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{{short description|Logarithmic unit expressing the ratio of a physical quantity}} {{Short description|Logarithmic unit expressing the ratio of physical quantities}}
{{About|the logarithmic unit|use of this unit in ] measurements|Sound pressure level|other uses}} {{About|the logarithmic unit|use of this unit in ] measurements|Sound pressure level|other uses}}
{{Use dmy dates|date=February 2014}} {{Use dmy dates|date=February 2014}}
{{Infobox unit
| name = decibel
| image =
| caption =
| standard = ]
| quantity =
| symbol = dB
| symbol2 =
| namedafter = ]
| units1 = bel
| inunits1 = {{sfrac|10}} bel
}}


The '''decibel''' (symbol: '''dB''') is a relative ] equal to one tenth of a '''bel''' ('''B'''). It expresses the ratio of two values of a ] on a ]. Two signals whose ] differ by one decibel have a power ratio of 10<sup>1/10</sup> (approximately {{val|1.26}}) or root-power ratio of 10<sup>{{frac|20}}</sup> (approximately {{val|1.12}}).<ref>{{cite book |author-last=Mark |author-first=James E. |title=Physical Properties of Polymers Handbook |publisher=Springer |date=2007 |page=1025 |bibcode=2007ppph.book.....M |quote= the decibel represents a reduction in power of 1.258 times }}</ref><ref>{{cite book |author-last=Yost |author-first=William |title=Fundamentals of Hearing: An Introduction |url=https://archive.org/details/fundamentalsofhe00yost |url-access=registration |publisher=Holt, Rinehart and Winston |edition=Second |date=1985 |page= |isbn=978-0-12-772690-8 |quote= a pressure ratio of 1.122 equals + 1.0 dB }}</ref> The '''decibel''' (symbol: '''dB''') is a relative ] equal to one tenth of a '''bel''' ('''B'''). It expresses the ratio of two values of a ] on a ]. Two signals whose ] differ by one decibel have a power ratio of 10<sup>1/10</sup> (approximately {{val|1.26}}) or root-power ratio of 10<sup>1/20</sup> (approximately {{val|1.12}}).<ref name="auto">{{cite book |author-last=Mark |author-first=James E. |title=Physical Properties of Polymers Handbook |publisher=Springer |date=2007 |page=1025 |bibcode=2007ppph.book.....M |quote= the decibel represents a reduction in power of 1.258 times }}</ref><ref name="auto1">{{cite book |author-last=Yost |author-first=William |title=Fundamentals of Hearing: An Introduction |url=https://archive.org/details/fundamentalsofhe00yost |url-access=registration |publisher=Holt, Rinehart and Winston |edition=Second |date=1985 |page= |isbn=978-0-12-772690-8 |quote= a pressure ratio of 1.122 equals + 1.0 dB }}</ref>


The unit expresses a relative change or an absolute value. In the latter case, the numeric value expresses the ratio of a value to a fixed reference value; when used in this way, the unit symbol is often suffixed with letter codes that indicate the reference value. For example, for the reference value of 1&nbsp;], a common suffix is "]" (e.g., "20&nbsp;dBV").<ref name="clqgmk"/><ref> {{Webarchive|url=https://web.archive.org/web/20160603203340/http://physics.nist.gov/cuu/pdf/sp811.pdf |date=2016-06-03 }}.</ref> The unit fundamentally expresses a relative change but may also be used to express an absolute value as the ratio of a value to a fixed reference value; when used in this way, the unit symbol is often suffixed with letter codes that indicate the reference value. For example, for the reference value of 1&nbsp;], a common suffix is "]" (e.g., "20&nbsp;dBV").<ref name="clqgmk"/><ref> {{Webarchive|url=https://web.archive.org/web/20160603203340/http://physics.nist.gov/cuu/pdf/sp811.pdf |date=2016-06-03 }}</ref>


Two principal types of scaling of the decibel are in common use. When expressing a power ratio, it is defined as ten times the ].<ref>{{cite book |title=IEEE Standard 100: a dictionary of IEEE standards and terms |edition=7th |publisher=The Institute of Electrical and Electronics Engineering |location=New York |year=2000 |isbn=978-0-7381-2601-2 |page=288}}</ref> That is, a change in ''power'' by a factor of 10 corresponds to a 10&nbsp;dB change in level. When expressing root-power quantities, a change in ''amplitude'' by a factor of 10 corresponds to a 20&nbsp;dB change in level. The decibel scales differ by a factor of two, so that the related power and root-power levels change by the same value in linear systems, where power is proportional to the square of amplitude. Two principal types of scaling of the decibel are in common use. When expressing a power ratio, it is defined as ten times the ].<ref>{{cite book |title=IEEE Standard 100: a dictionary of IEEE standards and terms |edition=7th |publisher=The Institute of Electrical and Electronics Engineering |location=New York |year=2000 |isbn=978-0-7381-2601-2 |page=288}}</ref> That is, a change in ''power'' by a factor of 10 corresponds to a 10&nbsp;dB change in level. When expressing root-power quantities, a change in ] by a factor of 10 corresponds to a 20&nbsp;dB change in level. The decibel scales differ by a factor of two, so that the related power and root-power levels change by the same value in linear systems, where power is proportional to the square of amplitude.


The definition of the decibel originated in the measurement of transmission loss and power in ] of the early 20th century in the ] in the United States. The '''bel''' was named in honor of ], but the bel is seldom used. Instead, the decibel is used for a wide variety of measurements in science and ], most prominently in ], ], and ]. In electronics, the ]s of amplifiers, ] of signals, and ]s are often expressed in decibels. The definition of the decibel originated in the measurement of transmission loss and power in ] of the early 20th century in the ] in the United States. The bel was named in honor of ], but the bel is seldom used. Instead, the decibel is used for a wide variety of measurements in science and ], most prominently for ] in ], in ] and ]. In electronics, the ]s of amplifiers, ] of signals, and ]s are often expressed in decibels.

{| class="wikitable" style="width:0; font-size:85%; float: right; margin-left:1em"
== History ==
The decibel originates from methods used to quantify signal loss in telegraph and telephone circuits. Until the mid-1920s, the unit for loss was ''miles of standard cable'' (MSC). 1&nbsp;MSC corresponded to the loss of power over one ] (approximately 1.6&nbsp;km) of standard telephone cable at a frequency of {{val|5000}}&nbsp;]s per second (795.8&nbsp;Hz), and matched closely the smallest attenuation detectable to a listener. A standard telephone cable was "a cable having uniformly distributed resistance of 88&nbsp;ohms per loop-mile and uniformly distributed ] ] of 0.054&nbsp;]s per mile" (approximately corresponding to 19&nbsp;] wire).<ref>{{cite book |last=Johnson |first=Kenneth Simonds |title=Transmission Circuits for Telephonic Communication: Methods of analysis and design |date=1944 |publisher=] |location=New York |page=10}}</ref>

In 1924, ] received a favorable response to a new unit definition among members of the International Advisory Committee on Long Distance Telephony in Europe and replaced the MSC with the ''Transmission Unit'' (TU). 1&nbsp;TU was defined such that the number of TUs was ten times the base-10 logarithm of the ratio of measured power to a reference power.<ref>{{cite book |title=Sound system engineering |edition=2nd |author-first1=Don |author-last1=Davis |author-first2=Carolyn |author-last2=Davis |publisher=] |date=1997 |isbn=978-0-240-80305-0 |page=35 |url={{Google books|plainurl=yes|id=9mAUp5IC5AMC|page=35}}}}</ref>
The definition was conveniently chosen such that 1&nbsp;TU approximated 1&nbsp;MSC; specifically, 1&nbsp;MSC was 1.056&nbsp;TU. In 1928, the Bell system renamed the TU into the decibel,<ref>{{cite journal |journal=Bell Laboratories Record |title='TU' becomes 'Decibel' |author-first=R. V. L. |author-last=Hartley |author-link=R. V. L. Hartley |volume=7 |issue=4 |publisher=AT&T |pages=137–139 |date=December 1928 |url={{Google books|plainurl=yes|id=h1ciAQAAIAAJ}}}}</ref> being one tenth of a newly defined unit for the base-10 logarithm of the power ratio. It was named the ''bel'', in honor of the telecommunications pioneer ].<ref>{{Cite journal |author-last=Martin |author-first=W. H. |date=January 1929 |title=DeciBel—The New Name for the Transmission Unit |journal=] |volume=8 |issue=1}}</ref>
The bel is seldom used, as the decibel was the proposed working unit.<ref>{{Google books |id=EaVSbjsaBfMC |page=276 |title=100 Years of Telephone Switching}}, Robert J. Chapuis, Amos E. Joel, 2003</ref>

The naming and early definition of the decibel is described in the ] Standard's Yearbook of 1931:<ref>{{Cite journal |title=Standards for Transmission of Speech |journal=Standards Yearbook |volume=119 |author-first=William H. |author-last=Harrison |date=1931 |publisher=National Bureau of Standards, U. S. Govt. Printing Office}}</ref>

{{blockquote |
Since the earliest days of the telephone, the need for a unit in which to measure the transmission efficiency of telephone facilities has been recognized. The introduction of cable in 1896 afforded a stable basis for a convenient unit and the "mile of standard" cable came into general use shortly thereafter. This unit was employed up to 1923 when a new unit was adopted as being more suitable for modern telephone work. The new transmission unit is widely used among the foreign telephone organizations and recently it was termed the "decibel" at the suggestion of the International Advisory Committee on Long Distance Telephony.

The decibel may be defined by the statement that two amounts of power differ by 1 decibel when they are in the ratio of 10<sup>0.1</sup> and any two amounts of power differ by ''N'' decibels when they are in the ratio of 10<sup>''N''(0.1)</sup>. The number of transmission units expressing the ratio of any two powers is therefore ten times the common logarithm of that ratio. This method of designating the gain or loss of power in telephone circuits permits direct addition or subtraction of the units expressing the efficiency of different parts of the circuit&nbsp;...}}

{{anchor|Logit}}In 1954, J. W. Horton argued that the use of the decibel as a unit for quantities other than transmission loss led to confusion, and suggested the name ''logit'' for "standard magnitudes which combine by multiplication", to contrast with the name ''unit'' for "standard magnitudes which combine by addition".<ref>{{cite journal |first=J. W. |last=Horton |title=The bewildering decibel |journal=Electrical Engineering |volume=73 |issue=6 |pages=550–555 |year=1954|doi=10.1109/EE.1954.6438830 |s2cid=51654766 }}
</ref>{{clarify|date=March 2018}}

In April&nbsp;2003, the ] (CIPM) considered a recommendation for the inclusion of the decibel in the ] (SI), but decided against the proposal.<ref>{{cite web |url=http://www.bipm.org/utils/common/pdf/CC/CCU/CCU16.pdf |archive-url=https://web.archive.org/web/20141006105908/http://www.bipm.org/utils/common/pdf/CC/CCU/CCU16.pdf |archive-date=2014-10-06 |url-status=live |publisher=Consultative Committee for Units |title=Meeting minutes |at=Section 3}}</ref> However, the decibel is recognized by other international bodies such as the ] (IEC) and ] (ISO).<ref name="IEC60027-3">{{cite web |url=http://webstore.iec.ch/webstore/webstore.nsf/artnum/028981 |title=Letter symbols to be used in electrical technology |at=Part 3: Logarithmic and related quantities, and their units |id=IEC&nbsp;60027-3, Ed.&nbsp;3.0 |publisher=International Electrotechnical Commission |date=19 July 2002}}</ref> The IEC permits the use of the decibel with root-power quantities as well as power and this recommendation is followed by many national standards bodies, such as ], which justifies the use of the decibel for voltage ratios.<ref name="NIST2008"/> In spite of their widespread use, ] (such as in ] or dBV) are not recognized by the IEC or ISO.

== Definition ==

{| class="wikitable floatright" style="width:0; font-size:85%; margin-left:1em"
|- |-
! scope="col" style="text-align:right;" | dB ! scope="col" style="text-align:right;" | dB
Line 17: Line 51:
|- |-
| style="text-align:right; border:none;" | 100 | style="text-align:right; border:none;" | 100
| style="text-align:right; border:none; padding-right:0" | {{space|em}}{{gaps|10|000|000|000}} || style="border:none;" | | style="text-align:right; border:none; padding-right:0" | {{gaps|10|000|000|000}} || style="border:none;" |
| style="text-align:right; border:none; padding-right:0" | {{gaps|100|000}} || style="border:none;" | | style="text-align:right; border:none; padding-right:0" | {{gaps|100|000}} || style="border:none;" |
|- |-
Line 77: Line 111:
|- |-
| style="text-align:right; border:none;" | −3 | style="text-align:right; border:none;" | −3
| style="text-align:right; border:none; padding-right:0" | 0 || style="border:none; padding-left:0;" | .501 ≈ {{frac|2}} | style="text-align:right; border:none; padding-right:0" | 0 || style="border:none; padding-left:0;" | .501 ≈ {{sfrac|2}}
| style="text-align:right; border:none; padding-right:0" | 0 || style="border:none; padding-left:0;" | .708 ≈ {{sqrt|{{frac|2}}}} | style="text-align:right; border:none; padding-right:0" | 0 || style="border:none; padding-left:0;" | .708 ≈ {{sqrt|{{sfrac|2}}}}
|- |-
| style="text-align:right; border:none;" | −6 | style="text-align:right; border:none;" | −6
| style="text-align:right; border:none; padding-right:0" | 0 || style="border:none; padding-left:0;" | .251 ≈ {{frac|4}} | style="text-align:right; border:none; padding-right:0" | 0 || style="border:none; padding-left:0;" | .251 ≈ {{sfrac|4}}
| style="text-align:right; border:none; padding-right:0" | 0 || style="border:none; padding-left:0;" | .501 ≈ {{frac|2}} | style="text-align:right; border:none; padding-right:0" | 0 || style="border:none; padding-left:0;" | .501 ≈ {{sfrac|2}}
|- |-
| style="text-align:right; border:none;" | −10 | style="text-align:right; border:none;" | −10
Line 124: Line 158:
| style="text-align:right; border:none; padding-right:0" | 0 || style="border:none; padding-left:0;" | {{gaps|.000|01}} | style="text-align:right; border:none; padding-right:0" | 0 || style="border:none; padding-left:0;" | {{gaps|.000|01}}
|- |-
| colspan="5" style="text-align:left; background:#f8f8ff;" | An example scale showing power ratios ''x'', amplitude ratios {{sqrt|''x''}}, and dB equivalents 10&nbsp;log<sub>10</sub>&nbsp;''x''. | colspan="5" style="text-align:left; background:#f8f8ff;" | An example scale showing power ratios ''x'', amplitude ratios {{sqrt|''x''}}, and dB equivalents 10&nbsp;log<sub>10</sub>&nbsp;''x''
|} |}


=={{anchor|MSC|TU|bel}}History==
The decibel originates from methods used to quantify signal loss in telegraph and telephone circuits. Until the mid-1920s, the unit for loss was ''Miles of Standard Cable'' (MSC). 1&nbsp;MSC corresponded to the loss of power over one ] (approximately 1.6&nbsp;km) of standard telephone cable at a frequency of {{val|5000}}&nbsp;]s per second (795.8&nbsp;Hz), and matched closely the smallest attenuation detectable to a listener. A standard telephone cable was "a cable having uniformly distributed resistance of 88&nbsp;ohms per loop-mile and uniformly distributed ] ] of 0.054&nbsp;]s per mile" (approximately corresponding to 19&nbsp;] wire).<ref>{{cite book |last=Johnson |first=Kenneth Simonds |title=Transmission Circuits for Telephonic Communication: Methods of analysis and design |date=1944 |publisher=] |location=New York |page=10}}</ref>


In 1924, ] received favorable response to a new unit definition among members of the International Advisory Committee on Long Distance Telephony in Europe and replaced the MSC with the ''Transmission Unit'' (TU). 1&nbsp;TU was defined such that the number of TUs was ten times the base-10 logarithm of the ratio of measured power to a reference power.<ref>{{cite book |title=Sound system engineering |edition=2nd |author-first1=Don |author-last1=Davis |author-first2=Carolyn |author-last2=Davis |publisher=] |date=1997 |isbn=978-0-240-80305-0 |page=35 |url={{Google books|plainurl=yes|id=9mAUp5IC5AMC|page=35}}}}</ref>
The definition was conveniently chosen such that 1&nbsp;TU approximated 1&nbsp;MSC; specifically, 1&nbsp;MSC was 1.056&nbsp;TU. In 1928, the Bell system renamed the TU into the decibel,<ref>{{cite journal |journal=Bell Laboratories Record |title='TU' becomes 'Decibel' |author-first=R. V. L. |author-last=Hartley |author-link=R. V. L. Hartley |volume=7 |issue=4 |publisher=AT&T |pages=137–139 |date=December 1928 |url={{Google books|plainurl=yes|id=h1ciAQAAIAAJ}}}}</ref> being one tenth of a newly defined unit for the base-10 logarithm of the power ratio. It was named the ''bel'', in honor of the telecommunications pioneer ].<ref>{{Cite journal |author-last=Martin |author-first=W. H. |date=January 1929 |title=DeciBel—The New Name for the Transmission Unit |journal=] |volume=8 |issue=1}}</ref>
The bel is seldom used, as the decibel was the proposed working unit.<ref>{{Google books |id=EaVSbjsaBfMC |page=276 |title=100 Years of Telephone Switching}}, Robert J. Chapuis, Amos E. Joel, 2003</ref>

The naming and early definition of the decibel is described in the ] Standard's Yearbook of 1931:<ref>{{Cite journal |title=Standards for Transmission of Speech |journal=Standards Yearbook |volume=119 |author-first=William H. |author-last=Harrison |date=1931 |publisher=National Bureau of Standards, U. S. Govt. Printing Office}}</ref>

{{quotation |
Since the earliest days of the telephone, the need for a unit in which to measure the transmission efficiency of telephone facilities has been recognized. The introduction of cable in 1896 afforded a stable basis for a convenient unit and the "mile of standard" cable came into general use shortly thereafter. This unit was employed up to 1923 when a new unit was adopted as being more suitable for modern telephone work. The new transmission unit is widely used among the foreign telephone organizations and recently it was termed the "decibel" at the suggestion of the International Advisory Committee on Long Distance Telephony.

The decibel may be defined by the statement that two amounts of power differ by 1 decibel when they are in the ratio of 10<sup>0.1</sup> and any two amounts of power differ by ''N'' decibels when they are in the ratio of 10<sup>''N''(0.1)</sup>. The number of transmission units expressing the ratio of any two powers is therefore ten times the common logarithm of that ratio. This method of designating the gain or loss of power in telephone circuits permits direct addition or subtraction of the units expressing the efficiency of different parts of the circuit&nbsp;...}}

{{anchor|Logit}}In 1954, J. W. Horton argued that the use of the decibel as a unit for quantities other than transmission loss led to confusion, and suggested the name ''logit'' for "standard magnitudes which combine by multiplication", to contrast with the name ''unit'' for "standard magnitudes which combine by addition".<ref>{{cite journal |first=J. W. |last=Horton |title=The bewildering decibel |journal=Electrical Engineering |volume=73 |issue=6 |pages=550–555 |year=1954|doi=10.1109/EE.1954.6438830 |s2cid=51654766 }}
</ref>{{clarify|date=March 2018}}

In April&nbsp;2003, the ] (CIPM) considered a recommendation for the inclusion of the decibel in the ] (SI), but decided against the proposal.<ref>{{cite web |url=http://www.bipm.org/utils/common/pdf/CC/CCU/CCU16.pdf |publisher=Consultative Committee for Units |title=Meeting minutes |at=Section 3}}</ref> However, the decibel is recognized by other international bodies such as the ] (IEC) and ] (ISO).<ref name="IEC60027-3">{{cite web |url=http://webstore.iec.ch/webstore/webstore.nsf/artnum/028981 |title=Letter symbols to be used in electrical technology |at=Part 3: Logarithmic and related quantities, and their units |id=IEC&nbsp;60027-3, Ed.&nbsp;3.0 |publisher=International Electrotechnical Commission |date=19 July 2002}}</ref> The IEC permits the use of the decibel with root-power quantities as well as power and this recommendation is followed by many national standards bodies, such as ], which justifies the use of the decibel for voltage ratios.<ref name="NIST2008"/> In spite of their widespread use, ] (such as in ] or dBV) are not recognized by the IEC or ISO.

==Definition==
ISO 80000-3 describes definitions for quantities and units of space and time.


The IEC Standard ] defines the following quantities. The decibel (dB) is one-tenth of a bel: {{nowrap|1=1 dB = 0.1 B}}. The bel (B) is {{1/2}}&nbsp;ln(10) ]s: {{nowrap|1=1 B = {{1/2}} ln(10) Np}}. The neper is the change in the ] of a root-power quantity when the root-power quantity changes by a factor of ], that is {{nowrap|1=1 Np = ln(e) = 1}}, thereby relating all of the units as nondimensional natural log of root-power-quantity ratios, {{nowrap|1=1 dB = 0.115&nbsp;13… Np = 0.115&nbsp;13…}}. Finally, the level of a quantity is the logarithm of the ratio of the value of that quantity to a reference value of the same kind of quantity. The IEC Standard ] defines the following quantities. The decibel (dB) is one-tenth of a bel: {{nowrap|1=1 dB = 0.1 B}}. The bel (B) is {{1/2}}&nbsp;ln(10) ]s: {{nowrap|1=1 B = {{1/2}} ln(10) Np}}. The neper is the change in the ] of a ] when the root-power quantity changes by a factor of ], that is {{nowrap|1=1 Np = ln(e) = 1}}, thereby relating all of the units as nondimensional ] of root-power-quantity ratios, {{val|1|u=dB}} =&nbsp;{{val|0.11513|end=...|u=Np}} =&nbsp;{{val|0.11513|end=...}}. Finally, the level of a quantity is the logarithm of the ratio of the value of that quantity to a reference value of the same kind of quantity.


