (January 1940). "A New Standard Volume Indicator and Reference Level" (PDF). Proceedings of the Institute of Radio Engineers. 28 (1): 1–17. doi:10.1109/JRPROC.1940.228815. S2CID   15458694. Archived (PDF) from the original on 2012-02-13. Retrieved 2012-08-04.
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.