Difference between revisions of "Volume" - New World Encyclopedia

Latest revision as of 20:40, 25 January 2016

Conjugate variables of thermodynamics
Pressure	Volume
Temperature	Entropy
Chem. potential	Particle no.

The amount of space occupied by an object or system is called the volume of the object or system. The volume of an object is one of the physical properties of the object. (For other meanings of the term, see Additional meanings of "volume" below.)

The volume of a solid object is given a numerical value that quantifies the amount of three-dimensional space it occupies. A one-dimensional object, such as a line in mathematics, or a two-dimensional object, such as a square, is assigned zero volume in three-dimensional space. In the thermodynamics of non-viscous fluids, volume is regarded as a "conjugate variable" to pressure. If pressure on the fluid is increased, its volume decreases; conversely, if pressure on the fluid is decreased, its volume increases.

Volume is sometimes distinguished from the capacity of a container. The term capacity is used to indicate how much a container can hold (commonly measured in liters or its derived units), and volume indicates how much space the object displaces (commonly measured in cubic meters or its derived units). Alternatively, in a capacity management setting, capacity is defined as volume over a specified time period.

If each side of a cube has length s, the volume of the cube is equal to s³

Volume formulae

Common equations for volume:
Shape	Equation	Variables
A cube:	$s^{3}=s\cdot s\cdot s$	s = length of a side
A rectangular prism:	$l\cdot w\cdot h$	l = length, w = width, h = height
A cylinder (circular prism):	$\pi r^{2}\cdot h$	r = radius of circular face, h = distance between faces
Any prism that has a constant cross sectional area along the height:	$A\cdot h$	A = area of the base, h = height
A sphere:	${\frac {4}{3}}\pi r^{3}$	r = radius of sphere which is the first integral of the formula for Surface Area of a sphere
An ellipsoid:	${\frac {4}{3}}\pi abc$	a, b, c = semi-axes of ellipsoid
A pyramid:	${\frac {1}{3}}Ah$	A = area of base, h = height from base to apex
A cone (circular-based pyramid):	${\frac {1}{3}}\pi r^{2}h$	r = radius of circle at base, h = distance from base to tip
Any figure (integral calculus required)	$\int A(h)dh$	h = any dimension of the figure, A(h) = area of the cross-sections perpendicular to h described as a function of the position along h. (This will work for any figure, no matter if the prism is slanted or the cross-sections change shape).

Mathematically, the volume of a body may be defined by means of integral calculus. In this approach, the volume of the body is taken to be approximately equal to the sum of volumes of a large number of small cubes or concentric cylindrical shells, and adding the individual volumes of those shapes.

Volume measures: United States

U.S. customary units of volume include the following:

U.S. fluid ounce, about 29.6 milliliters (mL)
U.S. liquid pint = 16 fluid ounces, or about 473 mL
U.S. dry pint = 1/64 U.S. bushel, or about 551 mL (used for things such as blueberries)
U.S. liquid quart = 32 fluid ounces (two U.S. pints), or about 946 mL
U.S. dry quart = 1/32 U.S. bushel, or about 1.101 liters (L)
U.S. liquid gallon = 128 fluid ounces or four U.S. quarts, about 3.785 L
U.S. dry gallon = 1/8 U.S. bushel, or about 4.405 L
U.S. (dry level) bushel = 2150.42 cubic inches, or about 35.239 L

cubic inch = 16.387 064 centimeters³
cubic foot = 1,728 inches³ ≈ 28.317 decimeters³
cubic yard = 27 feet³ ≈ 0.7646 meters³
cubic mile = 5,451,776,000 yards³ = 3,379,200 acre-feet ≈ 4.168 kilometers³

The acre foot is often used in measuring the volume of water in a reservoir or aquifer. It is the volume of water that would cover an area of one acre to a depth of one foot. It is equivalent to 43,560 cubic feet or 1233.481 cubic meters.

Volume measures: UK

The United Kingdom is increasingly using units of volume according to the SI metric system, namely, the cubic meter and liter. However, some former units of volume are still being used in varying degrees.