Therefore, the bel represents the logarithm of a ratio between two power quantities of 10:1, or the logarithm of a ratio between two root-power quantities of {{radic|10}}:1.<ref>{{cite book |title=International Standard CEI-IEC 27-3 |chapter=Letter symbols to be used in electrical technology |at=Part 3: Logarithmic quantities and units |publisher=International Electrotechnical Commission}}</ref> Therefore, the bel represents the logarithm of a ratio between two power quantities of 10:1, or the logarithm of a ratio between two root-power quantities of {{radic|10}}:1.<ref>{{cite book |title=International Standard CEI-IEC 27-3 |chapter=Letter symbols to be used in electrical technology |at=Part 3: Logarithmic quantities and units |publisher=International Electrotechnical Commission}}</ref>


Two signals whose levels differ by one decibel have a power ratio of 10<sup>1/10</sup>, which is approximately {{val|1.25893}}, and an amplitude (root-power quantity) ratio of 10<sup>{{frac|20}}</sup> ({{val|1.12202}}).<ref>{{cite book |author-last=Mark |author-first=James E. |title=Physical Properties of Polymers Handbook |publisher=Springer |date=2007 |page=1025 |bibcode=2007ppph.book.....M |quote= the decibel represents a reduction in power of 1.258 times }}</ref><ref>{{cite book |author-last=Yost |author-first=William |title=Fundamentals of Hearing: An Introduction |url=https://archive.org/details/fundamentalsofhe00yost |url-access=registration |publisher=Holt, Rinehart and Winston |edition=Second |date=1985 |page= |isbn=978-0-12-772690-8 |quote= a pressure ratio of 1.122 equals + 1.0 dB }}</ref> Two signals whose levels differ by one decibel have a power ratio of 10<sup>1/10</sup>, which is approximately {{val|1.25893}}, and an amplitude (root-power quantity) ratio of 10<sup>1/20</sup> ({{val|1.12202}}).<ref name="auto"/><ref name="auto1"/>


The bel is rarely used either without a prefix or with ] other than '']''; it is preferred, for example, to use ''hundredths of a decibel'' rather than ''millibels''. Thus, five one-thousandths of a bel would normally be written 0.05&nbsp;dB, and not 5&nbsp;mB.<ref>Fedor Mitschke, ''Fiber Optics: Physics and Technology'', Springer, 2010 {{ISBN|3642037038}}.</ref> The bel is rarely used either without a prefix or with ] other than '']''; it is customary, for example, to use ''hundredths of a decibel'' rather than ''millibels''. Thus, five one-thousandths of a bel would normally be written 0.05&nbsp;dB, and not 5&nbsp;mB.<ref>Fedor Mitschke, ''Fiber Optics: Physics and Technology'', Springer, 2010 {{ISBN|3642037038}}.</ref>


The method of expressing a ratio as a level in decibels depends on whether the measured property is a ''power quantity'' or a ''root-power quantity''; see '']'' for details. The method of expressing a ratio as a level in decibels depends on whether the measured property is a ''power quantity'' or a ''root-power quantity''; see '']'' for details.


===Power quantities=== === Power quantities ===
When referring to measurements of '']'' quantities, a ratio can be expressed as a ] in decibels by evaluating ten times the ] of the ratio of the measured quantity to reference value. Thus, the ratio of ''P'' (measured power) to ''P''<sub>0</sub> (reference power) is represented by ''L''<sub>''P''</sub>, that ratio expressed in decibels,<ref>{{Cite book |title=Microwave Engineering |author-first=David M. |author-last=Pozar |edition=3rd |publisher=Wiley |date=2005 |author-link=David M. Pozar |isbn=978-0-471-44878-5 |page=63}}</ref> which is calculated using the formula:<ref>IEC 60027-3:2002</ref> When referring to measurements of '']'' quantities, a ratio can be expressed as a ] in decibels by evaluating ten times the ] of the ratio of the measured quantity to reference value. Thus, the ratio of ''P'' (measured power) to ''P''<sub>0</sub> (reference power) is represented by ''L''<sub>''P''</sub>, that ratio expressed in decibels,<ref>{{Cite book |title=Microwave Engineering |author-first=David M. |author-last=Pozar |edition=3rd |publisher=Wiley |date=2005 |author-link=David M. Pozar |isbn=978-0-471-44878-5 |page=63}}</ref> which is calculated using the formula:<ref>IEC 60027-3:2002</ref>
: <math>

L_P = \frac{1}{2} \ln\!\left(\frac{P}{P_0}\right)\,\text{Np} = 10 \log_{10}\!\left(\frac{P}{P_0}\right)\,\text{dB}
:<math>
L_P = \frac{1}{2} \ln\!\left(\frac{P}{P_0}\right)\,\text{Np} = 10 \log_{10}\!\left(\frac{P}{P_0}\right)\,\text{dB}.
</math> </math>


The base-10 logarithm of the ratio of the two power quantities is the number of bels. The number of decibels is ten times the number of bels (equivalently, a decibel is one-tenth of a bel). ''P'' and ''P''<sub>0</sub> must measure the same type of quantity, and have the same units before calculating the ratio. If {{nowrap|1=''P'' = ''P''<sub>0</sub>}} in the above equation, then ''L''<sub>''P''</sub> = 0. If ''P'' is greater than ''P''<sub>0</sub> then ''L''<sub>''P''</sub> is positive; if ''P'' is less than ''P''<sub>0</sub> then ''L''<sub>''P''</sub> is negative. The base-10 logarithm of the ratio of the two power quantities is the number of bels. The number of decibels is ten times the number of bels (equivalently, a decibel is one-tenth of a bel). ''P'' and ''P''<sub>0</sub> must measure the same type of quantity, and have the same units before calculating the ratio. If {{nowrap|1=''P'' = ''P''<sub>0</sub>}} in the above equation, then ''L''<sub>''P''</sub> = 0. If ''P'' is greater than ''P''<sub>0</sub> then ''L''<sub>''P''</sub> is positive; if ''P'' is less than ''P''<sub>0</sub> then ''L''<sub>''P''</sub> is negative.


Rearranging the above equation gives the following formula for ''P'' in terms of ''P''<sub>0</sub> and ''L''<sub>''P''</sub>: Rearranging the above equation gives the following formula for ''P'' in terms of ''P''<sub>0</sub> and ''L''<sub>''P''</sub> :
:<math> : <math>
P = 10^\frac{L_P}{10\,\text{dB}} P_0. P = 10^\frac{L_P}{10\,\text{dB}} P_0
</math> </math>


Line 176: Line 189:
{{main|Power, root-power, and field quantities}} {{main|Power, root-power, and field quantities}}
When referring to measurements of root-power quantities, it is usual to consider the ratio of the squares of ''F'' (measured) and ''F''<sub>0</sub> (reference). This is because the definitions were originally formulated to give the same value for relative ratios for both power and root-power quantities. Thus, the following definition is used: When referring to measurements of root-power quantities, it is usual to consider the ratio of the squares of ''F'' (measured) and ''F''<sub>0</sub> (reference). This is because the definitions were originally formulated to give the same value for relative ratios for both power and root-power quantities. Thus, the following definition is used:
:<math> : <math>
L_F = \ln\!\left(\frac{F}{F_0}\right)\,\text{Np} = 10 \log_{10}\!\left(\frac{F^2}{F_0^2}\right)\,\text{dB} = 20 \log_{10} \left(\frac{F}{F_0}\right)\,\text{dB}. L_F = \ln\!\left(\frac{F}{F_0}\right)\,\text{Np} = 10 \log_{10}\!\left(\frac{F^2}{F_0^2}\right)\,\text{dB} = 20 \log_{10} \left(\frac{F}{F_0}\right)\,\text{dB}
</math> </math>


The formula may be rearranged to give The formula may be rearranged to give
:<math> : <math>
F = 10^\frac{L_F}{20\,\text{dB}} F_0. F = 10^\frac{L_F}{20\,\text{dB}} F_0
</math> </math>


Similarly, in ], dissipated power is typically proportional to the square of ] or ] when the ] is constant. Taking voltage as an example, this leads to the equation for power gain level ''L''<sub>''G''</sub>: Similarly, in ], dissipated power is typically proportional to the square of ] or ] when the ] is constant. Taking voltage as an example, this leads to the equation for power gain level ''L''<sub>''G''</sub>:
:<math> : <math>
L_G = 20 \log_{10}\!\left (\frac{V_\text{out}}{V_\text{in}}\right)\,\text{dB}, L_G = 20 \log_{10}\!\left (\frac{V_\text{out}}{V_\text{in}}\right)\,\text{dB}
</math> </math>
where ''V''<sub>out</sub> is the ] (rms) output voltage, ''V''<sub>in</sub> is the rms input voltage. A similar formula holds for current. where ''V''<sub>out</sub> is the ] (rms) output voltage, ''V''<sub>in</sub> is the rms input voltage. A similar formula holds for current.
Line 196: Line 209:
Although power and root-power quantities are different quantities, their respective levels are historically measured in the same units, typically decibels. A factor of 2 is introduced to make ''changes'' in the respective levels match under restricted conditions such as when the medium is linear and the ''same'' waveform is under consideration with changes in amplitude, or the medium impedance is linear and independent of both frequency and time. This relies on the relationship Although power and root-power quantities are different quantities, their respective levels are historically measured in the same units, typically decibels. A factor of 2 is introduced to make ''changes'' in the respective levels match under restricted conditions such as when the medium is linear and the ''same'' waveform is under consideration with changes in amplitude, or the medium impedance is linear and independent of both frequency and time. This relies on the relationship
:<math> \frac{P(t)}{P_0} = \left(\frac{F(t)}{F_0}\right)^2 </math> :<math> \frac{P(t)}{P_0} = \left(\frac{F(t)}{F_0}\right)^2 </math>
holding.<ref>{{citation |author=I M Mills |author2=B N Taylor |author3=A J Thor |title=Definitions of the units radian, neper, bel and decibel |year=2001 |journal=Metrologia |volume=38 |page=353 |number=4 |doi=10.1088/0026-1394/38/4/8|bibcode=2001Metro..38..353M }}</ref> In a nonlinear system, this relationship does not hold by the definition of linearity. However, even in a ] in which the power quantity is the product of two linearly related quantities (e.g. ] and ]), if the ] is frequency- or time-dependent, this relationship does not hold in general, for example if the energy spectrum of the waveform changes. holding.<ref>{{citation |author=I M Mills |author2=B N Taylor |author3=A J Thor |title=Definitions of the units radian, neper, bel and decibel |year=2001 |journal=Metrologia |volume=38 |page=353 |number=4 |doi=10.1088/0026-1394/38/4/8|bibcode=2001Metro..38..353M |s2cid=250827251 }}</ref> In a nonlinear system, this relationship does not hold by the definition of linearity. However, even in a ] in which the power quantity is the product of two linearly related quantities (e.g. ] and ]), if the ] is frequency- or time-dependent, this relationship does not hold in general, for example if the energy spectrum of the waveform changes.


For differences in level, the required relationship is relaxed from that above to one of proportionality (i.e., the reference quantities ''P''{{sub|0}} and ''F''{{sub|0}} need not be related), or equivalently, For differences in level, the required relationship is relaxed from that above to one of proportionality (i.e., the reference quantities ''P''{{sub|0}} and ''F''{{sub|0}} need not be related), or equivalently,
:<math> \frac{P_2}{P_1} = \left(\frac{F_2}{F_1}\right)^2 </math> : <math> \frac{P_2}{P_1} = \left(\frac{F_2}{F_1}\right)^2 </math>
must hold to allow the power level difference to be equal to the root-power level difference from power ''P''{{sub|1}} and ''F''{{sub|1}} to ''P''{{sub|2}} and ''F''{{sub|2}}. An example might be an amplifier with unity voltage gain independent of load and frequency driving a load with a frequency-dependent impedance: the relative voltage gain of the amplifier is always 0&nbsp;dB, but the power gain depends on the changing spectral composition of the waveform being amplified. Frequency-dependent impedances may be analyzed by considering the quantities ] and the associated root-power quantities via the ], which allows elimination of the frequency dependence in the analysis by analyzing the system at each frequency independently. must hold to allow the power level difference to be equal to the root-power level difference from power ''P''{{sub|1}} and ''F''{{sub|1}} to ''P''{{sub|2}} and ''F''{{sub|2}}. An example might be an amplifier with unity voltage gain independent of load and frequency driving a load with a frequency-dependent impedance: the relative voltage gain of the amplifier is always 0&nbsp;dB, but the power gain depends on the changing spectral composition of the waveform being amplified. Frequency-dependent impedances may be analyzed by considering the quantities ] and the associated root-power quantities via the ], which allows elimination of the frequency dependence in the analysis by analyzing the system at each frequency independently.


===Conversions=== === Conversions ===
Since logarithm differences measured in these units often represent power ratios and root-power ratios, values for both are shown below. The bel is traditionally used as a unit of logarithmic power ratio, while the neper is used for logarithmic root-power (amplitude) ratio. Since logarithm differences measured in these units often represent power ratios and root-power ratios, values for both are shown below. The bel is traditionally used as a unit of logarithmic power ratio, while the neper is used for logarithmic root-power (amplitude) ratio.


Line 209: Line 222:
!Unit !! In decibels !! In bels !! In ]s !! Power ratio !! Root-power ratio !Unit !! In decibels !! In bels !! In ]s !! Power ratio !! Root-power ratio
|- |-
| 1&nbsp;dB || 1&nbsp;dB || 0.1 B || {{val|0.11513}}&nbsp;Np || 10<sup>{{frac|10}}</sup> ≈ {{val|1.25893}} || 10<sup>{{frac|20}}</sup> ≈ {{val|1.12202}} | 1&nbsp;dB || 1&nbsp;dB || 0.1 B || {{val|0.11513}}&nbsp;Np || 10<sup>1/10</sup> ≈ {{val|1.25893}} || 10<sup>1/20</sup> ≈ {{val|1.12202}}
|- |-
| 1 Np || {{val|8.68589}}&nbsp;dB || {{val|0.868589}}&nbsp;B || 1 Np || e<sup>2</sup> ≈ {{val|7.38906}} || ] ≈ {{val|2.71828}} | 1 Np || {{val|8.68589}}&nbsp;dB || {{val|0.868589}}&nbsp;B || 1 Np || e<sup>2</sup> ≈ {{val|7.38906}} || ] ≈ {{val|2.71828}}
|- |-
| 1 B || 10&nbsp;dB || 1 B || 1.151&nbsp;3 Np || 10 || 10<sup>{{frac|2}}</sup> ≈ 3.162&nbsp;28 | 1 B || 10&nbsp;dB || 1 B || 1.151&nbsp;3 Np || 10 || 10<sup>1/2</sup> ≈ 3.162&nbsp;28
|} |}


===Examples=== === Examples ===
The unit dBW is often used to denote a ratio for which the reference is 1&nbsp;W, and similarly dBm for a {{nowrap|1 mW}} reference point. The unit dBW is often used to denote a ratio for which the reference is 1&nbsp;W, and similarly dBm for a {{nowrap|1 mW}} reference point.
* Calculating the ratio in decibels of {{nowrap|1 kW}} (one kilowatt, or {{val|1000}} watts) to {{nowrap|1 W}} yields: * Calculating the ratio in decibels of {{nowrap|1 kW}} (one kilowatt, or {{val|1000}} watts) to {{nowrap|1 W}} yields: <math display="block">
L_G = 10 \log_{10} \left(\frac{1\,000\,\text{W}}{1\,\text{W}}\right)\,\text{dB} = 30\,\text{dB}
::<math>
L_G = 10 \log_{10} \left(\frac{1\,000\,\text{W}}{1\,\text{W}}\right)\,\text{dB} = 30\,\text{dB}.
</math> </math>
* The ratio in decibels of {{nowrap|1={{radic|1&nbsp;000}} V ≈ 31.62 V}} to {{nowrap|1 V}} is * The ratio in decibels of {{nowrap|1={{radic|1000}} V ≈ 31.62 V}} to {{nowrap|1 V}} is: <math display="block">
L_G = 20 \log_{10} \left(\frac{31.62\,\text{V}}{1\,\text{V}}\right)\,\text{dB} = 30\,\text{dB}
::<math>
L_G = 20 \log_{10} \left(\frac{31.62\,\text{V}}{1\,\text{V}}\right)\,\text{dB} = 30\,\text{dB}.
</math> </math>
{{nowrap|1=(31.62 V / 1 V)<sup>2</sup> ≈ 1 kW / 1 W}}, illustrating the consequence from the definitions above that ''L''<sub>''G''</sub> has the same value, 30&nbsp;dB, regardless of whether it is obtained from powers or from amplitudes, provided that in the specific system being considered power ratios are equal to amplitude ratios squared. {{nowrap|1=(31.62 V / 1 V)<sup>2</sup> ≈ 1 kW / 1 W}}, illustrating the consequence from the definitions above that ''L''<sub>''G''</sub> has the same value, 30&nbsp;dB, regardless of whether it is obtained from powers or from amplitudes, provided that in the specific system being considered power ratios are equal to amplitude ratios squared.
* The ratio in decibels of {{nowrap|10 W}} to {{nowrap|1 mW}} (one milliwatt) is obtained with the formula * The ratio in decibels of {{nowrap|10 W}} to {{nowrap|1 mW}} (one milliwatt) is obtained with the formula: <math display="block">
L_G = 10 \log_{10} \left(\frac{10\text{W}}{0.001\text{W}}\right)\,\text{dB} = 40\,\text{dB}
::<math>
L_G = 10 \log_{10} \left(\frac{10\text{ W}}{0.001\text{ W}}\right) \text{ dB} = 40 \text{ dB}.
</math> </math>
* The power ratio corresponding to a {{nowrap|3 dB}} change in level is given by * The power ratio corresponding to a {{nowrap|3 dB}} change in level is given by: <math display="block">
G = 10^\frac{3}{10} \times 1 = 1.995\,26\ldots \approx 2
::<math>
G = 10^\frac{3}{10} \times 1 = 1.995\,26\ldots \approx 2.
</math> </math>


A change in power ratio by a factor of 10 corresponds to a change in level of {{nowrap|10 dB}}. A change in power ratio by a factor of 2 or {{frac|2}} is approximately a ]. More precisely, the change is ±{{val|3.0103}}&nbsp;dB, but this is almost universally rounded to 3&nbsp;dB in technical writing. This implies an increase in voltage by a factor of {{nowrap|{{sqrt|2}} ≈}} {{val|1.4142}}. Likewise, a doubling or halving of the voltage, and quadrupling or quartering of the power, is commonly described as 6&nbsp;dB rather than ±{{val|6.0206}}&nbsp;dB. A change in power ratio by a factor of 10 corresponds to a change in level of {{nowrap|10 dB}}. A change in power ratio by a factor of 2 or {{sfrac|2}} is approximately a ]. More precisely, the change is ±{{val|3.0103}}&nbsp;dB, but this is almost universally rounded to 3&nbsp;dB in technical writing. This implies an increase in voltage by a factor of {{nowrap|{{sqrt|2}} ≈}} {{val|1.4142}}. Likewise, a doubling or halving of the voltage, corresponding to a quadrupling or quartering of the power, is commonly described as 6&nbsp;dB rather than ±{{val|6.0206}}&nbsp;dB.


Should it be necessary to make the distinction, the number of decibels is written with additional ]. 3.000&nbsp;dB corresponds to a power ratio of 10<sup>{{frac|3|10}}</sup>, or {{val|1.9953}}, about 0.24% different from exactly 2, and a voltage ratio of {{val|1.4125}}, 0.12% different from exactly {{sqrt|2}}. Similarly, an increase of 6.000&nbsp;dB corresponds to the power ratio is {{nowrap|10<sup>{{frac|6|10}}</sup> ≈}} {{val|3.9811}}, about 0.5% different from 4. Should it be necessary to make the distinction, the number of decibels is written with additional ]. 3.000&nbsp;dB corresponds to a power ratio of 10<sup>3/10</sup>, or {{val|1.9953}}, about 0.24% different from exactly 2, and a voltage ratio of {{val|1.4125}}, 0.12% different from exactly {{sqrt|2}}. Similarly, an increase of 6.000&nbsp;dB corresponds to the power ratio is {{nowrap|10<sup>6/10</sup> ≈}} {{val|3.9811}}, about 0.5% different from 4.


==Properties== == Properties ==
The decibel is useful for representing large ratios and for simplifying representation of multiplicative effects, such as attenuation from multiple sources along a signal chain. Its application in systems with additive effects is less intuitive, such as in the combined sound pressure level of two machines operating together. Care is also necessary with decibels directly in fractions and with the units of multiplicative operations. The decibel is useful for representing large ratios and for simplifying representation of multiplicative effects, such as attenuation from multiple sources along a signal chain. Its application in systems with additive effects is less intuitive, such as in the combined sound pressure level of two machines operating together. Care is also necessary with decibels directly in fractions and with the units of multiplicative operations.


===Reporting large ratios=== === Reporting large ratios ===
The ] nature of the decibel means that a very large range of ratios can be represented by a convenient number, in a manner similar to ]. This allows one to clearly visualize huge changes of some quantity. See '']'' and '']''. For example, 120&nbsp;dB SPL may be clearer than "a trillion times more intense than the threshold of hearing".{{fact|date=February 2021}} The ] nature of the decibel means that a very large range of ratios can be represented by a convenient number, in a manner similar to ]. This allows one to clearly visualize huge changes of some quantity. See '']'' and '']''. For example, 120&nbsp;dB SPL may be clearer than "a trillion times more intense than the threshold of hearing".{{citation needed|date=February 2021}}


===Representation of multiplication operations=== === Representation of multiplication operations ===
Level values in decibels can be added instead of multiplying the underlying power values, which means that the overall gain of a multi-component system, such as a series of ] stages, can be calculated by summing the gains in decibels of the individual components, rather than multiply the amplification factors; that is, {{nowrap|log(''A'' × ''B'' × ''C'') }}= log(''A'') + log(''B'') + log(''C''). Practically, this means that, armed only with the knowledge that 1&nbsp;dB is a power gain of approximately 26%, 3&nbsp;dB is approximately 2× power gain, and 10&nbsp;dB is 10× power gain, it is possible to determine the power ratio of a system from the gain in dB with only simple addition and multiplication. For example: Level values in decibels can be added instead of multiplying the underlying power values, which means that the overall gain of a multi-component system, such as a series of ] stages, can be calculated by summing the gains in decibels of the individual components, rather than multiply the amplification factors; that is, {{nowrap|log(''A'' × ''B'' × ''C'') }}= log(''A'') + log(''B'') + log(''C''). Practically, this means that, armed only with the knowledge that 1&nbsp;dB is a power gain of approximately 26%, 3&nbsp;dB is approximately 2× power gain, and 10&nbsp;dB is 10× power gain, it is possible to determine the power ratio of a system from the gain in dB with only simple addition and multiplication. For example:
*:A system consists of 3 amplifiers in series, with gains (ratio of power out to in) of 10&nbsp;dB, 8&nbsp;dB, and 7&nbsp;dB respectively, for a total gain of 25&nbsp;dB. Broken into combinations of 10, 3, and 1&nbsp;dB, this is: *A system consists of 3 amplifiers in series, with gains (ratio of power out to in) of 10&nbsp;dB, 8&nbsp;dB, and 7&nbsp;dB respectively, for a total gain of 25&nbsp;dB. Broken into combinations of 10, 3, and 1&nbsp;dB, this is: {{block indent | em = 1.5 | text =
*:: 25&nbsp;dB = 10&nbsp;dB + 10&nbsp;dB + 3&nbsp;dB + 1&nbsp;dB + 1&nbsp;dB 25&nbsp;dB = 10&nbsp;dB + 10&nbsp;dB + 3&nbsp;dB + 1&nbsp;dB + 1&nbsp;dB
*:With an input of 1 watt, the output is approximately }} With an input of 1 watt, the output is approximately {{block indent | em = 1.5 | text =
*:: 1&nbsp;W × 10 × 10 × 2 × 1.26 × 1.26 ≈ 317.5&nbsp;W 1&nbsp;W × 10 × 10 × 2 × 1.26 × 1.26 ≈ 317.5&nbsp;W
*: Calculated precisely, the output is 1&nbsp;W × 10<sup>{{frac|25|10}}</sup> ≈ 316.2&nbsp;W. The approximate value has an error of only +0.4% with respect to the actual value, which is negligible given the precision of the values supplied and the accuracy of most measurement instrumentation. }} Calculated precisely, the output is 1&nbsp;W × 10<sup>25/10</sup> ≈ 316.2&nbsp;W. The approximate value has an error of only +0.4% with respect to the actual value, which is negligible given the precision of the values supplied and the accuracy of most measurement instrumentation.


However, according to its critics, the decibel creates confusion, obscures reasoning, is more related to the era of ]s than to modern digital processing, and is cumbersome and difficult to interpret.<ref name="Hickling">R. Hickling (1999), Noise Control and SI Units, J Acoust Soc Am 106, 3048</ref><ref>Hickling, R. (2006). Decibels and octaves, who needs them?. Journal of sound and vibration, 291(3-5), 1202-1207.</ref> However, according to its critics, the decibel creates confusion, obscures reasoning, is more related to the era of ]s than to modern digital processing, and is cumbersome and difficult to interpret.<ref name="Hickling">R. Hickling (1999), Noise Control and SI Units, J Acoust Soc Am 106, 3048</ref><ref>Hickling, R. (2006). Decibels and octaves, who needs them?. Journal of sound and vibration, 291(3-5), 1202-1207.</ref>
Quantities in decibels are not necessarily ],<ref>Nicholas P. Cheremisinoff (1996) Noise Control in Industry: A Practical Guide, Elsevier, 203 pp, p. </ref><ref>Andrew Clennel Palmer (2008), Dimensional Analysis and Intelligent Experimentation, World Scientific, 154 pp, p.13</ref> thus being "of unacceptable form for use in ]".<ref>J. C. Gibbings, ''Dimensional Analysis'', , Springer, 2011 {{ISBN|1849963177}}.</ref> Quantities in decibels are not necessarily ],<ref>Nicholas P. Cheremisinoff (1996) Noise Control in Industry: A Practical Guide, Elsevier, 203 pp, p. </ref><ref>Andrew Clennel Palmer (2008), Dimensional Analysis and Intelligent Experimentation, World Scientific, 154 pp, p.13</ref> thus being "of unacceptable form for use in ]".<ref>J. C. Gibbings, ''Dimensional Analysis'', , Springer, 2011 {{ISBN|1849963177}}.</ref>
Thus, units require special care in decibel operations. Take, for example, ] ''C/N<sub>0</sub>'' (in hertz), involving carrier power ''C'' (in watts) and noise ] ''N<sub>0</sub>'' (in W/Hz). Expressed in decibels, this ratio would be a subtraction (''C/N<sub>0</sub>'')<sub>dB</sub> = ''C''<sub>dB</sub> - ''N''<sub>0dB</sub>. However, the linear-scale units still simplify in the implied fraction, so that the results would be expressed in dB-Hz. Thus, units require special care in decibel operations. Take, for example, ] ''C''/''N''<sub>0</sub> (in hertz), involving carrier power ''C'' (in watts) and noise ] ''N''<sub>0</sub> (in W/Hz). Expressed in decibels, this ratio would be a subtraction (''C''/''N''<sub>0</sub>)<sub>dB</sub> = ''C''<sub>dB</sub> ''N''<sub>0&nbsp;dB</sub>. However, the linear-scale units still simplify in the implied fraction, so that the results would be expressed in dB-Hz.


==={{anchor|Addition}}Representation of addition operations=== === Representation of addition operations <span class="anchor" id="Addition"></span> ===
{{Details|Logarithmic addition}} {{Further|Logarithmic addition}}
According to Mitschke,<ref>{{cite book |title=Fiber Optics |publisher=Springer |date=2010}}</ref> "The advantage of using a logarithmic measure is that in a transmission chain, there are many elements concatenated, and each has its own gain or attenuation. To obtain the total, addition of decibel values is much more convenient than multiplication of the individual factors." However, for the same reason that humans excel at additive operation over multiplication, decibels are awkward in inherently additive operations:<ref>R. J. Peters, ''Acoustics and Noise Control'', Routledge, 12 November 2013, 400 pages, p.&nbsp;13</ref><blockquote>if two machines each individually produce a ] level of, say, 90&nbsp;dB at a certain point, then when both are operating together we should expect the combined sound pressure level to increase to 93&nbsp;dB, but certainly not to 180&nbsp;dB!; suppose that the noise from a machine is measured (including the contribution of background noise) and found to be 87&nbsp;dBA but when the machine is switched off the background noise alone is measured as 83&nbsp;dBA. the machine noise may be obtained by 'subtracting' the 83&nbsp;dBA background noise from the combined level of 87&nbsp;dBA; i.e., 84.8&nbsp;dBA.; in order to find a representative value of the sound level in a room a number of measurements are taken at different positions within the room, and an average value is calculated. Compare the logarithmic and arithmetic averages of 70&nbsp;dB and 90&nbsp;dB: ] = 87&nbsp;dB; ] = 80&nbsp;dB.</blockquote> According to Mitschke,<ref>{{cite book |title=Fiber Optics |publisher=Springer |date=2010}}</ref> "The advantage of using a logarithmic measure is that in a transmission chain, there are many elements concatenated, and each has its own gain or attenuation. To obtain the total, addition of decibel values is much more convenient than multiplication of the individual factors." However, for the same reason that humans excel at additive operation over multiplication, decibels are awkward in inherently additive operations:<ref>R. J. Peters, ''Acoustics and Noise Control'', Routledge, 12 November 2013, 400 pages, p.&nbsp;13</ref><blockquote>if two machines each individually produce a ] level of, say, 90&nbsp;dB at a certain point, then when both are operating together we should expect the combined sound pressure level to increase to 93&nbsp;dB, but certainly not to 180&nbsp;dB!; suppose that the noise from a machine is measured (including the contribution of background noise) and found to be 87&nbsp;dBA but when the machine is switched off the background noise alone is measured as 83&nbsp;dBA. the machine noise may be obtained by 'subtracting' the 83&nbsp;dBA background noise from the combined level of 87&nbsp;dBA; i.e., 84.8&nbsp;dBA.; in order to find a representative value of the sound level in a room a number of measurements are taken at different positions within the room, and an average value is calculated. Compare the logarithmic and arithmetic averages of 70&nbsp;dB and 90&nbsp;dB: ] = 87&nbsp;dB; ] = 80&nbsp;dB.</blockquote>


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&= 10 \cdot \log_{10}\left(\bigl(10^{70/10} + 10^{90/10}\bigr)/2\right)\,\text{dBA} \\ &= 10 \cdot \log_{10}\left(\bigl(10^{70/10} + 10^{90/10}\bigr)/2\right)\,\text{dBA} \\
&= 10 \cdot \left(\log_{10}\bigl(10^{70/10} + 10^{90/10}\bigr) - \log_{10} 2\right)\,\text{dBA} &= 10 \cdot \left(\log_{10}\bigl(10^{70/10} + 10^{90/10}\bigr) - \log_{10} 2\right)\,\text{dBA}
\approx 87\,\text{dBA}. \approx 87\,\text{dBA}
\end{align} \end{align}
</math> </math>
Note that the ] is obtained from the logarithmic sum by subtracting <math>10\log_{10} 2</math>, since logarithmic division is linear subtraction. The ] is obtained from the logarithmic sum by subtracting <math>10\log_{10} 2</math>, since logarithmic division is linear subtraction.


===Fractions=== === Fractions ===
] constants, in topics such as ] communication and ] ], are often expressed as a ] or ratio to distance of transmission. In this case, dB/m represents decibel per meter, dB/mi represents decibel per mile, for example. These quantities are to be manipulated obeying the rules of ], e.g., a 100-meter run with a 3.5&nbsp;dB/km fiber yields a loss of 0.35&nbsp;dB = 3.5&nbsp;dB/km × 0.1&nbsp;km. ] constants, in topics such as ] communication and ] ], are often expressed as a ] or ratio to distance of transmission. In this case, dB/m represents decibel per meter, dB/mi represents decibel per mile, for example. These quantities are to be manipulated obeying the rules of ], e.g., a 100-meter run with a 3.5&nbsp;dB/km fiber yields a loss of 0.35&nbsp;dB = 3.5&nbsp;dB/km × 0.1&nbsp;km.


==Uses== == Uses ==


===Perception=== === Perception ===
The human perception of the intensity of sound and light more nearly approximates the logarithm of intensity rather than a linear relationship (see ]), making the dB scale a useful measure.<ref>{{Google books |id=1SMXAAAAQBAJ |page=268 |title=Sensation and Perception}}</ref><ref>{{Google books |id=BggrpTek5kAC |page=SA19-PA9 |title=Introduction to Understandable Physics, Volume 2}}</ref><ref>{{Google books |id=ukvei0wge_8C |page=356 |title=Visual Perception: Physiology, Psychology, and Ecology}}</ref><ref>{{Google books |id=-QIfF9q6Q_EC |page=407 |title=Exercise Psychology}}</ref><ref>{{Google books |id=oUNfSjS11ggC |page=83 |title=Foundations of Perception}}</ref><ref>{{Google books |id=w888Mw1dh_EC |page=304 |title=Fitting The Task To The Human}}</ref> The human perception of the intensity of sound and light more nearly approximates the logarithm of intensity rather than a linear relationship (see ]), making the dB scale a useful measure.<ref>{{Google books |id=1SMXAAAAQBAJ |page=268 |title=Sensation and Perception}}</ref><ref>{{Google books |id=BggrpTek5kAC |page=SA19-PA9 |title=Introduction to Understandable Physics, Volume 2}}</ref><ref>{{Google books |id=ukvei0wge_8C |page=356 |title=Visual Perception: Physiology, Psychology, and Ecology}}</ref><ref>{{Google books |id=-QIfF9q6Q_EC |page=407 |title=Exercise Psychology}}</ref><ref>{{Google books |id=oUNfSjS11ggC |page=83 |title=Foundations of Perception}}</ref><ref>{{Google books |id=w888Mw1dh_EC |page=304 |title=Fitting The Task To The Human}}</ref>


===Acoustics=== === Acoustics ===
The decibel is commonly used in ] as a unit of ] or ]. The reference pressure for sound in air is set at the typical threshold of perception of an average human and there are ]. As sound pressure is a root-power quantity, the appropriate version of the unit definition is used:
]
: <math>
The decibel is commonly used in ] as a unit of ]. The reference pressure for sound in air is set at the typical threshold of perception of an average human and there are ]. As sound pressure is a root-power quantity, the appropriate version of the unit definition is used:
:<math>
L_p = 20 \log_{10}\!\left(\frac{p_{\text{rms}}}{p_{\text{ref}}}\right)\,\text{dB}, L_p = 20 \log_{10}\!\left(\frac{p_{\text{rms}}}{p_{\text{ref}}}\right)\,\text{dB},
</math> </math>
where ''p''<sub>rms</sub> is the ] of the measured sound pressure and ''p''<sub>ref</sub> is the standard reference sound pressure of 20 ]s in air or 1 micropascal in water.<ref>ISO 1683:2015</ref> where ''p''<sub>rms</sub> is the ] of the measured sound pressure and ''p''<sub>ref</sub> is the standard reference sound pressure of 20 ]s in air or 1 micropascal in water.<ref>ISO 1683:2015</ref>


Use of the decibel in underwater acoustics leads to confusion, in part because of this difference in reference value.<ref>C. S. Clay (1999), Underwater sound transmission and SI units, J Acoust Soc Am 106, 3047</ref> Use of the decibel in underwater acoustics leads to confusion, in part because of this difference in reference value.<ref>Chapman, D. M., & Ellis, D. D. (1998). Elusive decibel: Thoughts on sonars and marine mammals. Canadian Acoustics, 26(2), 29-31.</ref><ref>C. S. Clay (1999), Underwater sound transmission and SI units, J Acoust Soc Am 106, 3047</ref>


] is proportional to the square of sound pressure. Therefore, the sound intensity level can also be defined as:
The human ear has a large ] in sound reception. The ratio of the sound intensity that causes permanent damage during short exposure to that of the quietest sound that the ear can hear is equal to or greater than 1 trillion (10<sup>12</sup>).<ref>{{cite web |title=Loud Noise Can Cause Hearing Loss |url=https://www.cdc.gov/nceh/hearing_loss/what_noises_cause_hearing_loss.html |website=cdc.gov |date=7 October 2019 |publisher=Centers for Disease Control and Prevention |access-date=30 July 2020}}</ref> Such large measurement ranges are conveniently expressed in ]: the base-10 logarithm of 10<sup>12</sup> is 12, which is expressed as a sound pressure level of 120&nbsp;dB re 20&nbsp;].
: <math>
L_p = 10 \log_{10}\!\left(\frac{I}{I_{\text{ref}}}\right)\,\text{dB},
</math>


The human ear has a large ] in sound reception. The ratio of the sound intensity that causes permanent damage during short exposure to that of the quietest sound that the ear can hear is equal to or greater than 1 trillion (10<sup>12</sup>).<ref>{{cite web |title=Loud Noise Can Cause Hearing Loss |url=https://www.cdc.gov/nceh/hearing_loss/what_noises_cause_hearing_loss.html |website=cdc.gov |date=7 October 2019 |publisher=Centers for Disease Control and Prevention |access-date=30 July 2020}}</ref> Such large measurement ranges are conveniently expressed in ]: the base-10 logarithm of 10<sup>12</sup> is 12, which is expressed as a sound intensity level of 120&nbsp;dB re 1 pW/m<sup>2</sup>. The reference values of I and p in air have been chosen such that this corresponds approximately to a sound pressure level of 120&nbsp;dB re 20&nbsp;].
Since the human ear is not equally sensitive to all sound frequencies, the acoustic power spectrum is modified by ] (] being the most common standard) to get the weighted acoustic power before converting to a sound level or noise level in decibels.<ref name=Pierre>{{citation |url= http://storeycountywindfarms.org/ref3_Impact_Sound_Pressure.pdf |author=Richard L. St. Pierre, Jr. and Daniel J. Maguire |title=The Impact of A-weighting Sound Pressure Level Measurements during the Evaluation of Noise Exposure |date=July 2004 |access-date=2011-09-13}}</ref>

Since the human ear is not equally sensitive to all sound frequencies, the acoustic power spectrum is modified by ] (] being the most common standard) to get the weighted acoustic power before converting to a sound level or noise level in decibels.<ref name=Pierre>{{citation |url= http://storeycountywindfarms.org/ref3_Impact_Sound_Pressure.pdf |archive-url=https://web.archive.org/web/20151222153918/http://storeycountywindfarms.org/ref3_Impact_Sound_Pressure.pdf |archive-date=2015-12-22 |url-status=live |author=Richard L. St. Pierre, Jr. and Daniel J. Maguire |title=The Impact of A-weighting Sound Pressure Level Measurements during the Evaluation of Noise Exposure |date=July 2004 |access-date=2011-09-13}}</ref>


{{further|Sound pressure#Examples of sound pressure}} {{further|Sound pressure#Examples of sound pressure}}


===Telephony=== === Telephony ===
The decibel is used in ] and ]. Similarly to the use in acoustics, a frequency weighted power is often used. For audio noise measurements in electrical circuits, the weightings are called ]s.<ref name="Reeve">{{Cite book |last=Reeve |first= William D. |year= 1992 |title= Subscriber Loop Signaling and Transmission Handbook – Analog |edition= 1st |publisher=IEEE Press |isbn= 0-87942-274-2}}</ref> The decibel is used in ] and ]. Similarly to the use in acoustics, a frequency weighted power is often used. For audio noise measurements in electrical circuits, the weightings are called ]s.<ref name="Reeve">{{Cite book |last=Reeve |first= William D. |year= 1992 |title= Subscriber Loop Signaling and Transmission Handbook – Analog |edition= 1st |publisher=IEEE Press |isbn= 0-87942-274-2}}</ref>


===Electronics=== === Electronics ===
In electronics, the decibel is often used to express power or amplitude ratios (as for ]) in preference to ] ratios or ]ages. One advantage is that the total decibel gain of a series of components (such as ]s and ]) can be calculated simply by summing the decibel gains of the individual components. Similarly, in telecommunications, decibels denote signal gain or loss from a transmitter to a receiver through some medium (], ], ], ], etc.) using a ]. In electronics, the decibel is often used to express power or amplitude ratios (as for ]) in preference to ] ratios or ]ages. One advantage is that the total decibel gain of a series of components (such as ]s and ]) can be calculated simply by summing the decibel gains of the individual components. Similarly, in telecommunications, decibels denote signal gain or loss from a transmitter to a receiver through some medium (], ], ], ], etc.) using a ].


The decibel unit can also be combined with a reference level, often indicated via a suffix, to create an absolute unit of electric power. For example, it can be combined with "m" for "milliwatt" to produce the "]". A power level of 0 dBm corresponds to one milliwatt, and 1 dBm is one decibel greater (about 1.259&nbsp;mW). The decibel unit can also be combined with a reference level, often indicated via a suffix, to create an absolute unit of electric power. For example, it can be combined with "m" for "milliwatt" to produce the "]". A power level of 0 dBm corresponds to one milliwatt, and 1 dBm is one decibel greater (about 1.259&nbsp;mW).


In professional audio specifications, a popular unit is the ]. This is relative to the ] voltage which delivers 1&nbsp;mW (0&nbsp;dBm) into a 600-ohm resistor, or {{sqrt|1&nbsp;mW&times;600&nbsp;Ω }}≈ 0.775&nbsp;V<sub>RMS</sub>. When used in a 600-ohm circuit (historically, the standard reference impedance in telephone circuits), dBu and dBm are ]. In professional audio specifications, a popular unit is the ]. This is relative to the ] voltage which delivers 1&nbsp;mW (0&nbsp;dBm) into a 600-ohm resistor, or {{sqrt|1&nbsp;mW &times; 600&nbsp;Ω }}≈ 0.775&nbsp;V<sub>RMS</sub>. When used in a 600-ohm circuit (historically, the standard reference impedance in telephone circuits), dBu and dBm are ].


===Optics=== === Optics ===
In an ], if a known amount of ] power, in ] (referenced to 1&nbsp;mW), is launched into a ], 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 addition and subtraction of decibel quantities.<ref> In an ], if a known amount of ] power, in ] (referenced to 1&nbsp;mW), is launched into a ], 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 addition and subtraction of decibel quantities.<ref>
{{cite book {{cite book
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| url = {{Google books |plainurl=yes |id=B810SYIAa4IC |page=123 }} | url = {{Google books |plainurl=yes |id=B810SYIAa4IC |page=123 }}
}}</ref> }}</ref>


In spectrometry and optics, the ] used to measure ] is equivalent to −1&nbsp;B. In spectrometry and optics, the ] used to measure ] is equivalent to −1&nbsp;B.