Imperial units of volume:

UK fluid ounce = about 28.4 mL (this equals the volume of an avoirdupois ounce of water under certain conditions)
UK pint = 20 fluid ounces, or about 568 mL
UK quart = 40 ounces or two pints, 1.137 L
UK gallon = 4 quarts, or exactly 4.546 09 L

Volume measures: cooking

Traditional cooking measures for volume also include:

teaspoon = 1/6 U.S. fluid ounce (about 4.929 mL)
teaspoon = 1/6 Imperial fluid ounce (about 4.736 mL) (Canada)
teaspoon = 5 mL (metric)
tablespoon = ½ U.S. fluid ounce or 3 teaspoons (about 14.79 mL)
tablespoon = ½ Imperial fluid ounce or 3 teaspoons (about 14.21 mL) (Canada)
tablespoon = 15 mL or 3 teaspoons (metric)
tablespoon = 5 fluidrams (about 17.76 mL) (British)
cup = 8 U.S. fluid ounces or one-half U.S. liquid pint (about 237 mL)
cup = 8 Imperial fluid ounces or one-half fluid pint (about 227 mL) (Canada)
cup = 250 mL (metric)

Relationship to density

The volume of an object is equal to its mass divided by its average density (the term "average density" is used for an object that does not have uniform density). This is a rearrangement of the calculation of density as mass per unit volume.

The term "specific volume" is used for volume divided by mass, expressed in units such as cubic meters per kilogram (m³•kg^-1). It is the reciprocal of density.

Orders of magnitude (volume)

List of orders of magnitude for volume
Factor (meters³*)	Multiple	Value
10⁻¹⁰⁵	—	4×10⁻¹⁰⁵ m³ is the Planck volume
10⁻⁴⁵	—	Volume of a proton
10⁻³³	—	Volume of a hydrogen atom (6.54×10^-32 meters³)
10⁻²¹	1 attoliter	Volume of a typical virus (5 attoliters)
10⁻¹⁵	1 picoliter	A small grain of sand (0.063 millimeter diameter, 3 micrograms, 130 picoliters)
10⁻¹²	1 nanoliter	A medium grain of sand (0.5 millimeter diameter, 1.5 milligrams, 62 nanoliters)
10⁻⁹	1 microliter	A large grain of sand (2.0 millimeter diameter, 95 milligrams, 4 microliters)
10⁻⁶	1 milliliter (1 cubic centimeter)	1 teaspoon = 3.55 mL to 5 mL 1 tablespoon = 14.2 mL to 20 mL
10⁻³	1 liter (1 cubic decimeter)	1 U.S. quart = 0.95 liters; 1 United Kingdom quart = 1.14 liters
10⁰	1000 liters	Fuel tank for a 12-passenger turboprop airplane
10³	1000 cubic meters (1 million liters)	A medium-size forest pond. An Olympic-size swimming pool, 25 meters by 50 meters by 2 meters deep, holds at least 2.5 megaliters.
10⁶	1 million cubic meters	—
10⁹	1 cubic kilometer (km³)	Volume of Lake Mead (Hoover Dam) = 35.2 km³ Volume of crude oil on Earth = ~300 km³
10¹²	1000 cubic kilometers	Volume of Lake Superior = 12,232 km³
10¹⁵	—	—
10¹⁸	—	Volume of water in all Earth oceans = 1.3×10¹⁸
10²¹	—	Volume of Earth = ~1×10²¹ m³
10²⁴	—	Volume of Jupiter = ~1×10²⁵ m³
10²⁷	—	Volume of the Sun = ~1×10²⁷ m³
10³⁰	—	Volume of a red giant the same mass as the Sun = ~5×10³² m³
10³³	—	Volume of Betelgeuse = ~2.75×10³⁵ m³
10⁵⁴	—	Volume of small dwarf galaxy like NGC 1705 = ~3×10⁵⁵ m³
10⁵⁷	—	Volume of dwarf galaxy like the Large Magellanic Cloud = ~3×10⁵⁸ m³
10⁶⁰	—	Volume of galaxy like the Milky Way = ~3.3×10⁶¹ m³
10⁶⁶	—	Volume of the Local Group (galaxy group that includes the Milky Way) = ~5×10⁶⁸ m³
10⁷²	—	Volume of the Virgo Supercluster = ~4×10⁷³ m³
10⁸¹	—	Approximate volume of the observable universe 1.6×10⁸¹ m³

Additional meanings of "volume"

Besides the above meaning, the term "volume" can refer to the following concepts:

Volume form in mathematics.
Loudness, in acoustics. It is related to:
- Amplitude of the sound wave
- Sound pressure level
- Dynamics, in music.
Quantity, as in "the volume of ticket sales."
Volume, in computing, is a storage area with a single file system, typically residing on a single partition of a hard disk.
Volume is a term in data compression, for a file that has been compressed and split into different parts.