===Video and digital imaging=== === Video and digital imaging ===
In connection with video and digital ]s, decibels generally represent ratios of video voltages or digitized light intensities, using 20&nbsp;log of the ratio, even when the represented intensity (optical power) is directly proportional to the voltage generated by the sensor, not to its square, as in a ] where response voltage is linear in intensity.<ref> In connection with video and digital ]s, decibels generally represent ratios of video voltages or digitized light intensities, using 20&nbsp;log of the ratio, even when the represented intensity (optical power) is directly proportional to the voltage generated by the sensor, not to its square, as in a ] where response voltage is linear in intensity.<ref>
{{Cite book {{cite book
| title = The Colour Image Processing Handbook | title = The Colour Image Processing Handbook
| author = Stephen J. Sangwine and Robin E. N. Horne | author = Stephen J. Sangwine and Robin E. N. Horne
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| url = {{Google books |plainurl=yes |id=oEsZiCt5VOAC |page=127 }} | url = {{Google books |plainurl=yes |id=oEsZiCt5VOAC |page=127 }}
}}</ref> }}</ref>
Thus, a camera ] or ] quoted as 40&nbsp;dB represents a ratio of 100:1 between optical signal intensity and optical-equivalent dark-noise intensity, not a 10,000:1 intensity (power) ratio as 40&nbsp;dB might suggest.<ref> Thus, a camera ] or ] quoted as 40&nbsp;dB represents a ratio of 100:1 between optical signal intensity and optical-equivalent dark-noise intensity, not a 10,000:1 intensity (power) ratio as 40&nbsp;dB might suggest.<ref>
{{cite book {{cite book
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}}</ref> }}</ref>
Sometimes the 20&nbsp;log ratio definition is applied to electron counts or photon counts directly, which are proportional to sensor signal amplitude without the need to consider whether the voltage response to intensity is linear.<ref> Sometimes the 20&nbsp;log ratio definition is applied to electron counts or photon counts directly, which are proportional to sensor signal amplitude without the need to consider whether the voltage response to intensity is linear.<ref>
{{cite book {{cite book
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| chapter-url = {{Google books |plainurl=yes |id=UY6QzgzgieYC |page=79 }} | chapter-url = {{Google books |plainurl=yes |id=UY6QzgzgieYC |page=79 }}
}}</ref> }}</ref>


However, as mentioned above, the 10&nbsp;log intensity convention prevails more generally in physical optics, including fiber optics, so the terminology can become murky between the conventions of digital photographic technology and physics. Most commonly, quantities called "dynamic range" or "signal-to-noise" (of the camera) would be specified in 20&nbsp;log dB, but in related contexts (e.g. attenuation, gain, intensifier SNR, or rejection ratio) the term should be interpreted cautiously, as confusion of the two units can result in very large misunderstandings of the value. However, as mentioned above, the 10&nbsp;log intensity convention prevails more generally in physical optics, including fiber optics, so the terminology can become murky between the conventions of digital photographic technology and physics. Most commonly, quantities called "dynamic range" or "signal-to-noise" (of the camera) would be specified in 20&nbsp;log dB, but in related contexts (e.g. attenuation, gain, intensifier SNR, or rejection ratio) the term should be interpreted cautiously, as confusion of the two units can result in very large misunderstandings of the value.
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Photographers typically use an alternative base-2 log unit, the ], to describe light intensity ratios or dynamic range. Photographers typically use an alternative base-2 log unit, the ], to describe light intensity ratios or dynamic range.


=={{anchor|Suffixes}}Suffixes and reference values== == Suffixes and reference values <span class="anchor" id="Suffixes"></span> ==
Suffixes are commonly attached to the basic dB unit in order to indicate the reference value by which the ratio is calculated. For example, dBm indicates power measurement relative to 1&nbsp;milliwatt. Suffixes are commonly attached to the basic dB unit in order to indicate the reference value by which the ratio is calculated. For example, dBm indicates power measurement relative to 1&nbsp;milliwatt.


In cases where the unit value of the reference is stated, the decibel value is known as "absolute". If the unit value of the reference is not explicitly stated, as in the dB gain of an amplifier, then the decibel value is considered relative. In cases where the unit value of the reference is stated, the decibel value is known as "absolute". If the unit value of the reference is not explicitly stated, as in the dB gain of an amplifier, then the decibel value is considered relative.


This form of attaching suffixes to dB is widespread in practice, albeit being against the rules promulgated by standards bodies (ISO and IEC),<ref name=NIST2008>Thompson, A. and Taylor, B. N. sec 8.7, "Logarithmic quantities and units: level, neper, bel", ''Guide for the Use of the International System of Units (SI) 2008 Edition'', NIST Special Publication 811, 2nd printing (November 2008), SP811 </ref> given the "unacceptability of attaching information to units"{{efn|"When one gives the value of a quantity, it is incorrect to attach letters or other symbols to the unit in order to provide information about the quantity or its conditions of measurement. Instead, the letters or other symbols should be attached to the quantity."{{r|NIST2008|p=16}}}} and the "unacceptability of mixing information with units"{{efn|"When one gives the value of a quantity, any information concerning the quantity or its conditions of measurement must be presented in such a way as not to be associated with the unit. This means that quantities must be defined so that they can be expressed solely in acceptable units..."{{r|NIST2008|p=17}}}}. The ] standard recommends the following format:<ref name="IEC60027-3"/> ''L''<sub>''x''</sub> (re ''x''<sub>ref</sub>) or as ''L''<sub>''x''/''x''<sub>ref</sub></sub>, where ''x'' is the quantity symbol and ''x''<sub>ref</sub> is the value of the reference quantity, e.g., ''L''<sub>''E''</sub>&nbsp;(re&nbsp;1&nbsp;μV/m)&nbsp;=&nbsp;20&nbsp;dB or ''L''<sub>''E''/(1&nbsp;μV/m)</sub>=&nbsp;20&nbsp;dB for the ] ''E'' relative to 1&nbsp;μV/m reference value. This form of attaching suffixes to dB is widespread in practice, albeit being against the rules promulgated by standards bodies (ISO and IEC),<ref name=NIST2008>Thompson, A. and Taylor, B. N. sec 8.7, "Logarithmic quantities and units: level, neper, bel", ''Guide for the Use of the International System of Units (SI) 2008 Edition'', NIST Special Publication 811, 2nd printing (November 2008), SP811 </ref> given the "unacceptability of attaching information to units"{{efn|"When one gives the value of a quantity, it is incorrect to attach letters or other symbols to the unit in order to provide information about the quantity or its conditions of measurement. Instead, the letters or other symbols should be attached to the quantity."{{r|NIST2008|p=16}}}} and the "unacceptability of mixing information with units".{{efn|"When one gives the value of a quantity, any information concerning the quantity or its conditions of measurement must be presented in such a way as not to be associated with the unit. This means that quantities must be defined so that they can be expressed solely in acceptable units..."{{r|NIST2008|p=17}}}} The ] standard recommends the following format:<ref name="IEC60027-3"/> {{nowrap|''L''<sub>''x''</sub> (re ''x''<sub>ref</sub>)}} or as {{nowrap|''L''<sub>''x''/''x''<sub>ref</sub></sub>}}, where ''x'' is the quantity symbol and ''x''<sub>ref</sub> is the value of the reference quantity, e.g., {{nowrap|''L''<sub>''E''</sub> (re 1 μV/m)}}&nbsp;=&nbsp;20&nbsp;dB or {{nowrap|''L''<sub>''E''/(1 μV/m)</sub>}} =&nbsp;20&nbsp;dB for the ] ''E'' relative to 1&nbsp;μV/m reference value.
If the measurement result 20 dB is presented separately, it can be specified using the information in parentheses, which is then part of the surrounding text and not a part of the unit: 20 dB (re: 1&nbsp;μV/m) or 20 dB (1&nbsp;μV/m). If the measurement result 20&nbsp;dB is presented separately, it can be specified using the information in parentheses, which is then part of the surrounding text and not a part of the unit: 20&nbsp;dB (re: 1&nbsp;μV/m) or 20&nbsp;dB (1&nbsp;μV/m).


Outside of documents adhering to SI units, the practice is very common as illustrated by the following examples. There is no general rule, with various discipline-specific practices. Sometimes the suffix is a unit symbol ("W","K","m"), sometimes it is a transliteration of a unit symbol ("uV" instead of μV for microvolt), sometimes it is an acronym for the unit's name ("sm" for square meter, "m" for milliwatt), other times it is a mnemonic for the type of quantity being calculated ("i" for antenna gain with respect to an isotropic antenna, "λ" for anything normalized by the EM wavelength), or otherwise a general attribute or identifier about the nature of the quantity ("A" for ] sound pressure level). The suffix is often connected with a ], as in "dB{{nbhyph}}Hz", or with a space, as in "dB&nbsp;HL", or enclosed in parentheses, as in "dB(sm)", or with no intervening character, as in "dBm" (which is non-compliant with international standards). Outside of documents adhering to SI units, the practice is very common as illustrated by the following examples. There is no general rule, with various discipline-specific practices. Sometimes the suffix is a unit symbol ("W","K","m"), sometimes it is a transliteration of a unit symbol ("uV" instead of μV for microvolt), sometimes it is an acronym for the unit's name ("sm" for square meter, "m" for milliwatt), other times it is a mnemonic for the type of quantity being calculated ("i" for antenna gain with respect to an isotropic antenna, "λ" for anything normalized by the EM wavelength), or otherwise a general attribute or identifier about the nature of the quantity ("A" for ] sound pressure level). The suffix is often connected with a ], as in "dB{{nbhyph}}Hz", or with a space, as in "dB&nbsp;HL", or enclosed in parentheses, as in "dB(sm)", or with no intervening character, as in "dBm" (which is non-compliant with international standards).


== List of suffixes ==
===Voltage===
Since the decibel is defined with respect to power, not amplitude, conversions of voltage ratios to decibels must square the amplitude, or use the factor of 20 instead of 10, as discussed above.


=== Voltage ===
] (the ]) and ] (the power dissipated as ] by the 600&nbsp;Ω ])]]
Since the decibel is defined with respect to '']'', not '']'', conversions of voltage ratios to decibels must square the amplitude, or use the factor of 20 instead of 10, as discussed above.


] (the ]) and ] (the power dissipated as ] by the 600&nbsp;Ω ])]]
;dBV: dB(V<sub>]</sub>)&nbsp;– ]age relative to 1&nbsp;volt, regardless of impedance.<ref name = "clqgmk">{{citation |url=http://designtools.analog.com/dt/dbconvert/dbconvert.html |publisher=Analog Devices |title=Utilities : V<sub>RMS</sub> / dBm / dBu / dBV calculator |access-date=2016-09-16}}</ref> This is used to measure microphone sensitivity, and also to specify the consumer ] of {{nowrap|−10 dBV}}, in order to reduce manufacturing costs relative to equipment using a {{nowrap|+4 dBu}} line-level signal.<ref>{{Cite book|url=https://books.google.com/books?id=TIfOAwAAQBAJ&q=%22%E2%88%9210+dBV%22+%221+kHz%22|title=The Audio Expert: Everything You Need to Know About Audio|last=Winer|first=Ethan|publisher=Focal Press|year=2013|isbn=978-0-240-82100-9|pages=107}}</ref>


; dB{{sub| V}} : dB(V<sub>]</sub>)&nbsp;– ]age relative to 1&nbsp;volt, regardless of impedance.<ref name=clqgmk>{{cite web |title=V<sub>RMS</sub> / dBm / dBu / dBV calculator |department=Utilities |publisher=Analog Devices |url=http://designtools.analog.com/dt/dbconvert/dbconvert.html |via=designtools.analog.com |access-date=2016-09-16}}</ref> This is used to measure microphone sensitivity, and also to specify the consumer ] of {{nowrap|−10 dBV}}, in order to reduce manufacturing costs relative to equipment using a {{nowrap|+4 dBu}} line-level signal.<ref>{{cite book |last=Winer |first=Ethan |year=2013 |title=The Audio Expert: Everything you need to know about audio |publisher=Focal Press |isbn=978-0-240-82100-9 |page= |url=https://books.google.com/books?id=TIfOAwAAQBAJ |via=Google }}</ref>
;dBu or dBv: ] ]age relative to {{nowrap|<math>V = \sqrt{600 \, \Omega \cdot 0.001\,\text{W}} \approx 0.7746\,\text{V}</math>}} (i.e. the voltage that would dissipate 1 mW into a 600&nbsp;Ω load). An ] voltage of 1&nbsp;V therefore corresponds to <math>20\cdot\log_{10}\left ( \frac{1\,V_\text{RMS}}{\sqrt{0.6}\,V} \right )=2.218\,\text{dBu}.</math><ref name="clqgmk" /> Originally dBv, it was changed to dBu to avoid confusion with dBV.<ref>{{cite web|url=http://stason.org/TULARC/entertainment/audio/pro/3-3-What-is-the-difference-between-dBv-dBu-dBV-dBm-dB.html|title=3.3&nbsp;– What is the difference between dBv, dBu, dBV, dBm, dB SPL, and plain old dB? Why not just use regular voltage and power measurements?|first=Stas Bekman: stas (at)|last=stason.org|website=stason.org}}</ref> The "v" comes from "volt", while "u" comes from the volume ''unit'' used in the ].<ref>{{citation |url=https://www.youtube.com/watch?v=b02P4f3CBuM | archive-url=https://ghostarchive.org/varchive/youtube/20211030/b02P4f3CBuM| archive-date=2021-10-30|title=Creation of the dBu standard level reference |author=Rupert Neve |author-link=Rupert Neve}}{{cbignore}}</ref>{{paragraphbreak}}dBu can be used as a measure of voltage, regardless of impedance, but is derived from a 600&nbsp;Ω load dissipating 0&nbsp;dBm (1&nbsp;mW). The reference voltage comes from the computation {{nowrap|<math>V = \sqrt{R \cdot P}</math>}} where <math>R</math> is the resistance and <math>P</math> is the power.{{paragraphbreak}} In ], equipment may be calibrated to indicate a "0" on the VU meters some finite time after a signal has been applied at an amplitude of {{nowrap|+4 dBu}}. Consumer equipment typically uses a lower "nominal" signal level of {{nowrap|−10 dBV}}.<ref>{{cite web|author=deltamedia.com |url=http://www.deltamedia.com/resource/db_or_not_db.html |title=DB or Not DB |publisher=Deltamedia.com |access-date=2013-09-16}}</ref> Therefore, many devices offer dual voltage operation (with different gain or "trim" settings) for interoperability reasons. A switch or adjustment that covers at least the range between {{nowrap|+4 dBu}} and {{nowrap|−10 dBV}} is common in professional equipment.


; dB{{sub| u}} or dB{{sub| v}} : ] ]age relative to {{nowrap|<math>V = \sqrt{600\ \Omega\ \cdot\ 0.001\ \mathsf{W}\;} \approx 0.7746\ \mathsf{V}\ </math>}} (i.e. the voltage that would dissipate 1&nbsp;mW into a 600&nbsp;Ω load). An ] voltage of 1&nbsp;V therefore corresponds to <math>\ 20\cdot\log_{10} \left( \frac{\ 1\ V_\mathsf{RMS}\ }{ \sqrt{0.6\ }\ V} \right) = 2.218\ \mathsf{dB_u} ~.</math><ref name=clqgmk/> Originally dB{{sub| v }}, it was changed to dB{{sub| u}} to avoid confusion with dB{{sub| V}}.<ref>{{cite web |first=Stas |last=Bekman |title=3.3 – What is the difference between dBv, dBu, dBV, dBm, dB&nbsp;SPL, and plain old dB? Why not just use regular voltage and power measurements? |website=stason.org |department=Entertainment audio |series=TULARC |url=http://stason.org/TULARC/entertainment/audio/pro/3-3-What-is-the-difference-between-dBv-dBu-dBV-dBm-dB.html }}</ref> The ''v'' comes from ''volt'', while ''u'' comes from the ] displayed on a ].<ref>{{cite AV media |first=Rupert |last=Neve |author-link=Rupert Neve |date=9 October 2015 |title=Creation of the dB{{sub| u}} standard level reference |medium=video |url=https://www.youtube.com/watch?v=b02P4f3CBuM | archive-url=https://ghostarchive.org/varchive/youtube/20211030/b02P4f3CBuM |archive-date=2021-10-30 }}{{cbignore}}</ref>{{paragraphbreak}}dB{{sub| u}} can be used as a measure of voltage, regardless of impedance, but is derived from a 600&nbsp;Ω load dissipating 0&nbsp;dB{{sub| m}} (1&nbsp;mW). The reference voltage comes from the computation <math>\ 7 \mathsf{V} = \sqrt{R \cdot P\ }\ </math> where <math>\ R\ </math> is the resistance and <math>\ P\ </math> is the power.
;dBm0s

:Defined by Recommendation ITU-R V.574.; dBmV: dB(mV<sub>]</sub>) – ]age relative to 1&nbsp;millivolt across 75&nbsp;Ω.<ref>{{Cite book
: In ], equipment may be calibrated to indicate a "0" on the VU meters some finite time after a signal has been applied at an amplitude of {{nobr|+4 dBu}}. Consumer equipment typically uses a lower "nominal" signal level of {{nobr|−10 dB{{sub| V}} .}}<ref>{{cite web |title=dB or not dB&nbsp;? |website=deltamedia.com |url=http://www.deltamedia.com/resource/db_or_not_db.html |url-status=dead |access-date=2013-09-16 |archive-url=https://web.archive.org/web/20130620064637/http://www.deltamedia.com/resource/db_or_not_db.html |archive-date=20 June 2013 }}</ref> Therefore, many devices offer dual voltage operation (with different gain or "trim" settings) for interoperability reasons. A switch or adjustment that covers at least the range between {{nobr|+4 dB{{sub| u}}}} and {{nobr|−10 dB{{sub| V}}}} is common in professional equipment.

; dB{{sub| m0s}} : Defined by Recommendation ITU-R V.574&nbsp;; dB{{sub| mV}}: dB(mV<sub>RMS</sub>) – ] ]age relative to 1&nbsp;millivolt across 75&nbsp;Ω.<ref>
{{cite book
|title=The IEEE Standard Dictionary of Electrical and Electronics terms |title=The IEEE Standard Dictionary of Electrical and Electronics terms
|edition=6th |edition=6th
|orig-year=1941
|year=1996 |year=1996
|orig-year=1941
|publisher=IEEE
|publisher=]
|isbn=978-1-55937-833-8 |isbn=978-1-55937-833-8
}}
}}</ref> Widely used in ] networks, where the nominal strength of a single TV signal at the receiver terminals is about 0&nbsp;dBmV. Cable TV uses 75&nbsp;Ω coaxial cable, so 0&nbsp;dBmV corresponds to −78.75&nbsp;dBW (−48.75&nbsp;dBm) or approximately 13&nbsp;nW.
</ref> Widely used in ] networks, where the nominal strength of a single TV signal at the receiver terminals is about 0&nbsp;dB{{sub| mV}}. Cable&nbsp;TV uses 75&nbsp;Ω coaxial cable, so 0&nbsp;dB{{sub| mV}} corresponds to −78.75&nbsp;dB{{sub| W}} {{nobr|( −48.75 dB{{sub| m}} )}} or approximately 13&nbsp;nW.


;dBμV or dBuV: dB(μV<sub>]</sub>)&nbsp;– ]age relative to 1&nbsp;microvolt. Widely used in television and aerial amplifier specifications. 60&nbsp;dBμV&nbsp;= 0&nbsp;dBmV. ; dB{{sub| μV}} or dB{{sub| uV}} : dB(μV<sub>]</sub>) – ]age relative to 1&nbsp;microvolt. Widely used in television and aerial amplifier specifications. 60&nbsp;dBμV&nbsp;= 0&nbsp;dB{{sub| mV}}.


===Acoustics=== === Acoustics ===
Probably the most common usage of "decibels" in reference to sound level is dB&nbsp;SPL, ] referenced to the nominal threshold of human hearing:<ref>{{Cite book Probably the most common usage of "decibels" in reference to sound level is dB{{sub| SPL}}, ] referenced to the nominal threshold of human hearing:<ref>
{{cite book
| title = Audio postproduction for digital video | title = Audio postproduction for digital video
| author = Jay Rose | first = Jay | last = Rose
| publisher = Focal Press | publisher = Focal Press
| year = 2002 | year = 2002
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| page = 25 | page = 25
| url = {{Google books |plainurl=yes |id=sUcRegHAXdkC |page=25 }} | url = {{Google books |plainurl=yes |id=sUcRegHAXdkC |page=25 }}
}}</ref> The measures of pressure (a root-power quantity) use the factor of 20, and the measures of power (e.g. dB&nbsp;SIL and dB&nbsp;SWL) use the factor of 10. }}</ref> The measures of pressure (a root-power quantity) use the factor of 20, and the measures of power (e.g. dB{{sub| SIL}} and dB{{sub| SWL}}) use the factor of 10.
;dB&nbsp;SPL: dB&nbsp;SPL (]) – for sound in air and other gases, relative to 20&nbsp;micropascals (μPa), or {{val|2|e=-5|u=Pa}}, approximately the quietest sound a human can hear. For ] and other liquids, a reference pressure of 1&nbsp;μPa is used.<ref>Morfey, C. L. (2001). Dictionary of Acoustics. Academic Press, San Diego.</ref>{{paragraphbreak}} An RMS sound pressure of one pascal corresponds to a level of 94&nbsp;dB&nbsp;SPL. ; dB{{sub| SPL}} : dB{{sub| SPL}} (]) – for sound in air and other gases, relative to 20&nbsp;micropascals (μPa), or {{val|2|e=-5|u=Pa}}, approximately the quietest sound a human can hear. For ] and other liquids, a reference pressure of 1&nbsp;μPa is used.<ref>Morfey, C. L. (2001). Dictionary of Acoustics. Academic Press, San Diego.</ref>{{paragraphbreak}} An RMS sound pressure of one pascal corresponds to a level of 94&nbsp;dB&nbsp;SPL.
;dB&nbsp;SIL: dB ] – relative to 10<sup>−12</sup>&nbsp;W/m<sup>2</sup>, which is roughly the ] in air. ; dB{{sub| SIL}} : dB ] – relative to 10<sup>−12</sup>&nbsp;W/m<sup>2</sup>, which is roughly the ] in air.
;dB&nbsp;SWL: dB ] – relative to 10<sup>−12</sup>&nbsp;W. ; dB{{sub| SWL}} : dB ] – relative to 10<sup>−12</sup>&nbsp;W.
;dBA, dBB, and dBC: These symbols are often used to denote the use of different ]s, used to approximate the human ear's ] to sound, although the measurement is still in dB&nbsp;(SPL). These measurements usually refer to noise and its effects on humans and other animals, and they are widely used in industry while discussing noise control issues, regulations and environmental standards. Other variations that may be seen are dB<sub>A</sub> or ]. According to standards from the International Electro-technical Committee (])<ref>{{cite book |title=IEC 61672-1:2013 Electroacoustics - Sound Level meters - Part 1: Specifications |date=2013 |publisher=International Electrotechnical Committee |location=Geneva}}</ref> and the American National Standards Institute, ],<ref>] , 2.3 Sound Level, p. 2–3.</ref> the preferred usage is to write L<sub>A</sub>&nbsp;= x&nbsp;dB. Nevertheless, the units dBA and dB(A) are still commonly used as a shorthand for A{{nbhyph}}weighted measurements. Compare ], used in telecommunications. ; dB{{sub| A}}, dB{{sub| B}}, and dB{{sub| C}} : These symbols are often used to denote the use of different ]s, used to approximate the human ear's ] to sound, although the measurement is still in dB&nbsp;(SPL). These measurements usually refer to noise and its effects on humans and other animals, and they are widely used in industry while discussing noise control issues, regulations and environmental standards. Other variations that may be seen are dB{{sub| A}} or ]. According to standards from the International Electro-technical Committee (])<ref>{{cite book |title=IEC 61672-1:2013 Electroacoustics - Sound Level meters - Part 1: Specifications |date=2013 |publisher=International Electrotechnical Committee |location=Geneva}}</ref> and the American National Standards Institute, ],<ref>] , 2.3 Sound Level, p. 2–3.</ref> the preferred usage is to write {{nobr| {{mvar|L}}{{sub| A}} {{=}} {{mvar|x}}&nbsp;dB .}} Nevertheless, the units dB{{sub| A}} and dB(A) are still commonly used as a shorthand for A{{nbhyph}}weighted measurements. Compare ], used in telecommunications.
;dB&nbsp;HL: dB hearing level is used in ]s as a measure of hearing loss. The reference level varies with frequency according to a ] as defined in ANSI and other standards, such that the resulting audiogram shows deviation from what is regarded as 'normal' hearing.{{Citation needed|date=March 2008}} ; dB{{sub| HL}} : dB ] is used in ]s as a measure of hearing loss. The reference level varies with frequency according to a ] as defined in ANSI and other standards, such that the resulting audiogram shows deviation from what is regarded as 'normal' hearing.{{Citation needed|date=March 2008}}
;dB&nbsp;Q: sometimes used to denote weighted noise level, commonly using the ]{{Citation needed|date=March 2008}} ; dB{{sub| Q}} : sometimes used to denote weighted noise level, commonly using the ]{{Citation needed|date=March 2008}}
;dBpp: relative to the peak to peak sound pressure.<ref>Zimmer, Walter MX, Mark P. Johnson, Peter T. Madsen, and Peter L. Tyack. "Echolocation clicks of free-ranging Cuvier’s beaked whales (Ziphius cavirostris)." The Journal of the Acoustical Society of America 117, no. 6 (2005): 3919–3927.</ref> ; dB{{sub| pp}} : relative to the peak to peak sound pressure.<ref>{{cite journal |last1=Zimmer |first1=Walter M.X. |first2=Mark P. |last2=Johnson |first3=Peter T. |last3=Madsen |first4=Peter L. |last4=Tyack |year=2005 |title=Echolocation clicks of free-ranging Cuvier's beaked whales (''Ziphius cavirostris'') |journal=] |volume=117 |issue=6 |pages=3919–3927 |doi=10.1121/1.1910225 |pmid=16018493 |bibcode=2005ASAJ..117.3919Z |hdl=1912/2358 |hdl-access=free }}</ref>
;dBG: G{{nbhyph}}weighted spectrum<ref>{{cite web| url = http://oto2.wustl.edu/cochlea/wt4.html| url-status = dead| archive-url = https://web.archive.org/web/20101212221829/http://oto2.wustl.edu/cochlea/wt4.html| archive-date = 12 December 2010| title = Turbine Sound Measurements}}</ref> ; dB{{sub| G}} : G‑weighted spectrum<ref>{{cite web | title = Turbine sound measurements |via=wustl.edu | url = http://oto2.wustl.edu/cochlea/wt4.html | url-status = dead | archive-url = https://web.archive.org/web/20101212221829/http://oto2.wustl.edu/cochlea/wt4.html | archive-date = 12 December 2010 }}</ref>


===Audio electronics=== === Audio electronics ===
See also dBV and dBu above. See also dB{{sub| V}} and dB{{sub| u}} above.


;]: dB(mW) – power relative to 1&nbsp;]. In audio and telephony, dBm is typically referenced relative to a 600&nbsp;Ω impedance,<ref>{{cite book|last=Bigelow|first=Stephen|title=Understanding Telephone Electronics|publisher=Newnes|isbn=978-0750671750|page=|year=2001|url-access=registration|url=https://archive.org/details/isbn_9780750671750/page/16}}</ref> which corresponds to a voltage level of 0.775&nbsp;volts or 775&nbsp;millivolts. ; ] : dB(mW) – power relative to 1&nbsp;]. In audio and telephony, dB{{sub| m}} is typically referenced relative to a 600&nbsp;Ω impedance,<ref>{{cite book|last=Bigelow |first=Stephen |year=2001 |title=Understanding Telephone Electronics |publisher=Newnes Press |place=Boston, MA |isbn=978-0750671750 |page= |url-access=registration |url=https://archive.org/details/isbn_9780750671750/page/16 }}</ref> which corresponds to a voltage level of 0.775&nbsp;volts or 775&nbsp;millivolts.
;]: Power in dBm (described above) measured at a ]. ; ] : Power in dB{{sub| m}} (described above) measured at a ].
;]: dB(]) – the ] of a signal compared with the maximum which a device can handle before ] occurs. Full-scale may be defined as the power level of a full-scale ] or alternatively a full-scale ]. A signal measured with reference to a full-scale sine-wave appears 3&nbsp;dB weaker when referenced to a full-scale square wave, thus: 0&nbsp;dBFS(fullscale sine wave) = −3&nbsp;dBFS(fullscale square wave). ; ] : dB(]) – the ] of a signal compared with the maximum which a device can handle before ] occurs. Full-scale may be defined as the power level of a full-scale ] or alternatively a full-scale ]. A signal measured with reference to a full-scale sine-wave appears 3&nbsp;dB weaker when referenced to a full-scale square wave, thus: 0&nbsp;dBFS(fullscale sine wave) = −3&nbsp;dB{{sub| FS}} (fullscale square wave).
;dBVU: dB volume unit<ref>Tharr, D. (1998). Case Studies: Transient Sounds Through Communication Headsets. Applied Occupational and Environmental Hygiene, 13(10), 691–697.</ref> ; dB{{sub| VU}} : dB ]<ref>{{cite journal |last=Thar |first=D. |year=1998 |title=Case Studies: Transient sounds through communication headsets |journal=Applied Occupational and Environmental Hygiene |volume=13 |issue=10 |pages=691–697 |doi=10.1080/1047322X.1998.10390142 }}</ref>
;dBTP: dB(true peak) – ] of a signal compared with the maximum which a device can handle before clipping occurs.<ref>]</ref> In digital systems, 0&nbsp;dBTP would equal the highest level (number) the processor is capable of representing. Measured values are always negative or zero, since they are less than or equal to full-scale. ; dB{{sub| TP}} : dB(true peak) – ] of a signal compared with the maximum which a device can handle before clipping occurs.<ref>]</ref> In digital systems, 0&nbsp;dB{{sub| TP}} would equal the highest level (number) the processor is capable of representing. Measured values are always negative or zero, since they are less than or equal to full-scale.


===Radar=== === Radar ===
;]: dB(Z)&nbsp;– decibel relative to Z&nbsp;= 1&nbsp;mm<sup>6</sup>⋅m<sup>−3</sup>:<ref>{{cite web |url=https://www.weather.gov/jetstream/glossary_d<!-- Former URL: http://www.srh.noaa.gov/jetstream/append/glossary_d.htm --> |title=Glossary: D's |publisher=National Weather Service |access-date=2013-04-25 |archive-url=https://web.archive.org/web/20190808140856/https://www.weather.gov/jetstream/glossary_d |archive-date=2019-08-08 |url-status=live}}</ref> energy of reflectivity (weather radar), related to the amount of transmitted power returned to the radar receiver. Values above 20&nbsp;dBZ usually indicate falling precipitation.<ref>{{cite web |url=https://www.weather.gov/jetstream/radarfaq#reflcolor |title=RIDGE Radar Frequently Asked Questions |access-date=2019-08-08 |archive-url=https://web.archive.org/web/20190331123302/https://www.weather.gov/jetstream/radarfaq#reflcolor |archive-date=2019-03-31 |url-status=live}}</ref> ; ] : dB(Z) – decibel relative to Z&nbsp;= 1&nbsp;mm{{sup|6 }}⋅m{{sup|−3 }}:<ref>{{cite web |title=Terms starting with&nbsp;'''D''' |department=Glossary |publisher=U.S. ] |website=weather.gov |url=https://www.weather.gov/jetstream/glossary_d<!-- Former URL: http://www.srh.noaa.gov/jetstream/append/glossary_d.htm --> |access-date=2013-04-25 |archive-url=https://web.archive.org/web/20190808140856/https://www.weather.gov/jetstream/glossary_d |archive-date=2019-08-08 |url-status=live}}</ref> energy of reflectivity (weather radar), related to the amount of transmitted power returned to the radar receiver. Values above 20&nbsp;dB{{sub| Z}} usually indicate falling precipitation.<ref>{{cite web |title=Frequently Asked Questions |department=RIDGE Radar |publisher=U.S. ] |website=weather.gov |url=https://www.weather.gov/jetstream/radarfaq#reflcolor |access-date=2019-08-08 |archive-url=https://web.archive.org/web/20190331123302/https://www.weather.gov/jetstream/radarfaq#reflcolor |archive-date=2019-03-31 |url-status=live }}</ref>
;dBsm: dB(m<sup>2</sup>) – decibel relative to one square meter: measure of the ] (RCS) of a target. The power reflected by the target is proportional to its RCS. "Stealth" aircraft and insects have negative RCS measured in dBsm, large flat plates or non-stealthy aircraft have positive values.<ref>{{cite web |url=http://everything2.com/title/dBsm |title=Definition at Everything2 |access-date=2019-08-08 |archive-url=https://web.archive.org/web/20190610170944/https://everything2.com/title/dBsm?%2F |archive-date=10 June 2019 |url-status=live }}</ref> ; dB{{sub| sm}} : dB(m²) – decibel relative to one square meter: measure of the ] (RCS) of a target. The power reflected by the target is proportional to its RCS. "Stealth" aircraft and insects have negative RCS measured in dB{{sub| sm }}, large flat plates or non-stealthy aircraft have positive values.<ref>{{cite web |title=dBsm |department=Definition |website=Everything&nbsp;2 |url=http://everything2.com/title/dBsm |access-date=2019-08-08 |archive-url=https://web.archive.org/web/20190610170944/https://everything2.com/title/dBsm?%2F |archive-date=10 June 2019 |url-status=live }}</ref>


===Radio power, energy, and field strength=== === Radio power, energy, and field strength ===
;]: relative to carrier – in ]s, this indicates the relative levels of noise or sideband power, compared with the carrier power. Compare dBC, used in acoustics. ; ] : relative to carrier – in ], this indicates the relative levels of noise or sideband power, compared with the carrier power. Compare dB{{sub| C}}, used in acoustics.
;dBpp: relative to the maximum value of the peak power. ; dB{{sub| pp}} : relative to the maximum value of the peak power.
;dBJ: energy relative to 1&nbsp;]. 1&nbsp;joule&nbsp;= 1&nbsp;watt second&nbsp;= 1&nbsp;watt per hertz, so ] can be expressed in dBJ. ; dB{{sub| J}} : energy relative to 1&nbsp;]. 1&nbsp;joule&nbsp;= 1&nbsp;watt second&nbsp;= 1&nbsp;watt per hertz, so ] can be expressed in dB{{sub| J }}.
;]: dB(mW) – power relative to 1&nbsp;]. In the radio field, dBm is usually referenced to a 50&nbsp;Ω load, with the resultant voltage being 0.224&nbsp;volts.<ref>{{cite book|last=Carr|first=Joseph|title=RF Components and Circuits|year=2002|publisher=Newnes|isbn=978-0750648448|pages=45–46}}</ref> ; ] : dB(mW) – power relative to 1&nbsp;]. In the radio field, dB{{sub| m}} is usually referenced to a 50&nbsp;Ω load, with the resultant voltage being 0.224&nbsp;volts.<ref>{{cite book |last=Carr |first=Joseph |author-link=Joseph Carr |year=2002 |title=RF Components and Circuits |publisher=Newnes |isbn=978-0750648448 |pages=45–46 }}</ref>
;dBμV/m, dBuV/m, or dBμ:<ref name="dBµ">{{cite web|title=The dBµ vs. dBu Mystery: Signal Strength vs. Field Strength?|url=http://radio-timetraveller.blogspot.com/2015/02/the-db-versus-dbu-mystery-signal.html|website=radio-timetraveller.blogspot.com|date=24 February 2015|access-date=13 October 2016}}</ref> dB(μV/m) – ] relative to 1&nbsp;] per ]. The unit is often used to specify the signal strength of a ] ] at a receiving site (the signal measured ''at the antenna output'' is reported in dBμV). ; dB{{sub| μV/m }}, dB{{sub| uV/m }}, or dB{{sub| μ }} :<ref name="dBμ">{{cite web |title=The dBμ vs. dBu mystery: Signal strength vs. field strength? |date=24 February 2015 |website=Radio Time Traveller (radio-timetraveller.blogspot.com) |type=blog |via=blogspot.com |url=http://radio-timetraveller.blogspot.com/2015/02/the-db-versus-dbu-mystery-signal.html |access-date=13 October 2016 }}</ref> dB(μV/m) – ] relative to 1&nbsp;] per ]. The unit is often used to specify the signal strength of a ] ] at a receiving site (the signal measured ''at the antenna output'' is reported in dBμ{{sub| V}}).
;dBf: dB(fW) – power relative to 1&nbsp;]. ; dB{{sub| f}} : dB(fW) – power relative to 1&nbsp;].
;dBW: dB(W) – power relative to 1&nbsp;]. ; dB{{sub| W}} : dB(W) – power relative to 1&nbsp;].
;dBk: dB(kW) – power relative to 1&nbsp;]. ; dB{{sub| k}} : dB(kW) – power relative to 1&nbsp;].
;dBe: dB electrical. ; dB{{sub| e}} : dB electrical.
;dBo: dB optical. A change of 1&nbsp;dBo in optical power can result in a change of up to 2&nbsp;dBe in electrical signal power in a system that is thermal noise limited.<ref>Chand, N., Magill, P. D., Swaminathan, S. V., & Daugherty, T. H. (1999). Delivery of digital video and other multimedia services (>&nbsp;1&nbsp;Gb/s bandwidth) in passband above the 155&nbsp;Mb/s baseband services on a FTTx full service access network. Journal of lightwave technology, 17(12), 2449–2460.</ref> ; dB{{sub| o}} : dB optical. A change of 1&nbsp;dB{{sub| o}} in optical power can result in a change of up to 2&nbsp;dB{{sub| e}} in electrical signal power in a system that is thermal noise limited.<ref>{{cite journal |last1=Chand |first1=N. |last2=Magill |first2=P.D. |last3=Swaminathan |first3=S.V. |last4=Daugherty |first4=T.H. |year=1999 |title=Delivery of digital video and other multimedia services {{nobr|( > 1 Gb/s}} bandwidth) in passband above the 155&nbsp;Mb/s baseband services on a FTTx full service access network |journal=Journal of Lightwave Technology |volume=17 |issue=12 |pages=2449–2460 |doi=10.1109/50.809663 }}</ref>


===Antenna measurements=== === Antenna measurements ===
;dBi: dB(isotropic) – the forward ] compared with the hypothetical ], which uniformly distributes energy in all directions. ] of the EM field is assumed unless noted otherwise. ; dB{{sub| i}} : dB(isotropic) <span id="dBi_anchor" class="anchor"></span> – the ] of an antenna compared with the gain of a theoretical ], which uniformly distributes energy in all directions. ] of the EM field is assumed unless noted otherwise.
;dBd: dB(dipole) – the forward gain of an ] compared with a half-wave ]. 0&nbsp;dBd&nbsp;= 2.15&nbsp;dBi ; dB{{sub| d}} : dB(dipole) – the ] of an ] compared with the gain a half-wave ]. 0&nbsp;dBd&nbsp;= 2.15&nbsp;dBi
;dBiC: dB(isotropic circular) – the forward gain of an antenna compared to a ] isotropic antenna. There is no fixed conversion rule between dBiC and dBi, as it depends on the receiving antenna and the field polarization. ; dB{{sub| iC}} : dB(isotropic circular) – the gain of an antenna compared to the gain of a theoretical ] isotropic antenna. There is no fixed conversion rule between dB{{sub|iC}} and dB{{sub|i}}, as it depends on the receiving antenna and the field polarization.
;dBq: dB(quarterwave) – the forward gain of an antenna compared to a quarter wavelength whip. Rarely used, except in some marketing material. 0&nbsp;dBq&nbsp;= −0.85&nbsp;dBi ; dB{{sub| q}} : dB(quarterwave) – the ] of an antenna compared to the gain of a quarter wavelength whip. Rarely used, except in some marketing material; {{nobr| 0 dB{{sub|q}} {{=}} −0.85 dB{{sub|i}} }}
;dBsm: dB(m<sup>2</sup>) – decibel relative to one square meter: measure of the ].<ref>{{cite book |url={{Google books |plainurl=yes |id=-AkfVZskc64C |page=118 }} |title=EW 102: A Second Course in Electronic Warfare |author=David Adamy |access-date=2013-09-16}}</ref> ; dB{{sub| sm}} : dB{{sub| m²}}, dB(m²) – decibels relative to one square meter: A measure of the ] for capturing signals of the antenna.<ref>{{cite book |first=David |last=Adamy |year=2004 |title=EW&nbsp;102: A second course in electronic warfare |series=Artech House Radar Library |place=Boston, MA |publisher=Artech House |isbn=9781-58053687-5 |page= |url={{Google books |plainurl=yes |id=-AkfVZskc64C }} |via=Google |access-date=2013-09-16}}</ref>
;dBm<sup>−1</sup>: dB(m<sup>−1</sup>) – decibel relative to reciprocal of meter: measure of the ]. ; dB{{sub| m⁻¹}} : dB(m{{sup|−1}}) – decibels relative to reciprocal of meter: measure of the ].