References
ISBN links support NWE through referral fees

Kensler, Chris. 2003. Secrets Treasures and Magical Measures: Adventures in Measurement: Temperature, Time, Length, Weight, Volume, Angles, Shape and Money. New York, NY: Kaplan Publishing. ISBN 0743235258
Ness, Richard M. 1999. “Surfaces and Volumes of Common Shapes.” Ness Engineering Technical Data. Retrieved November 14, 2008.
Kay, David. 2000. College Geometry: A Discovery Approach, 2nd ed. Boston, MA: Addison Wesley. ISBN 0321046242

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History of "Volume"

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@@ Line 1: / Line 1: @@
-{{Copyedited}}{{Paid}}{{Contracted}}{{Images OK}}{{Submitted}}{{Approved}}
+{{Copyedited}}{{Paid}}{{Images OK}}{{Submitted}}{{Approved}}
-[[Image:Hexahedron.jpg|200px|thumb|left|If each side of a cube has length ''s'', the volume of the cube is equal to ''s''<sup>3</sup>]]
 {{Conjugate variables (thermodynamics)}}
 The amount of space occupied by an object or system is called the '''volume''' of the object or system. The volume of an object is one of the physical properties of the object. (For other meanings of the term, see [[#Additional meanings of "volume"|Additional meanings of "volume"]] below.)
-The volume of a solid object is given a numerical value that quantifies the amount of three-[[dimension]]al [[space]] it occupies. A one-dimensional object, such as a [[line (mathematics)|line]] in mathematics, or a two-dimensional object, such as a [[square (geometry)|square]], is assigned zero volume in three-dimensional space. In the [[thermodynamics]] of non-viscous fluids, volume is regarded as a "[[conjugate variables (thermodynamics)|conjugate variable]]*" to [[pressure]]. If pressure on the fluid is increased, its volume decreases; conversely, if pressure on the fluid is decreased, its volume increases.
+The volume of a solid object is given a numerical value that quantifies the amount of three-[[dimension]]al [[space]] it occupies. A one-dimensional object, such as a [[line (mathematics)|line]] in mathematics, or a two-dimensional object, such as a [[square (geometry)|square]], is assigned zero volume in three-dimensional space. In the [[thermodynamics]] of non-viscous fluids, volume is regarded as a "[[conjugate variables (thermodynamics)|conjugate variable]]" to [[pressure]]. If pressure on the fluid is increased, its volume decreases; conversely, if pressure on the fluid is decreased, its volume increases.
+{{toc}}
 Volume is sometimes distinguished from the capacity of a container. The term capacity is used to indicate how much a container can hold (commonly measured in liters or its derived units), and volume indicates how much space the object displaces (commonly measured in cubic meters or its derived units). Alternatively, in a capacity management setting, capacity is defined as volume over a specified time period.
+[[Image:Hexahedron.jpg|200px|thumb|left|If each side of a cube has length ''s'', the volume of the cube is equal to ''s''<sup>3</sup>]]
-<br clear="all">
 == Volume formulae ==
 {| class=prettytable
@@ Line 36: / Line 35: @@
 |A [[sphere]]:
 |<math>\frac{4}{3} \pi r^3</math>
-|''r'' = radius of sphere<br/>which is the first [[integral]]* of the [[formula]]* for [[Surface Area]]* of a [[sphere]]*
+|''r'' = radius of sphere<br/>which is the first [[integral]] of the [[formula]] for [[Surface Area]] of a [[sphere]]
 |-
 |An [[ellipsoid]]:
@@ Line 60: / Line 59: @@
 ==Volume measures: United States==
-[[U.S. customary units]]* of volume include the following:
+[[U.S. customary units]] of volume include the following:
 *U.S. fluid [[ounce]], about 29.6 milliliters (mL)
@@ Line 71: / Line 70: @@
 *U.S. (dry level) bushel = 2150.42 cubic inches, or about 35.239 L
-*[[cubic inch]]* = 16.387 064 centimeters<sup>3</sup>