===Other measurements=== === Other measurements ===
;dB{{nbhyph}}Hz: dB(Hz) – bandwidth relative to one hertz. E.g., 20&nbsp;dB{{nbhyph}}Hz corresponds to a bandwidth of 100&nbsp;Hz. Commonly used in ] calculations. Also used in ] (not to be confused with ], in dB). ; dB{{sub| Hz}} or dB‑Hz : dB(Hz) – bandwidth relative to one hertz. E.g., 20&nbsp;dB{{nbhyph}}Hz corresponds to a bandwidth of 100&nbsp;Hz. Commonly used in ] calculations. Also used in ] (not to be confused with ], in dB).
;]: dB(overload) – the ] of a signal (usually audio) compared with the maximum which a device can handle before ] occurs. Similar to dBFS, but also applicable to analog systems. According to ITU-T Rec. G.100.1 the level in dBov of a digital system is defined as: ; ]: dB(overload) – the ] of a signal (usually audio) compared with the maximum which a device can handle before ] occurs. Similar to dB FS, but also applicable to analog systems. According to ITU-T Rec. G.100.1 the level in dB ov of a digital system is defined as: <math display = "block">\ L_\mathsf{ov} = 10 \log_{10} \left( \frac{ P }{\ P_\mathsf{max}\ } \right)\ \ ,</math> with the maximum signal power <math>\ P_\mathsf{max} = 1.0\ ,</math> for a rectangular signal with the maximum amplitude <math>\ x_\mathsf{over} ~.</math> The level of a tone with a digital amplitude (peak value) of <math>\ x_\mathsf{over}\ </math> is therefore <math>\ L_\mathsf{ov} = -3.01\ \mathsf{dB_{ov}} ~.</math><ref>{{cite report |title=The use of the decibel and of relative levels in speech band telecommunications |date=June 2015 |id=ITU-T Rec. G.100.1 |publisher=] (ITU) |place=Geneva, CH |type=tech spec |url=https://www.itu.int/rec/dologin_pub.asp?lang=e&id=T-REC-G.100.1-201506-I!!PDF-E&type=items }}</ref>
; dB{{sub| r}} : dB(relative) – simply a relative difference from something else, which is made apparent in context. The difference of a filter's response to nominal levels, for instance.
:: <math>L_\text{ov} = 10\log_{10}\left ( \frac{P}{P_0} \right )\ </math>,
; ] : dB above ]. See also '''dB{{sub| rnC}}'''
: with the maximum signal power <math>P_0=1.0</math>, for a rectangular signal with the maximum amplitude <math>x_\text{over}</math>. The level of a tone with a digital amplitude (peak value) of <math>x_\text{over}</math> is therefore <math>L= -3.01\ \text{dBov}</math>.<ref>ITU-T Rec. G.100.1 The use of the decibel and of relative levels in speechband telecommunications https://www.itu.int/rec/dologin_pub.asp?lang=e&id=T-REC-G.100.1-201506-I!!PDF-E&type=items</ref>
; dB{{sub| rnC}} : '''dB(rnC)''' represents an audio level measurement, typically in a telephone circuit, relative to a −90&nbsp;dB{{sub| m}} reference level, with the measurement of this level frequency-weighted by a standard C-message weighting filter. The C-message weighting filter was chiefly used in North America. The ] filter is used for this purpose on international circuits.{{efn|See '']'' to see a comparison of frequency response curves for the C-message weighting and psophometric weighting filters.}}<ref>Definition of dB{{sub| rnC}} is given in <br/>{{cite book |editor-first=R.F. |editor-last=Rey |year=1983 |title=Engineering and Operations in the Bell System |edition=2nd |publisher=AT&T Bell Laboratories |place=Murray Hill, NJ |isbn=0-932764-04-5 |page=230 }}</ref>
;dBr: dB(relative) – simply a relative difference from something else, which is made apparent in context. The difference of a filter's response to nominal levels, for instance.
; dB{{sub| K}} : '''dB(K)''' – decibels relative to 1&nbsp;]; used to express ].<ref>{{cite book |first=K.N. Raja |last=Rao |date=2013-01-31 |df=dmy-all |title=Satellite Communication: Concepts and applications |page= |url={{Google books |plainurl=yes |id=pjEubAt5dk0C }} |via=Google |access-date=2013-09-16 }}</ref>
;]: dB above ]. See also '''dBrnC'''
; dB{{sub| K⁻¹}} or dB{{sub|/K}} : dB(K⁻¹) – decibels relative to 1&nbsp;K⁻¹.<ref>{{cite book |first=Ali Akbar |last=Arabi |year= |title=Comprehensive Glossary of Telecom Abbreviations and Acronyms |page= |url={{Google books |plainurl=yes |id=DVoqmlX6048C }} |via=Google |access-date=2013-09-16 |df=dmy-all }}</ref> — ''not'' decibels per Kelvin: Used for the {{mvar|{{sfrac| G | T }} }} ], a ] used in ], relating the ] {{mvar|G}} to the ] system noise equivalent temperature {{mvar|T}}.<ref>{{cite book |first=Mark E. |last=Long |year=1999 |title=The Digital Satellite TV Handbook |place=Woburn, MA |publisher=Newnes Press |page= |url={{Google books |plainurl=yes |id=L4yQ0iztvQEC }} |access-date=2013-09-16 |df=dmy-all }}</ref><ref>{{cite book |first=Mac E. |last=van&nbsp;Valkenburg |date=2001-10-19 |df=dmy-all |title=Reference Data for Engineers: Radio, electronics, computers, and communications |series=Technology & Engineering |editor-first=Wendy M. |editor-last=Middleton |place=Woburn, MA |publisher=Newness Press |isbn=9780-08051596-0 |page= |url={{Google books |plainurl=yes |id=U9RzPGwlic4C }} |via=Google |access-date=2013-09-16}}</ref>
;dBrnC: '''dBrnC''' represents an audio level measurement, typically in a telephone circuit, relative to a -90 dBm reference level, with the measurement of this level frequency-weighted by a standard C-message weighting filter. The C-message weighting filter was chiefly used in North America. The Psophometric filter is used for this purpose on international circuits. See ] to see a comparison of frequency response curves for the C-message weighting and Psophometric weighting filters.<ref>dBrnC is defined on page 230 in "Engineering and Operations in the Bell System," (2ed), R.F. Rey (technical editor), copyright 1983, AT&T Bell Laboratories, Murray Hill, NJ, {{ISBN|0-932764-04-5}}</ref>
;dBK:'''dB(K)'''&nbsp;– decibels relative to 1&nbsp;]; used to express ].<ref>{{cite book |url={{Google books |plainurl=yes |id=pjEubAt5dk0C |page=126 }} |title=Satellite Communication: Concepts And Applications |author=K. N. Raja Rao |date=2013-01-31 |access-date=2013-09-16}}</ref>
;dB/K: dB(K<sup>−1</sup>)&nbsp;– decibels relative to 1&nbsp;K<sup>−1</sup>.<ref>{{cite book |url={{Google books |plainurl=yes |id=DVoqmlX6048C |page=79 }} |title=Comprehensive Glossary of Telecom Abbreviations and Acronyms |author=Ali Akbar Arabi |access-date=2013-09-16}}</ref>&nbsp;— ''not'' decibels per kelvin: Used for the '']'' factor, a ] utilized in ], relating the ] ''G'' to the ] system noise equivalent temperature ''T''.<ref>{{cite book |url={{Google books |plainurl=yes |id=L4yQ0iztvQEC |page=93 }} |title=The Digital Satellite TV Handbook |author=Mark E. Long |access-date=2013-09-16}}</ref><ref>{{cite book |url={{Google books |plainurl=yes |id=U9RzPGwlic4C |page=SA27-PA14 }} |title=Reference Data for Engineers: Radio, Electronics, Computers and Communications |author=Mac E. Van Valkenburg |date=2001-10-19 |access-date=2013-09-16}}</ref>


===List of suffixes in alphabetical order=== === List of suffixes in alphabetical order ===


====Unpunctuated suffixes==== ==== Unpunctuated suffixes ====
;dBA: see ]. ; dB{{sub| A}} : see ].
;dBa: see ]. ; dB{{sub| a}} : see ].
;dBB: see ]. ; dB{{sub| B}} : see ].
;]: relative to carrier – in ]s, this indicates the relative levels of noise or sideband power, compared with the carrier power. ; ] : relative to carrier – in ], this indicates the relative levels of noise or sideband power, compared with the carrier power.
;dBC: see ]. ; dB{{sub| C}} : see ].
;dBD: see ]. ; dB{{sub| D}} : see ].
;dBd: dB(dipole) – the forward gain of an ] compared with a half-wave ]. 0&nbsp;dBd = 2.15&nbsp;dBi ; dB{{sub| d}} : dB(dipole) – the forward gain of an ] compared with a half-wave ]. 0&nbsp;dBd = 2.15&nbsp;dB{{sub| i}}
;dBe: dB electrical. ; dB{{sub| e}} : dB electrical.
;dBf: dB(fW) – power relative to 1 ]. ; dB{{sub| f}} : dB(fW) – power relative to 1&nbsp;].
;]: dB(]) – the ] of a signal compared with the maximum which a device can handle before ] occurs. Full-scale may be defined as the power level of a full-scale ] or alternatively a full-scale ]. A signal measured with reference to a full-scale sine-wave appears 3&nbsp;dB weaker when referenced to a full-scale square wave, thus: 0&nbsp;dBFS(fullscale sine wave) = −3&nbsp;dBFS(fullscale square wave). ; ] : dB(]) – the ] of a signal compared with the maximum which a device can handle before ] occurs. Full-scale may be defined as the power level of a full-scale ] or alternatively a full-scale ]. A signal measured with reference to a full-scale sine-wave appears 3&nbsp;dB weaker when referenced to a full-scale square wave, thus: 0&nbsp;dB{{sub| FS}} (fullscale sine wave) = −3&nbsp;dB{{sub| FS}} (full-scale square wave).
;dBG: ] spectrum ; dB{{sub| G}} : ] spectrum
;dBi: dB(isotropic) – the forward ] compared with the hypothetical ], which uniformly distributes energy in all directions. ] of the EM field is assumed unless noted otherwise. ; dB{{sub| i}} : dB(isotropic) – the forward ] compared with the hypothetical ], which uniformly distributes energy in all directions. ] of the EM field is assumed unless noted otherwise.
;dBiC: dB(isotropic circular) – the forward gain of an antenna compared to a ] isotropic antenna. There is no fixed conversion rule between dBiC and dBi, as it depends on the receiving antenna and the field polarization. ; dB{{sub| iC}} : dB(isotropic circular) – the forward gain of an antenna compared to a ] isotropic antenna. There is no fixed conversion rule between dB{{sub| iC}} and dB{{sub| i }}, as it depends on the receiving antenna and the field polarization.
;dBJ: energy relative to 1 ]. 1 joule = 1 watt second = 1 watt per hertz, so ] can be expressed in dBJ. ; dB{{sub| J}} : energy relative to 1&nbsp;]: 1&nbsp;joule = 1&nbsp;watt-second = 1&nbsp;watt per hertz, so ] can be expressed in dB{{sub| J }}.
;dBk: dB(kW) – power relative to 1 ]. ; dB{{sub| k}} : dB(kW) – power relative to 1&nbsp;].
;dBK:'''dB(K)''' – decibels relative to ]: Used to express ]. ; dB{{sub| K}} :'''dB(K)''' – decibels relative to ]: Used to express ].
;]: dB(mW) – power relative to 1 ]. ; ] : dB(mW) – power relative to 1 ].
; dB{{sub| m²}} or dB{{sub| sm}} : dB(m²) – decibel relative to one square meter
;]: Power in dBm measured at a zero transmission level point.
; ] : Power in dB{{sub| m}} measured at a zero transmission level point.
;dBm0s: Defined by Recommendation ITU-R V.574.
; dB{{sub| m0s}} : Defined by ''Recommendation ITU-R V.574''.
;dBmV: dB(mV<sub>]</sub>) – ]age relative to 1 millivolt across 75 Ω.
; dB{{sub| mV}} : dB(mV<sub>]</sub>) – ]age relative to 1&nbsp;millivolt across 75&nbsp;Ω.
;dBo: dB optical. A change of 1 dBo in optical power can result in a change of up to 2 dBe in electrical signal power in system that is thermal noise limited.
; dB{{sub| o}} : dB optical. A change of 1&nbsp;dB{{sub| o}} in optical power can result in a change of up to 2&nbsp;dB{{sub| e}} in electrical signal power in system that is thermal noise limited.
;dBO: see dBov
; dB{{sub| O}} : see dB{{sub| ov}}
;dBov or dBO: dB(overload) – the ] of a signal (usually audio) compared with the maximum which a device can handle before ] occurs.
; dB{{sub| ov}} or dB{{sub| O}} : dB(overload) – the ] of a signal (usually audio) compared with the maximum which a device can handle before ] occurs.
;dBpp: relative to the peak to peak sound pressure.
;dBpp: relative to the maximum value of the peak power. ; dB{{sub| pp}} : relative to the peak to peak ].
; dB{{sub| pp}} : relative to the maximum value of the peak ].
;dBq: dB(quarterwave) – the forward gain of an antenna compared to a quarter wavelength whip. Rarely used, except in some marketing material. 0&nbsp;dBq = −0.85&nbsp;dBi
; dB{{sub| q}} : dB(quarterwave) – the forward gain of an antenna compared to a quarter wavelength whip. Rarely used, except in some marketing material. 0&nbsp;dBq = −0.85&nbsp;dB{{sub| i}}
;dBr: dB(relative) – simply a relative difference from something else, which is made apparent in context. The difference of a filter's response to nominal levels, for instance.
; dB{{sub| r}} : dB(relative) – simply a relative difference from something else, which is made apparent in context. The difference of a filter's response to nominal levels, for instance.
;]: dB above ]. See also '''dBrnC'''
; ] : dB above ]. See also '''dB{{sub| rnC}}'''
;dBrnC: '''dBrnC''' represents an audio level measurement, typically in a telephone circuit, relative to the ], with the measurement of this level frequency-weighted by a standard C-message weighting filter. The C-message weighting filter was chiefly used in North America.
; dB{{sub| rnC}} : '''dB{{sub| rnC}}''' represents an audio level measurement, typically in a telephone circuit, relative to the ], with the measurement of this level frequency-weighted by a standard C-message weighting filter. The C-message weighting filter was chiefly used in North America.
;dBsm: dB(m<sup>2</sup>) – decibel relative to one square meter
; dB{{sub| sm}} : see dB{{sub| m²}}
;dBTP: dB(true peak) – ] of a signal compared with the maximum which a device can handle before clipping occurs.
; dB{{sub| TP}} : dB(true peak) – ] of a signal compared with the maximum which a device can handle before clipping occurs.
;dBu or dBv: ] ]age relative to {{nowrap|<math>\sqrt{0.6}\,\text{V}\, \approx 0.7746\,\text{V}\, \approx -2.218\,\text{dBV}</math>}}.
; dB{{sub| u}} or dB{{sub| v}} : ] ]age relative to <math>\ \sqrt{0.6\; }\ \mathsf{V}\ \approx 0.7746\ \mathsf{V}\ \approx -2.218\ \mathsf{dB_V} ~.</math>
;dBu0s: Defined by Recommendation ITU-R V.574.
; dB{{sub| u0s}} : Defined by ''Recommendation ITU-R V.574''.
;dBuV: see dBμV
; dB{{sub| uV}} : see dB{{sub| μV}}
;dBuV/m: see dBμV/m
; dB{{sub| uV/m}} : see dB{{sub| μV/m}}
;dBv: see dBu
;dBV: dB(V<sub>]</sub>) – ]age relative to 1 volt, regardless of impedance. ; dB{{sub| v}} : see dB{{sub| u}}
; dB{{sub| V}} : dB(V<sub>]</sub>) – ]age relative to 1 volt, regardless of impedance.
;dBVU: dB volume unit ; dB{{sub| VU}} : dB(VU) dB ]
;dBW: dB(W) – power relative to 1 ]. ; dB{{sub| W}} : dB(W) – power relative to 1&nbsp;].
;dBW·m<sup>−2</sup>·Hz<sup>−1</sup>: ] relative to 1 W·m<sup>−2</sup>·Hz<sup>−1</sup><ref>{{cite web|url=http://www.iucaf.org/sschool/mike/Units_and_Calculations.ppt |title=Archived copy |access-date=2013-08-24 |url-status=live |archive-url=https://web.archive.org/web/20160303223821/http://www.iucaf.org/sschool/mike/Units_and_Calculations.ppt |archive-date=2016-03-03 }}</ref> ; dB{{sub| W·m⁻²·Hz⁻¹}} : ] relative to 1 W·m⁻²·Hz⁻¹<ref>{{cite web |title=Units and calculations |website=iucaf.org |url=http://www.iucaf.org/sschool/mike/Units_and_Calculations.ppt |access-date=2013-08-24 |url-status=live |archive-url=https://web.archive.org/web/20160303223821/http://www.iucaf.org/sschool/mike/Units_and_Calculations.ppt |archive-date=2016-03-03 }}</ref>
;]: dB(Z) – decibel relative to Z = 1&nbsp;mm<sup>6</sup>⋅m<sup>−3</sup> ; ] : dB(Z) – decibel relative to Z = 1&nbsp;mm<sup>6</sup>⋅m<sup>−3</sup>
;dBμ: see dBμV/m ; dB{{sub| μ}} : see dB{{sub| μV/m}}
;dBμV or dBuV: dB(μV<sub>]</sub>) – ]age relative to 1 microvolt. ; dB{{sub| μV}} or dB{{sub| uV}} : dB(μV<sub>]</sub>) – ]age relative to 1&nbsp;] microvolt.
;dBμV/m, dBuV/m, or dBμ: dB(μV/m) – ] relative to 1 ] per ]. ; dB{{sub| μV/m }}, dB{{sub| uV/m }}, or dB{{sub| μ }} : dB(μV/m) – ] relative to 1&nbsp;] per ].


====Suffixes preceded by a space==== ==== Suffixes preceded by a space ====
;dB HL: dB hearing level is used in ]s as a measure of hearing loss. ; dB HL : dB hearing level is used in ]s as a measure of hearing loss.
;dB Q: sometimes used to denote weighted noise level ; dB Q : sometimes used to denote weighted noise level
;dB SIL: dB ] – relative to 10<sup>−12</sup>&nbsp;W/m<sup>2</sup> ; dB SIL : dB ] – relative to 10<sup>−12</sup>&nbsp;W/m<sup>2</sup>
;dB SPL: dB SPL (]) – for sound in air and other gases, relative to 20&nbsp;μPa in air or 1&nbsp;μPa in water ; dB SPL : dB SPL (]) – for sound in air and other gases, relative to 20&nbsp;μPa in air or 1&nbsp;μPa in water
;dB SWL: dB ] – relative to 10<sup>−12</sup>&nbsp;W. ; dB SWL : dB ] – relative to 10<sup>−12</sup>&nbsp;W.


====Suffixes within parentheses==== ==== Suffixes within parentheses ====
;], ], ], ], ],<!-- possibly also dB(M), but I haven't seen this in practise yet --> and ]: These symbols are often used to denote the use of different ]s, used to approximate the human ear's ] to sound, although the measurement is still in dB (SPL). These measurements usually refer to noise and its effects on humans and other animals, and they are widely used in industry while discussing noise control issues, regulations and environmental standards. Other variations that may be seen are dB<sub>A</sub> or ]. ; ], ], ], ], ],<!-- possibly also dB(M), but I haven't seen this in practise yet --> and ] : These symbols are often used to denote the use of different ]s, used to approximate the human ear's ] to sound, although the measurement is still in dB (SPL). These measurements usually refer to noise and its effects on humans and other animals, and they are widely used in industry while discussing noise control issues, regulations and environmental standards. Other variations that may be seen are dB<sub>A</sub> or ].


====Other suffixes==== ==== Other suffixes ====
;dB-Hz: dB(Hz) – bandwidth relative to one hertz. ; dB{{sub| Hz}} or dB-Hz : dB(Hz) – bandwidth relative to one ]
;dB/K: dB(K<sup>−1</sup>) – decibels relative to ] of ] ; dB{{sub| K⁻¹}} or dB{{sub| /K}} : dB(K⁻¹) – decibels relative to ] of ]
;dBm<sup>−1</sup>: dB(m<sup>−1</sup>) – decibel relative to reciprocal of meter: measure of the ]. ; dB{{sub| m⁻¹}} : dB(m⁻¹) – decibel relative to reciprocal of meter: measure of the ]


; mB{{sub| m}} : {{anchor|Millibel}} mB(mW) – power relative to 1&nbsp;], in millibels (one hundredth of a decibel). 100&nbsp;mB{{sub| m}} = 1&nbsp;dB{{sub| m }}. This unit is in the Wi-Fi drivers of the ] kernel<ref>{{cite web |title=Setting {{sc|TX}} power |series=en:users:documentation:iw |website=wireless.kernel.org |url=http://wireless.kernel.org/en/users/Documentation/iw#Setting_TX_power }}</ref> and the regulatory domain sections.<ref>{{cite web |title=Is your Wi Fi ap missing channels&nbsp;12 and 13&nbsp;? |date=16 May 2013 |website=Pentura Labs |via=wordpress.com |url=http://penturalabs.wordpress.com/2013/05/16/is-your-wifi-ap-missing-channels-12-13/ }}</ref>
==Related units==
;mBm:{{anchor|Millibel}} mB(mW) – power relative to 1 ], in millibels (one hundredth of a decibel). 100&nbsp;mBm = 1&nbsp;dBm. This unit is in the Wi-Fi drivers of the ] kernel<ref>{{cite web|url=http://wireless.kernel.org/en/users/Documentation/iw#Setting_TX_power|title=en:users:documentation:iw |website=wireless.kernel.org}}</ref> and the regulatory domain sections.<ref>{{cite web|url=http://penturalabs.wordpress.com/2013/05/16/is-your-wifi-ap-missing-channels-12-13/|title=Is your WiFi AP Missing Channels 12 & 13?|date=16 May 2013|website=wordpress.com}}</ref>


==See also== == See also ==
{{div col begin|colwidth=8}}
* ] * ]
* ] * ]
* ] (L<sub>den</sub>) and ] (Ldl), European and American standards for expressing noise level over an entire day
* ] * ]
* ] * ]
* ] * ]
* ]
* {{Section link|One-third octave|Base 10}} * {{Section link|One-third octave|Base 10}}
* ] * ]
Line 531: Line 551:
* ] * ]
* ] * ]
{{div col end}}


==Notes== == Notes ==
{{notelist}} {{notelist}}


==References== == References ==
{{Reflist}} {{reflist|25em}}


==Further reading== == Further reading ==
* {{cite journal |author-last=Tuffentsammer |author-first=Karl |title=Das Dezilog, eine Brücke zwischen Logarithmen, Dezibel, Neper und Normzahlen |language=de |trans-title=The decilog, a bridge between logarithms, decibel, neper and preferred numbers |journal=VDI-Zeitschrift |volume=98 |date=1956 |pages=267–274}} * {{cite journal |author-last=Tuffentsammer |author-first=Karl |title=Das Dezilog, eine Brücke zwischen Logarithmen, Dezibel, Neper und Normzahlen |language=de |trans-title=The decilog, a bridge between logarithms, decibel, neper and preferred numbers |journal=VDI-Zeitschrift |volume=98 |date=1956 |pages=267–274}}
* {{cite book |title=Logarithmen, Normzahlen, Dezibel, Neper, Phon - natürlich verwandt! |language=de |trans-title=Logarithms, preferred numbers, decibel, neper, phon - naturally related! |author-first=Eugen |author-last=Paulin |date=2007-09-01 |url=http://www.rechenschieber.org/Normzahlen.pdf |access-date=2016-12-18 |url-status=live |archive-url=https://web.archive.org/web/20161218223050/http://www.rechenschieber.org/Normzahlen.pdf |archive-date=2016-12-18}} * {{cite book |title=Logarithmen, Normzahlen, Dezibel, Neper, Phon - natürlich verwandt! |language=de |trans-title=Logarithms, preferred numbers, decibel, neper, phon - naturally related! |author-first=Eugen |author-last=Paulin |date=2007-09-01 |url=http://www.rechenschieber.org/Normzahlen.pdf |access-date=2016-12-18 |url-status=live |archive-url=https://web.archive.org/web/20161218223050/http://www.rechenschieber.org/Normzahlen.pdf |archive-date=2016-12-18}}


==External links== == External links ==
* *
* *
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] ]
] ]
]
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] ]

Latest revision as of 04:10, 30 December 2024

Logarithmic unit expressing the ratio of physical quantities This article is about the logarithmic unit. For use of this unit in sound measurements, see Sound pressure level. For other uses, see Decibel (disambiguation).

decibel
Unit systemNon-SI accepted unit
SymboldB
Named afterAlexander Graham Bell
Conversions
1 dB in ...... is equal to ...
   bel   ⁠1/10⁠ bel

The decibel (symbol: dB) 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 10 (approximately 1.26) or root-power ratio of 10 (approximately 1.12).

The unit fundamentally expresses a relative change but may also be used to express an absolute value as the ratio of a value to a fixed reference value; when used in this way, the unit symbol is often suffixed with letter codes that indicate the reference value. For example, for the reference value of 1 volt, a common suffix is "V" (e.g., "20 dBV").

Two principal types of scaling of the decibel are in common use. When expressing a power ratio, it is defined as ten times the logarithm with base 10. That is, a change in power by a factor of 10 corresponds to a 10 dB change in level. When expressing root-power quantities, a change in amplitude by a factor of 10 corresponds to a 20 dB change in level. The decibel scales differ by a factor of two, so that the related power and root-power levels change by the same value in linear systems, where power is proportional to the square of amplitude.

The definition of the decibel originated in the measurement of transmission loss and power in telephony of the early 20th century in the Bell System in the United States. The bel was named in honor of Alexander Graham Bell, but the bel is seldom used. Instead, the decibel is used for a wide variety of measurements in science and engineering, most prominently for sound power in acoustics, in electronics and control theory. In electronics, the gains of amplifiers, attenuation of signals, and signal-to-noise ratios are often expressed in decibels.

History

The decibel originates from methods used to quantify signal loss in telegraph and telephone circuits. Until the mid-1920s, the unit for loss was miles of standard cable (MSC). 1 MSC corresponded to the loss of power over one mile (approximately 1.6 km) of standard telephone cable at a frequency of 5000 radians per second (795.8 Hz), and matched closely the smallest attenuation detectable to a listener. A standard telephone cable was "a cable having uniformly distributed resistance of 88 ohms per loop-mile and uniformly distributed shunt capacitance of 0.054 microfarads per mile" (approximately corresponding to 19 gauge wire).

In 1924, Bell Telephone Laboratories received a favorable response to a new unit definition among members of the International Advisory Committee on Long Distance Telephony in Europe and replaced the MSC with the Transmission Unit (TU). 1 TU was defined such that the number of TUs was ten times the base-10 logarithm of the ratio of measured power to a reference power. The definition was conveniently chosen such that 1 TU approximated 1 MSC; specifically, 1 MSC was 1.056 TU. In 1928, the Bell system renamed the TU into the decibel, being one tenth of a newly defined unit for the base-10 logarithm of the power ratio. It was named the bel, in honor of the telecommunications pioneer Alexander Graham Bell. The bel is seldom used, as the decibel was the proposed working unit.

The naming and early definition of the decibel is described in the NBS Standard's Yearbook of 1931:

Since the earliest days of the telephone, the need for a unit in which to measure the transmission efficiency of telephone facilities has been recognized. The introduction of cable in 1896 afforded a stable basis for a convenient unit and the "mile of standard" cable came into general use shortly thereafter. This unit was employed up to 1923 when a new unit was adopted as being more suitable for modern telephone work. The new transmission unit is widely used among the foreign telephone organizations and recently it was termed the "decibel" at the suggestion of the International Advisory Committee on Long Distance Telephony.

The decibel may be defined by the statement that two amounts of power differ by 1 decibel when they are in the ratio of 10 and any two amounts of power differ by N decibels when they are in the ratio of 10. The number of transmission units expressing the ratio of any two powers is therefore ten times the common logarithm of that ratio. This method of designating the gain or loss of power in telephone circuits permits direct addition or subtraction of the units expressing the efficiency of different parts of the circuit ...

In 1954, J. W. Horton argued that the use of the decibel as a unit for quantities other than transmission loss led to confusion, and suggested the name logit for "standard magnitudes which combine by multiplication", to contrast with the name unit for "standard magnitudes which combine by addition".

In April 2003, the International Committee for Weights and Measures (CIPM) considered a recommendation for the inclusion of the decibel in the International System of Units (SI), but decided against the proposal. However, the decibel is recognized by other international bodies such as the International Electrotechnical Commission (IEC) and International Organization for Standardization (ISO). The IEC permits the use of the decibel with root-power quantities as well as power and this recommendation is followed by many national standards bodies, such as NIST, which justifies the use of the decibel for voltage ratios. In spite of their widespread use, suffixes (such as in dBA or dBV) are not recognized by the IEC or ISO.

Definition

dB Power ratio Amplitude ratio
100 10000000000 100000
90 1000000000 31623
80 100000000 10000
70 10000000 3162
60 1000000 1000
50 100000 316 .2
40 10000 100
30 1000 31 .62
20 100 10
10 10 3 .162
6 3 .981 ≈ 4 1 .995 ≈ 2
3 1 .995 ≈ 2 1 .413 ≈ √2
1 1 .259 1 .122
0 1 1
−1 0 .794 0 .891
−3 0 .501 ≈ ⁠1/2⁠ 0 .708 ≈ √⁠1/2⁠
−6 0 .251 ≈ ⁠1/4⁠ 0 .501 ≈ ⁠1/2⁠
−10 0 .1 0 .3162
−20 0 .01 0 .1
−30 0 .001 0 .03162
−40 0 .0001 0 .01
−50 0 .00001 0 .003162
−60 0 .000001 0 .001
−70 0 .0000001 0 .0003162
−80 0 .00000001 0 .0001
−90 0 .000000001 0 .00003162
−100 0 .0000000001 0 .00001
An example scale showing power ratios x, amplitude ratios √x, and dB equivalents 10 log10 x


The IEC Standard 60027-3:2002 defines the following quantities. The decibel (dB) is one-tenth of a bel: 1 dB = 0.1 B. The bel (B) is 1⁄2 ln(10) nepers: 1 B = 1⁄2 ln(10) Np. The neper is the change in the level of a root-power quantity when the root-power quantity changes by a factor of e, that is 1 Np = ln(e) = 1, thereby relating all of the units as nondimensional natural log of root-power-quantity ratios, 1 dB = 0.11513... Np = 0.11513.... Finally, the level of a quantity is the logarithm of the ratio of the value of that quantity to a reference value of the same kind of quantity.

Therefore, the bel represents the logarithm of a ratio between two power quantities of 10:1, or the logarithm of a ratio between two root-power quantities of √10:1.

Two signals whose levels differ by one decibel have a power ratio of 10, which is approximately 1.25893, and an amplitude (root-power quantity) ratio of 10 (1.12202).

The bel is rarely used either without a prefix or with SI unit prefixes other than deci; it is customary, for example, to use hundredths of a decibel rather than millibels. Thus, five one-thousandths of a bel would normally be written 0.05 dB, and not 5 mB.

The method of expressing a ratio as a level in decibels depends on whether the measured property is a power quantity or a root-power quantity; see Power, root-power, and field quantities for details.

Power quantities

When referring to measurements of power quantities, a ratio can be expressed as a level in decibels by evaluating ten times the base-10 logarithm of the ratio of the measured quantity to reference value. Thus, the ratio of P (measured power) to P0 (reference power) is represented by LP, that ratio expressed in decibels, which is calculated using the formula:

L P = 1 2 ln ( P P 0 ) Np = 10 log 10 ( P P 0 ) dB {\displaystyle L_{P}={\frac {1}{2}}\ln \!\left({\frac {P}{P_{0}}}\right)\,{\text{Np}}=10\log _{10}\!\left({\frac {P}{P_{0}}}\right)\,{\text{dB}}}

The base-10 logarithm of the ratio of the two power quantities is the number of bels. The number of decibels is ten times the number of bels (equivalently, a decibel is one-tenth of a bel). P and P0 must measure the same type of quantity, and have the same units before calculating the ratio. If P = P0 in the above equation, then LP = 0. If P is greater than P0 then LP is positive; if P is less than P0 then LP is negative.

Rearranging the above equation gives the following formula for P in terms of P0 and LP :

P = 10 L P 10 dB P 0 {\displaystyle P=10^{\frac {L_{P}}{10\,{\text{dB}}}}P_{0}}

Root-power (field) quantities

Main article: Power, root-power, and field quantities

When referring to measurements of root-power quantities, it is usual to consider the ratio of the squares of F (measured) and F0 (reference). This is because the definitions were originally formulated to give the same value for relative ratios for both power and root-power quantities. Thus, the following definition is used:

L F = ln ( F F 0 ) Np = 10 log 10 ( F 2 F 0 2 ) dB = 20 log 10 ( F F 0 ) dB {\displaystyle L_{F}=\ln \!\left({\frac {F}{F_{0}}}\right)\,{\text{Np}}=10\log _{10}\!\left({\frac {F^{2}}{F_{0}^{2}}}\right)\,{\text{dB}}=20\log _{10}\left({\frac {F}{F_{0}}}\right)\,{\text{dB}}}

The formula may be rearranged to give

F = 10 L F 20 dB F 0 {\displaystyle F=10^{\frac {L_{F}}{20\,{\text{dB}}}}F_{0}}

Similarly, in electrical circuits, dissipated power is typically proportional to the square of voltage or current when the impedance is constant. Taking voltage as an example, this leads to the equation for power gain level LG:

L G = 20 log 10 ( V out V in ) dB {\displaystyle L_{G}=20\log _{10}\!\left({\frac {V_{\text{out}}}{V_{\text{in}}}}\right)\,{\text{dB}}}

where Vout is the root-mean-square (rms) output voltage, Vin is the rms input voltage. A similar formula holds for current.

The term root-power quantity is introduced by ISO Standard 80000-1:2009 as a substitute of field quantity. The term field quantity is deprecated by that standard and root-power is used throughout this article.

Relationship between power and root-power levels

Although power and root-power quantities are different quantities, their respective levels are historically measured in the same units, typically decibels. A factor of 2 is introduced to make changes in the respective levels match under restricted conditions such as when the medium is linear and the same waveform is under consideration with changes in amplitude, or the medium impedance is linear and independent of both frequency and time. This relies on the relationship

P ( t ) P 0 = ( F ( t ) F 0 ) 2 {\displaystyle {\frac {P(t)}{P_{0}}}=\left({\frac {F(t)}{F_{0}}}\right)^{2}}

holding. In a nonlinear system, this relationship does not hold by the definition of linearity. However, even in a linear system in which the power quantity is the product of two linearly related quantities (e.g. voltage and current), if the impedance is frequency- or time-dependent, this relationship does not hold in general, for example if the energy spectrum of the waveform changes.

For differences in level, the required relationship is relaxed from that above to one of proportionality (i.e., the reference quantities P0 and F0 need not be related), or equivalently,

P 2 P 1 = ( F 2 F 1 ) 2 {\displaystyle {\frac {P_{2}}{P_{1}}}=\left({\frac {F_{2}}{F_{1}}}\right)^{2}}

must hold to allow the power level difference to be equal to the root-power level difference from power P1 and F1 to P2 and F2. An example might be an amplifier with unity voltage gain independent of load and frequency driving a load with a frequency-dependent impedance: the relative voltage gain of the amplifier is always 0 dB, but the power gain depends on the changing spectral composition of the waveform being amplified. Frequency-dependent impedances may be analyzed by considering the quantities power spectral density and the associated root-power quantities via the Fourier transform, which allows elimination of the frequency dependence in the analysis by analyzing the system at each frequency independently.

Conversions

Since logarithm differences measured in these units often represent power ratios and root-power ratios, values for both are shown below. The bel is traditionally used as a unit of logarithmic power ratio, while the neper is used for logarithmic root-power (amplitude) ratio.

Conversion between units of level and a list of corresponding ratios
Unit In decibels In bels In nepers Power ratio Root-power ratio
1 dB 1 dB 0.1 B 0.11513 Np 10 ≈ 1.25893 10 ≈ 1.12202
1 Np 8.68589 dB 0.868589 B 1 Np e ≈ 7.38906 e ≈ 2.71828
1 B 10 dB 1 B 1.151 3 Np 10 10 ≈ 3.162 28

Examples

The unit dBW is often used to denote a ratio for which the reference is 1 W, and similarly dBm for a 1 mW reference point.

  • Calculating the ratio in decibels of 1 kW (one kilowatt, or 1000 watts) to 1 W yields: L G = 10 log 10 ( 1 000 W 1 W ) dB = 30 dB {\displaystyle L_{G}=10\log _{10}\left({\frac {1\,000\,{\text{W}}}{1\,{\text{W}}}}\right)\,{\text{dB}}=30\,{\text{dB}}}
  • The ratio in decibels of √1000 V ≈ 31.62 V to 1 V is: L G = 20 log 10 ( 31.62 V 1 V ) dB = 30 dB {\displaystyle L_{G}=20\log _{10}\left({\frac {31.62\,{\text{V}}}{1\,{\text{V}}}}\right)\,{\text{dB}}=30\,{\text{dB}}}

(31.62 V / 1 V) ≈ 1 kW / 1 W, illustrating the consequence from the definitions above that LG has the same value, 30 dB, regardless of whether it is obtained from powers or from amplitudes, provided that in the specific system being considered power ratios are equal to amplitude ratios squared.

  • The ratio in decibels of 10 W to 1 mW (one milliwatt) is obtained with the formula: L G = 10 log 10 ( 10 W 0.001 W ) dB = 40 dB {\displaystyle L_{G}=10\log _{10}\left({\frac {10{\text{W}}}{0.001{\text{W}}}}\right)\,{\text{dB}}=40\,{\text{dB}}}
  • The power ratio corresponding to a 3 dB change in level is given by: G = 10 3 10 × 1 = 1.995 26 2 {\displaystyle G=10^{\frac {3}{10}}\times 1=1.995\,26\ldots \approx 2}

A change in power ratio by a factor of 10 corresponds to a change in level of 10 dB. A change in power ratio by a factor of 2 or ⁠1/2⁠ is approximately a change of 3 dB. More precisely, the change is ±3.0103 dB, but this is almost universally rounded to 3 dB in technical writing. This implies an increase in voltage by a factor of √2 ≈ 1.4142. Likewise, a doubling or halving of the voltage, corresponding to a quadrupling or quartering of the power, is commonly described as 6 dB rather than ±6.0206 dB.

Should it be necessary to make the distinction, the number of decibels is written with additional significant figures. 3.000 dB corresponds to a power ratio of 10, or 1.9953, about 0.24% different from exactly 2, and a voltage ratio of 1.4125, 0.12% different from exactly √2. Similarly, an increase of 6.000 dB corresponds to the power ratio is 10 ≈ 3.9811, about 0.5% different from 4.

Properties

The decibel is useful for representing large ratios and for simplifying representation of multiplicative effects, such as attenuation from multiple sources along a signal chain. Its application in systems with additive effects is less intuitive, such as in the combined sound pressure level of two machines operating together. Care is also necessary with decibels directly in fractions and with the units of multiplicative operations.

Reporting large ratios

The logarithmic scale nature of the decibel means that a very large range of ratios can be represented by a convenient number, in a manner similar to scientific notation. This allows one to clearly visualize huge changes of some quantity. See Bode plot and Semi-log plot. For example, 120 dB SPL may be clearer than "a trillion times more intense than the threshold of hearing".

Representation of multiplication operations

Level values in decibels can be added instead of multiplying the underlying power values, which means that the overall gain of a multi-component system, such as a series of amplifier stages, can be calculated by summing the gains in decibels of the individual components, rather than multiply the amplification factors; that is, log(A × B × C) = log(A) + log(B) + log(C). Practically, this means that, armed only with the knowledge that 1 dB is a power gain of approximately 26%, 3 dB is approximately 2× power gain, and 10 dB is 10× power gain, it is possible to determine the power ratio of a system from the gain in dB with only simple addition and multiplication. For example:

  • A system consists of 3 amplifiers in series, with gains (ratio of power out to in) of 10 dB, 8 dB, and 7 dB respectively, for a total gain of 25 dB. Broken into combinations of 10, 3, and 1 dB, this is: 25 dB = 10 dB + 10 dB + 3 dB + 1 dB + 1 dB With an input of 1 watt, the output is approximately 1 W × 10 × 10 × 2 × 1.26 × 1.26 ≈ 317.5 W Calculated precisely, the output is 1 W × 10 ≈ 316.2 W. The approximate value has an error of only +0.4% with respect to the actual value, which is negligible given the precision of the values supplied and the accuracy of most measurement instrumentation.

However, according to its critics, the decibel creates confusion, obscures reasoning, is more related to the era of slide rules than to modern digital processing, and is cumbersome and difficult to interpret. Quantities in decibels are not necessarily additive, thus being "of unacceptable form for use in dimensional analysis". Thus, units require special care in decibel operations. Take, for example, carrier-to-noise-density ratio C/N0 (in hertz), involving carrier power C (in watts) and noise power spectral density N0 (in W/Hz). Expressed in decibels, this ratio would be a subtraction (C/N0)dB = CdBN0 dB. However, the linear-scale units still simplify in the implied fraction, so that the results would be expressed in dB-Hz.

Representation of addition operations

Further information: Logarithmic addition

According to Mitschke, "The advantage of using a logarithmic measure is that in a transmission chain, there are many elements concatenated, and each has its own gain or attenuation. To obtain the total, addition of decibel values is much more convenient than multiplication of the individual factors." However, for the same reason that humans excel at additive operation over multiplication, decibels are awkward in inherently additive operations:

if two machines each individually produce a sound pressure level of, say, 90 dB at a certain point, then when both are operating together we should expect the combined sound pressure level to increase to 93 dB, but certainly not to 180 dB!; suppose that the noise from a machine is measured (including the contribution of background noise) and found to be 87 dBA but when the machine is switched off the background noise alone is measured as 83 dBA. the machine noise may be obtained by 'subtracting' the 83 dBA background noise from the combined level of 87 dBA; i.e., 84.8 dBA.; in order to find a representative value of the sound level in a room a number of measurements are taken at different positions within the room, and an average value is calculated. Compare the logarithmic and arithmetic averages of 70 dB and 90 dB: logarithmic average = 87 dB; arithmetic average = 80 dB.

Addition on a logarithmic scale is called logarithmic addition, and can be defined by taking exponentials to convert to a linear scale, adding there, and then taking logarithms to return. For example, where operations on decibels are logarithmic addition/subtraction and logarithmic multiplication/division, while operations on the linear scale are the usual operations:

87 dBA 83 dBA = 10 log 10 ( 10 87 / 10 10 83 / 10 ) dBA 84.8 dBA {\displaystyle 87\,{\text{dBA}}\ominus 83\,{\text{dBA}}=10\cdot \log _{10}{\bigl (}10^{87/10}-10^{83/10}{\bigr )}\,{\text{dBA}}\approx 84.8\,{\text{dBA}}}
M lm ( 70 , 90 ) = ( 70 dBA + 90 dBA ) / 2 = 10 log 10 ( ( 10 70 / 10 + 10 90 / 10 ) / 2 ) dBA = 10 ( log 10 ( 10 70 / 10 + 10 90 / 10 ) log 10 2 ) dBA 87 dBA {\displaystyle {\begin{aligned}M_{\text{lm}}(70,90)&=\left(70\,{\text{dBA}}+90\,{\text{dBA}}\right)/2\\&=10\cdot \log _{10}\left({\bigl (}10^{70/10}+10^{90/10}{\bigr )}/2\right)\,{\text{dBA}}\\&=10\cdot \left(\log _{10}{\bigl (}10^{70/10}+10^{90/10}{\bigr )}-\log _{10}2\right)\,{\text{dBA}}\approx 87\,{\text{dBA}}\end{aligned}}}

The logarithmic mean is obtained from the logarithmic sum by subtracting 10 log 10 2 {\displaystyle 10\log _{10}2} , since logarithmic division is linear subtraction.

Fractions

Attenuation constants, in topics such as optical fiber communication and radio propagation path loss, are often expressed as a fraction or ratio to distance of transmission. In this case, dB/m represents decibel per meter, dB/mi represents decibel per mile, for example. These quantities are to be manipulated obeying the rules of dimensional analysis, e.g., a 100-meter run with a 3.5 dB/km fiber yields a loss of 0.35 dB = 3.5 dB/km × 0.1 km.

Uses

Perception

The human perception of the intensity of sound and light more nearly approximates the logarithm of intensity rather than a linear relationship (see Weber–Fechner law), making the dB scale a useful measure.

Acoustics

The decibel is commonly used in acoustics as a unit of sound power level or sound pressure level. The reference pressure for sound in air is set at the typical threshold of perception of an average human and there are common comparisons used to illustrate different levels of sound pressure. As sound pressure is a root-power quantity, the appropriate version of the unit definition is used:

L p = 20 log 10 ( p rms p ref ) dB , {\displaystyle L_{p}=20\log _{10}\!\left({\frac {p_{\text{rms}}}{p_{\text{ref}}}}\right)\,{\text{dB}},}

where prms is the root mean square of the measured sound pressure and pref is the standard reference sound pressure of 20 micropascals in air or 1 micropascal in water.

Use of the decibel in underwater acoustics leads to confusion, in part because of this difference in reference value.

Sound intensity is proportional to the square of sound pressure. Therefore, the sound intensity level can also be defined as:

L p = 10 log 10 ( I I ref ) dB , {\displaystyle L_{p}=10\log _{10}\!\left({\frac {I}{I_{\text{ref}}}}\right)\,{\text{dB}},}

The human ear has a large dynamic range in sound reception. The ratio of the sound intensity that causes permanent damage during short exposure to that of the quietest sound that the ear can hear is equal to or greater than 1 trillion (10). Such large measurement ranges are conveniently expressed in logarithmic scale: the base-10 logarithm of 10 is 12, which is expressed as a sound intensity level of 120 dB re 1 pW/m. The reference values of I and p in air have been chosen such that this corresponds approximately to a sound pressure level of 120 dB re 20 μPa.