+*[[cubic inch]] = 16.387 064 centimeters<sup>3</sup>
-*[[cubic foot]]* = 1,728 inches<sup>3</sup> ≈ 28.317 decimeters<sup>3</sup>
+*[[cubic foot]] = 1,728 inches<sup>3</sup> ≈ 28.317 decimeters<sup>3</sup>
-*[[cubic yard]]* = 27 feet<sup>3</sup> ≈ 0.7646 meters<sup>3</sup>
+*[[cubic yard]] = 27 feet<sup>3</sup> ≈ 0.7646 meters<sup>3</sup>
-*[[cubic mile]]* = 5,451,776,000 yards<sup>3</sup> = 3,379,200 acre-feet ≈ 4.168 kilometers<sup>3</sup>
+*[[cubic mile]] = 5,451,776,000 yards<sup>3</sup> = 3,379,200 acre-feet ≈ 4.168 kilometers<sup>3</sup>
-The '''acre foot''' is often used in measuring the volume of water in a [[reservoir (water)|reservoir]] or [[aquifer]]. It is the volume of water that would cover an [[area]] of one [[acre]] to a depth of one [[foot (unit of length)|foot]]*. It is equivalent to 43,560 cubic feet or 1233.481 cubic meters.
+The '''acre foot''' is often used in measuring the volume of water in a [[reservoir (water)|reservoir]] or [[aquifer]]. It is the volume of water that would cover an [[area]] of one [[acre]] to a depth of one [[foot (unit of length)|foot]]. It is equivalent to 43,560 cubic feet or 1233.481 cubic meters.
 ==Volume measures: UK==
@@ Line 82: / Line 81: @@
 The [[United Kingdom]] is increasingly using units of volume according to the [[International System of Units |SI metric system]], namely, the [[cubic meter]] and [[liter]]. However, some former units of volume are still being used in varying degrees.
-[[Imperial units]]* of volume:
+[[Imperial units]] of volume:
 *UK fluid [[ounce]] = about 28.4 mL (this equals the volume of an avoirdupois ounce of water under certain conditions)
 *UK [[pint]] = 20 fluid ounces, or about 568 mL
@@ Line 92: / Line 91: @@
 Traditional cooking measures for volume also include:
-*[[teaspoon]]* = 1/6 U.S. fluid ounce (about 4.929 mL)
+*[[teaspoon]] = 1/6 U.S. fluid ounce (about 4.929 mL)
 *teaspoon = 1/6 Imperial fluid ounce (about 4.736 mL) (Canada)
 *teaspoon = 5 mL (metric)
-*[[tablespoon]]* = ½ U.S. fluid ounce or 3 teaspoons (about 14.79 mL)
+*[[tablespoon]] = ½ U.S. fluid ounce or 3 teaspoons (about 14.79 mL)
 *tablespoon = ½ Imperial fluid ounce or 3 teaspoons (about 14.21 mL) (Canada)
 *tablespoon = 15 mL or 3 teaspoons (metric)
-*tablespoon = 5 [[fluidram]]*s (about 17.76 mL) (British)
+*tablespoon = 5 [[fluidram]]s (about 17.76 mL) (British)
-*[[Cup (unit)|cup]]* = 8 U.S. fluid ounces or one-half U.S. liquid pint (about 237 mL)
+*[[Cup (unit)|cup]] = 8 U.S. fluid ounces or one-half U.S. liquid pint (about 237 mL)
 *cup = 8 Imperial fluid ounces or one-half fluid pint (about 227 mL) (Canada)
 *cup = 250 mL (metric)
@@ Line 105: / Line 104: @@
 ==Relationship to density==
-The volume of an object is [[equality (mathematics)|equal]]* to its [[mass]] [[division (mathematics)|divided]] by its [[average]] [[density]] (the term "average density" is used for an object that does not have uniform density). This is a rearrangement of the calculation of density as mass per unit volume.
+The volume of an object is [[equality (mathematics)|equal]] to its [[mass]] [[division (mathematics)|divided]] by its [[average]] [[density]] (the term "average density" is used for an object that does not have uniform density). This is a rearrangement of the calculation of density as mass per unit volume.
-The term "[[specific volume]]*" is used for volume divided by mass, expressed in units such as cubic meters per kilogram (m³•kg<sup>-1</sup>). It is the [[reciprocal]]* of [[density]].
+The term "[[specific volume]]" is used for volume divided by mass, expressed in units such as cubic meters per kilogram (m³•kg<sup>-1</sup>). It is the [[reciprocal]] of [[density]].
 == Orders of magnitude (volume) ==
@@ Line 149: / Line 148: @@
 |10<sup>−6</sup>
 |1 milliliter<br/>(1 cubic centimeter)
-|1 [[teaspoon]]* = 3.55 mL to 5 mL<br/>
+|1 [[teaspoon]] = 3.55 mL to 5 mL<br/>
-[[tablespoon]]* = 14.2 mL to 20 mL
+[[tablespoon]] = 14.2 mL to 20 mL
 |-
 |10<sup>−3</sup>
@@ Line 158: / Line 157: @@
 |10<sup>0</sup>
 |'''1000 liters'''
-|Fuel tank for a 12-passenger [[turboprop]]* [[fixed-wing aircraft|airplane]]*
+|Fuel tank for a 12-passenger [[turboprop]] [[fixed-wing aircraft|airplane]]
 |-
 |10<sup>3</sup>
@@ Line 171: / Line 170: @@
 |1 cubic kilometer (km<sup>3</sup>)
 |Volume of [[Lake Mead]] ([[Hoover Dam]]) = 35.2&nbsp;km<sup>3</sup><br/>
-Volume of [[crude oil]]* on Earth = ~300 km<sup>3</sup>
+Volume of [[crude oil]] on Earth = ~300 km<sup>3</sup>
 |-
 |10<sup>12</sup>
@@ Line 199: / Line 198: @@
 |10<sup>30</sup>
 | —
-|Volume of a [[red giant]]* the same mass as the Sun = ~5{{e|32}}&nbsp;m<sup>3</sup>
+|Volume of a [[red giant]] the same mass as the Sun = ~5{{e|32}}&nbsp;m<sup>3</sup>
 |-
 |10<sup>33</sup>
 | —
-|Volume of [[Betelgeuse]]* = ~2.75{{e|35}}&nbsp;m<sup>3</sup>
+|Volume of [[Betelgeuse]] = ~2.75{{e|35}}&nbsp;m<sup>3</sup>
 |-
 |10<sup>54</sup>
@@ Line 211: / Line 210: @@
 |10<sup>57</sup>
 | —
-|Volume of dwarf galaxy like the [[Large Magellanic Cloud]]* = ~3{{e|58}}&nbsp;m<sup>3</sup>
+|Volume of dwarf galaxy like the [[Large Magellanic Cloud]] = ~3{{e|58}}&nbsp;m<sup>3</sup>
 |-
 |10<sup>60</sup>
@@ Line 219: / Line 218: @@
 |10<sup>66</sup>
 | —
-|Volume of the [[Local Group]]* (galaxy group that includes the Milky Way) = ~5{{e|68}}&nbsp;m<sup>3</sup>
+|Volume of the [[Local Group]] (galaxy group that includes the Milky Way) = ~5{{e|68}}&nbsp;m<sup>3</sup>
 |-
 |10<sup>72</sup>
 | —
-|Volume of the [[Virgo Supercluster]]* = ~4{{e|73}}&nbsp;m<sup>3</sup>
+|Volume of the [[Virgo Supercluster]] = ~4{{e|73}}&nbsp;m<sup>3</sup>
 |-
 |10<sup>81</sup>
@@ Line 234: / Line 233: @@
 Besides the above meaning, the term "volume" can refer to the following concepts:
-* [[Volume form]]* in mathematics.
+* [[Volume form]] in mathematics.
-* [[Loudness]]*, in [[acoustics]]. It is related to:
+* [[Loudness]], in [[acoustics]]. It is related to:
-** [[Amplitude]]* of the sound wave
+** [[Amplitude]] of the sound wave
-** [[Sound pressure level]]*
+** [[Sound pressure level]]
-** [[Dynamics]]*, in [[music]].
+** [[Dynamics]], in [[music]].
 * [[Quantity]], as in "the ''volume'' of ticket sales."
 * Volume, in [[computer|computing]], is a storage area with a single file system, typically residing on a single partition of a hard disk.
@@ Line 245: / Line 244: @@
 == References ==
-* Kensler, Chris (2003). ''Secrets Treasures and Magical Measures: Adventures in Measurement: Temperature, Time, Length, Weight, Volume, Angles, Shape and Money''. New York, NY: Kaplan Publishing. ISBN 0743235258
+* Kensler, Chris. 2003. ''Secrets Treasures and Magical Measures: Adventures in Measurement: Temperature, Time, Length, Weight, Volume, Angles, Shape and Money''. New York, NY: Kaplan Publishing. ISBN 0743235258
-* Ness, Richard M. (1999). [http://home.san.rr.com/nessengr/techdata/volume/surfvolum.html “Surfaces and Volumes of Common Shapes.”] Ness Engineering Technical Data. Retrieved July 23, 2007.
+* Ness, Richard M. 1999. [http://www.nessengr.com/techdata/volume/surfvolum.html “Surfaces and Volumes of Common Shapes.”] Ness Engineering Technical Data. Retrieved November 14, 2008.
-* Kay, David (2000). ''College Geometry: A Discovery Approach'', 2nd ed. Boston, MA: Addison Wesley. ISBN 0321046242
+* Kay, David. 2000. ''College Geometry: A Discovery Approach'', 2nd ed. Boston, MA: Addison Wesley. ISBN 0321046242
 == See also ==
 *[[Area]]
-*[[Conversion of units#Volume|Conversion of units]]
 *[[Density]]
 *[[Mass]]
 *[[Pressure]]
-==External links==
-All links retrieved July 23, 2007.
-* [http://www.phy.ilstu.edu/~mnorton/Geometry.txt FORTRAN code for finding volumes of various shapes]
 [[Category:Physical sciences]]