Since the human ear is not equally sensitive to all sound frequencies, the acoustic power spectrum is modified by frequency weighting (A-weighting being the most common standard) to get the weighted acoustic power before converting to a sound level or noise level in decibels.

Further information: Sound pressure § Examples of sound pressure

Telephony

The decibel is used in telephony and audio. Similarly to the use in acoustics, a frequency weighted power is often used. For audio noise measurements in electrical circuits, the weightings are called psophometric weightings.

Electronics

In electronics, the decibel is often used to express power or amplitude ratios (as for gains) in preference to arithmetic ratios or percentages. One advantage is that the total decibel gain of a series of components (such as amplifiers and attenuators) can be calculated simply by summing the decibel gains of the individual components. Similarly, in telecommunications, decibels denote signal gain or loss from a transmitter to a receiver through some medium (free space, waveguide, coaxial cable, fiber optics, etc.) using a link budget.

The decibel unit can also be combined with a reference level, often indicated via a suffix, to create an absolute unit of electric power. For example, it can be combined with "m" for "milliwatt" to produce the "dBm". A power level of 0 dBm corresponds to one milliwatt, and 1 dBm is one decibel greater (about 1.259 mW).

In professional audio specifications, a popular unit is the dBu. This is relative to the root mean square voltage which delivers 1 mW (0 dBm) into a 600-ohm resistor, or √1 mW × 600 Ω ≈ 0.775 VRMS. When used in a 600-ohm circuit (historically, the standard reference impedance in telephone circuits), dBu and dBm are identical.

Optics

In an optical link, if a known amount of optical power, in dBm (referenced to 1 mW), 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 addition and subtraction of decibel quantities.

In spectrometry and optics, the blocking unit used to measure optical density is equivalent to −1 B.

Video and digital imaging

In connection with video and digital image sensors, decibels generally represent ratios of video voltages or digitized light intensities, using 20 log of the ratio, even when the represented intensity (optical power) is directly proportional to the voltage generated by the sensor, not to its square, as in a CCD imager where response voltage is linear in intensity. Thus, a camera signal-to-noise ratio or dynamic range quoted as 40 dB represents a ratio of 100:1 between optical signal intensity and optical-equivalent dark-noise intensity, not a 10,000:1 intensity (power) ratio as 40 dB might suggest. Sometimes the 20 log ratio definition is applied to electron counts or photon counts directly, which are proportional to sensor signal amplitude without the need to consider whether the voltage response to intensity is linear.

However, as mentioned above, the 10 log intensity convention prevails more generally in physical optics, including fiber optics, so the terminology can become murky between the conventions of digital photographic technology and physics. Most commonly, quantities called "dynamic range" or "signal-to-noise" (of the camera) would be specified in 20 log dB, but in related contexts (e.g. attenuation, gain, intensifier SNR, or rejection ratio) the term should be interpreted cautiously, as confusion of the two units can result in very large misunderstandings of the value.

Photographers typically use an alternative base-2 log unit, the stop, to describe light intensity ratios or dynamic range.

Suffixes and reference values

Suffixes are commonly attached to the basic dB unit in order to indicate the reference value by which the ratio is calculated. For example, dBm indicates power measurement relative to 1 milliwatt.

In cases where the unit value of the reference is stated, the decibel value is known as "absolute". If the unit value of the reference is not explicitly stated, as in the dB gain of an amplifier, then the decibel value is considered relative.

This form of attaching suffixes to dB is widespread in practice, albeit being against the rules promulgated by standards bodies (ISO and IEC), given the "unacceptability of attaching information to units" and the "unacceptability of mixing information with units". The IEC 60027-3 standard recommends the following format: Lx (re xref) or as Lx/xref, where x is the quantity symbol and xref is the value of the reference quantity, e.g., LE (re 1 μV/m) = 20 dB or LE/(1 μV/m) = 20 dB for the electric field strength E relative to 1 μV/m reference value. If the measurement result 20 dB is presented separately, it can be specified using the information in parentheses, which is then part of the surrounding text and not a part of the unit: 20 dB (re: 1 μV/m) or 20 dB (1 μV/m).

Outside of documents adhering to SI units, the practice is very common as illustrated by the following examples. There is no general rule, with various discipline-specific practices. Sometimes the suffix is a unit symbol ("W","K","m"), sometimes it is a transliteration of a unit symbol ("uV" instead of μV for microvolt), sometimes it is an acronym for the unit's name ("sm" for square meter, "m" for milliwatt), other times it is a mnemonic for the type of quantity being calculated ("i" for antenna gain with respect to an isotropic antenna, "λ" for anything normalized by the EM wavelength), or otherwise a general attribute or identifier about the nature of the quantity ("A" for A-weighted sound pressure level). The suffix is often connected with a hyphen, as in "dB‑Hz", or with a space, as in "dB HL", or enclosed in parentheses, as in "dB(sm)", or with no intervening character, as in "dBm" (which is non-compliant with international standards).

List of suffixes

Voltage

Since the decibel is defined with respect to power, not amplitude, conversions of voltage ratios to decibels must square the amplitude, or use the factor of 20 instead of 10, as discussed above.

A schematic showing the relationship between dB u (the voltage source) and dB m (the power dissipated as heat by the 600 Ω resistor)
dB V
dB(VRMS) – voltage relative to 1 volt, regardless of impedance. This is used to measure microphone sensitivity, and also to specify the consumer line-level of −10 dBV, in order to reduce manufacturing costs relative to equipment using a +4 dBu line-level signal.
dB u or dB v
RMS voltage relative to V = 600   Ω     0.001   W 0.7746   V   {\displaystyle V={\sqrt {600\ \Omega \ \cdot \ 0.001\ {\mathsf {W}}\;}}\approx 0.7746\ {\mathsf {V}}\ } (i.e. the voltage that would dissipate 1 mW into a 600 Ω load). An RMS voltage of 1 V therefore corresponds to   20 log 10 (   1   V R M S   0.6     V ) = 2.218   d B u   . {\displaystyle \ 20\cdot \log _{10}\left({\frac {\ 1\ V_{\mathsf {RMS}}\ }{{\sqrt {0.6\ }}\ V}}\right)=2.218\ {\mathsf {dB_{u}}}~.} Originally dB v , it was changed to dB u to avoid confusion with dB V. The v comes from volt, while u comes from the volume unit displayed on a VU meter.dB u can be used as a measure of voltage, regardless of impedance, but is derived from a 600 Ω load dissipating 0 dB m (1 mW). The reference voltage comes from the computation   7 V = R P     {\displaystyle \ 7{\mathsf {V}}={\sqrt {R\cdot P\ }}\ } where   R   {\displaystyle \ R\ } is the resistance and   P   {\displaystyle \ P\ } is the power.
In professional audio, equipment may be calibrated to indicate a "0" on the VU meters some finite time after a signal has been applied at an amplitude of +4 dBu. Consumer equipment typically uses a lower "nominal" signal level of −10 dB V . Therefore, many devices offer dual voltage operation (with different gain or "trim" settings) for interoperability reasons. A switch or adjustment that covers at least the range between +4 dB u and −10 dB V is common in professional equipment.
dB m0s
Defined by Recommendation ITU-R V.574 ; dB mV: dB(mVRMS) – root mean square voltage relative to 1 millivolt across 75 Ω. Widely used in cable television networks, where the nominal strength of a single TV signal at the receiver terminals is about 0 dB mV. Cable TV uses 75 Ω coaxial cable, so 0 dB mV corresponds to −78.75 dB W ( −48.75 dB m ) or approximately 13 nW.
dB μV or dB uV
dB(μVRMS) – voltage relative to 1 microvolt. Widely used in television and aerial amplifier specifications. 60 dBμV = 0 dB mV.

Acoustics

Probably the most common usage of "decibels" in reference to sound level is dB SPL, sound pressure level referenced to the nominal threshold of human hearing: The measures of pressure (a root-power quantity) use the factor of 20, and the measures of power (e.g. dB SIL and dB SWL) use the factor of 10.

dB SPL
dB SPL (sound pressure level) – for sound in air and other gases, relative to 20 micropascals (μPa), or 2×10 Pa, approximately the quietest sound a human can hear. For sound in water and other liquids, a reference pressure of 1 μPa is used. An RMS sound pressure of one pascal corresponds to a level of 94 dB SPL.
dB SIL
dB sound intensity level – relative to 10 W/m, which is roughly the threshold of human hearing in air.
dB SWL
dB sound power level – relative to 10 W.
dB A, dB B, and dB C
These symbols are often used to denote the use of different weighting filters, used to approximate the human ear's response to sound, although the measurement is still in dB (SPL). These measurements usually refer to noise and its effects on humans and other animals, and they are widely used in industry while discussing noise control issues, regulations and environmental standards. Other variations that may be seen are dB A or dB(A). According to standards from the International Electro-technical Committee (IEC 61672-2013) and the American National Standards Institute, ANSI S1.4, the preferred usage is to write L A = x dB . Nevertheless, the units dB A and dB(A) are still commonly used as a shorthand for A‑weighted measurements. Compare dB c, used in telecommunications.
dB HL
dB hearing level is used in audiograms as a measure of hearing loss. The reference level varies with frequency according to a minimum audibility curve as defined in ANSI and other standards, such that the resulting audiogram shows deviation from what is regarded as 'normal' hearing.
dB Q
sometimes used to denote weighted noise level, commonly using the ITU-R 468 noise weighting
dB pp
relative to the peak to peak sound pressure.
dB G
G‑weighted spectrum

Audio electronics

See also dB V and dB u above.

dB m
dB(mW) – power relative to 1 milliwatt. In audio and telephony, dB m is typically referenced relative to a 600 Ω impedance, which corresponds to a voltage level of 0.775 volts or 775 millivolts.
dB m0
Power in dB m (described above) measured at a zero transmission level point.
dB FS
dB(full scale) – the amplitude of a signal compared with the maximum which a device can handle before clipping occurs. Full-scale may be defined as the power level of a full-scale sinusoid or alternatively a full-scale square wave. A signal measured with reference to a full-scale sine-wave appears 3 dB weaker when referenced to a full-scale square wave, thus: 0 dBFS(fullscale sine wave) = −3 dB FS (fullscale square wave).
dB VU
dB volume unit
dB TP
dB(true peak) – peak amplitude of a signal compared with the maximum which a device can handle before clipping occurs. In digital systems, 0 dB TP would equal the highest level (number) the processor is capable of representing. Measured values are always negative or zero, since they are less than or equal to full-scale.

Radar

dB Z
dB(Z) – decibel relative to Z = 1 mm⋅m: energy of reflectivity (weather radar), related to the amount of transmitted power returned to the radar receiver. Values above 20 dB Z usually indicate falling precipitation.
dB sm
dB(m²) – decibel relative to one square meter: measure of the radar cross section (RCS) of a target. The power reflected by the target is proportional to its RCS. "Stealth" aircraft and insects have negative RCS measured in dB sm , large flat plates or non-stealthy aircraft have positive values.

Radio power, energy, and field strength

dB c
relative to carrier – in telecommunications, this indicates the relative levels of noise or sideband power, compared with the carrier power. Compare dB C, used in acoustics.
dB pp
relative to the maximum value of the peak power.
dB J
energy relative to 1 joule. 1 joule = 1 watt second = 1 watt per hertz, so power spectral density can be expressed in dB J .
dB m
dB(mW) – power relative to 1 milliwatt. In the radio field, dB m is usually referenced to a 50 Ω load, with the resultant voltage being 0.224 volts.
dB μV/m , dB uV/m , or dB μ 
dB(μV/m) – electric field strength relative to 1 microvolt per meter. The unit is often used to specify the signal strength of a television broadcast at a receiving site (the signal measured at the antenna output is reported in dBμ V).
dB f
dB(fW) – power relative to 1 femtowatt.
dB W
dB(W) – power relative to 1 watt.
dB k
dB(kW) – power relative to 1 kilowatt.
dB e
dB electrical.
dB o
dB optical. A change of 1 dB o in optical power can result in a change of up to 2 dB e in electrical signal power in a system that is thermal noise limited.

Antenna measurements

dB i
dB(isotropic) – the gain of an antenna compared with the gain of a theoretical isotropic antenna, which uniformly distributes energy in all directions. Linear polarization of the EM field is assumed unless noted otherwise.
dB d
dB(dipole) – the gain of an antenna compared with the gain a half-wave dipole antenna. 0 dBd = 2.15 dBi
dB iC
dB(isotropic circular) – the gain of an antenna compared to the gain of a theoretical circularly polarized isotropic antenna. There is no fixed conversion rule between dBiC and dBi, as it depends on the receiving antenna and the field polarization.
dB q
dB(quarterwave) – the gain of an antenna compared to the gain of a quarter wavelength whip. Rarely used, except in some marketing material; 0 dBq = −0.85 dBi
dB sm
dB m², dB(m²) – decibels relative to one square meter: A measure of the effective area for capturing signals of the antenna.
dB m⁻¹
dB(m) – decibels relative to reciprocal of meter: measure of the antenna factor.

Other measurements

dB Hz or dB‑Hz
dB(Hz) – bandwidth relative to one hertz. E.g., 20 dB‑Hz corresponds to a bandwidth of 100 Hz. Commonly used in link budget calculations. Also used in carrier-to-noise-density ratio (not to be confused with carrier-to-noise ratio, in dB).
dB ov or dB O
dB(overload) – the amplitude of a signal (usually audio) compared with the maximum which a device can handle before clipping occurs. Similar to dB FS, but also applicable to analog systems. According to ITU-T Rec. G.100.1 the level in dB ov of a digital system is defined as:   L o v = 10 log 10 ( P   P m a x   )   [ d B o v ]   , {\displaystyle \ L_{\mathsf {ov}}=10\log _{10}\left({\frac {P}{\ P_{\mathsf {max}}\ }}\right)\ \ ,} with the maximum signal power   P m a x = 1.0   , {\displaystyle \ P_{\mathsf {max}}=1.0\ ,} for a rectangular signal with the maximum amplitude   x o v e r   . {\displaystyle \ x_{\mathsf {over}}~.} The level of a tone with a digital amplitude (peak value) of   x o v e r   {\displaystyle \ x_{\mathsf {over}}\ } is therefore   L o v = 3.01   d B o v   . {\displaystyle \ L_{\mathsf {ov}}=-3.01\ {\mathsf {dB_{ov}}}~.}
dB r
dB(relative) – simply a relative difference from something else, which is made apparent in context. The difference of a filter's response to nominal levels, for instance.
dB rn
dB above reference noise. See also dB rnC
dB rnC
dB(rnC) represents an audio level measurement, typically in a telephone circuit, relative to a −90 dB m reference level, with the measurement of this level frequency-weighted by a standard C-message weighting filter. The C-message weighting filter was chiefly used in North America. The psophometric filter is used for this purpose on international circuits.
dB K
dB(K) – decibels relative to 1 K; used to express noise temperature.
dB K⁻¹ or dB/K
dB(K⁻¹) – decibels relative to 1 K⁻¹. — not decibels per Kelvin: Used for the ⁠ G / T ⁠ (G/T) factor, a figure of merit used in satellite communications, relating the antenna gain G to the receiver system noise equivalent temperature T.

List of suffixes in alphabetical order

Unpunctuated suffixes

dB A
see dB(A).
dB a
see dB rn adjusted.
dB B
see dB(B).
dB c
relative to carrier – in telecommunications, this indicates the relative levels of noise or sideband power, compared with the carrier power.
dB C
see dB(C).
dB D
see dB(D).
dB d
dB(dipole) – the forward gain of an antenna compared with a half-wave dipole antenna. 0 dBd = 2.15 dB i
dB e
dB electrical.
dB f
dB(fW) – power relative to 1 femtowatt.
dB FS
dB(full scale) – the amplitude of a signal compared with the maximum which a device can handle before clipping occurs. Full-scale may be defined as the power level of a full-scale sinusoid or alternatively a full-scale square wave. A signal measured with reference to a full-scale sine-wave appears 3 dB weaker when referenced to a full-scale square wave, thus: 0 dB FS (fullscale sine wave) = −3 dB FS (full-scale square wave).
dB G
G-weighted spectrum
dB i
dB(isotropic) – the forward gain of an antenna compared with the hypothetical isotropic antenna, which uniformly distributes energy in all directions. Linear polarization of the EM field is assumed unless noted otherwise.
dB iC
dB(isotropic circular) – the forward gain of an antenna compared to a circularly polarized isotropic antenna. There is no fixed conversion rule between dB iC and dB i , as it depends on the receiving antenna and the field polarization.
dB J
energy relative to 1 joule: 1 joule = 1 watt-second = 1 watt per hertz, so power spectral density can be expressed in dB J .
dB k
dB(kW) – power relative to 1 kilowatt.
dB K
dB(K) – decibels relative to kelvin: Used to express noise temperature.
dB m
dB(mW) – power relative to 1 milliwatt.
dB m² or dB sm
dB(m²) – decibel relative to one square meter
dB m0
Power in dB m measured at a zero transmission level point.
dB m0s
Defined by Recommendation ITU-R V.574.
dB mV
dB(mVRMS) – voltage relative to 1 millivolt across 75 Ω.
dB o
dB optical. A change of 1 dB o in optical power can result in a change of up to 2 dB e in electrical signal power in system that is thermal noise limited.
dB O
see dB ov
dB ov or dB O
dB(overload) – the amplitude of a signal (usually audio) compared with the maximum which a device can handle before clipping occurs.
dB pp
relative to the peak to peak sound pressure.
dB pp
relative to the maximum value of the peak electrical power.
dB q
dB(quarterwave) – the forward gain of an antenna compared to a quarter wavelength whip. Rarely used, except in some marketing material. 0 dBq = −0.85 dB i
dB r
dB(relative) – simply a relative difference from something else, which is made apparent in context. The difference of a filter's response to nominal levels, for instance.
dB rn
dB above reference noise. See also dB rnC
dB rnC
dB rnC represents an audio level measurement, typically in a telephone circuit, relative to the circuit noise level, with the measurement of this level frequency-weighted by a standard C-message weighting filter. The C-message weighting filter was chiefly used in North America.
dB sm
see dB m²
dB TP
dB(true peak) – peak amplitude of a signal compared with the maximum which a device can handle before clipping occurs.
dB u or dB v
RMS voltage relative to   0.6   V   0.7746   V   2.218   d B V   . {\displaystyle \ {\sqrt {0.6\;}}\ {\mathsf {V}}\ \approx 0.7746\ {\mathsf {V}}\ \approx -2.218\ {\mathsf {dB_{V}}}~.}
dB u0s
Defined by Recommendation ITU-R V.574.
dB uV
see dB μV
dB uV/m
see dB μV/m
dB v
see dB u
dB V
dB(VRMS) – voltage relative to 1 volt, regardless of impedance.
dB VU
dB(VU) dB volume unit
dB W
dB(W) – power relative to 1 watt.
dB W·m⁻²·Hz⁻¹
spectral density relative to 1 W·m⁻²·Hz⁻¹
dB Z
dB(Z) – decibel relative to Z = 1 mm⋅m
dB μ
see dB μV/m
dB μV or dB uV
dB(μVRMS) – voltage relative to 1 root mean square microvolt.
dB μV/m , dB uV/m , or dB μ 
dB(μV/m) – electric field strength relative to 1 microvolt per meter.

Suffixes preceded by a space

dB HL
dB hearing level is used in audiograms as a measure of hearing loss.
dB Q
sometimes used to denote weighted noise level
dB SIL
dB sound intensity level – relative to 10 W/m
dB SPL
dB SPL (sound pressure level) – for sound in air and other gases, relative to 20 μPa in air or 1 μPa in water
dB SWL
dB sound power level – relative to 10 W.

Suffixes within parentheses

dB(A), dB(B), dB(C), dB(D), dB(G), and dB(Z)
These symbols are often used to denote the use of different weighting filters, used to approximate the human ear's response to sound, although the measurement is still in dB (SPL). These measurements usually refer to noise and its effects on humans and other animals, and they are widely used in industry while discussing noise control issues, regulations and environmental standards. Other variations that may be seen are dBA or dBA.

Other suffixes

dB Hz or dB-Hz
dB(Hz) – bandwidth relative to one Hertz
dB K⁻¹ or dB /K
dB(K⁻¹) – decibels relative to reciprocal of kelvin
dB m⁻¹
dB(m⁻¹) – decibel relative to reciprocal of meter: measure of the antenna factor
mB m
mB(mW) – power relative to 1 milliwatt, in millibels (one hundredth of a decibel). 100 mB m = 1 dB m . This unit is in the Wi-Fi drivers of the Linux kernel and the regulatory domain sections.

See also

Notes

  1. "When one gives the value of a quantity, it is incorrect to attach letters or other symbols to the unit in order to provide information about the quantity or its conditions of measurement. Instead, the letters or other symbols should be attached to the quantity."
  2. "When one gives the value of a quantity, any information concerning the quantity or its conditions of measurement must be presented in such a way as not to be associated with the unit. This means that quantities must be defined so that they can be expressed solely in acceptable units..."
  3. See psophometric weighting to see a comparison of frequency response curves for the C-message weighting and psophometric weighting filters.

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Further reading

  • Tuffentsammer, Karl (1956). "Das Dezilog, eine Brücke zwischen Logarithmen, Dezibel, Neper und Normzahlen" [The decilog, a bridge between logarithms, decibel, neper and preferred numbers]. VDI-Zeitschrift (in German). 98: 267–274.
  • Paulin, Eugen (1 September 2007). Logarithmen, Normzahlen, Dezibel, Neper, Phon - natürlich verwandt! [Logarithms, preferred numbers, decibel, neper, phon - naturally related!] (PDF) (in German). Archived (PDF) from the original on 18 December 2016. Retrieved 18 December 2016.

External links

Decibel suffixes (dB)
See also
logarithmic unit
link budget
signal noise
telecommunications
SI units
Base units
Derived units
with special names
Other accepted units
See also
Categories: