Editing Statics

{{Short description|Branch of mechanics concerned with balance of forces in nonmoving systems}}
{{About||the concept in economics|Comparative statics|the concept in exploration geophysics|Static correction (disambiguation){{!}}Static|other uses|Static analysis}}
{{distinguish|statistics}}
{{Classical mechanics|cTopic=Branches}}

'''Statics''' is the branch of [[classical mechanics]] that is concerned with the analysis of [[force]] and [[torque]] acting on a [[physical system]] that does not experience an [[acceleration]], but rather is in [[mechanical equilibrium|equilibrium]] with its environment. 

If <math>\textbf F</math> is the total of the forces acting on the system, <math>m</math> is the mass of the system and <math>\textbf a</math> is the acceleration of the system, [[Newton's second law]] states that <math> \textbf F = m \textbf a \,</math> (the bold font indicates a [[Euclidean vector|vector]] quantity, i.e. one with both [[Magnitude (mathematics)|magnitude]] and [[Direction (geometry)|direction]]). If <math>\textbf a =0</math>, then <math> \textbf F = 0</math>. As for a system in static equilibrium, the acceleration equals zero, the system is either at rest, or its [[center of mass]] moves at constant [[velocity]]. 

The application of the assumption of zero acceleration to the summation of [[Moment (physics)|moment]]s acting on the system leads to <math> \textbf M = I \alpha  = 0</math>, where <math>\textbf M</math> is the summation of all moments acting on the system, <math>I</math> is the moment of inertia of the mass and <math>\alpha</math> is the angular acceleration of the system. For a system where <math>\alpha = 0</math>, it is also true that <math> \textbf M = 0.</math>

Together, the equations <math> \textbf F = m \textbf a = 0</math> (the 'first condition for equilibrium') and <math> \textbf M = I \alpha  = 0</math> (the 'second condition for equilibrium') can be used to solve for unknown quantities acting on the system.

==History==
[[Archimedes]] (c. 287–c. 212 BC) did pioneering work in statics.<ref>{{cite book|last=Lindberg|first=David C.|title=The Beginnings of Western Science|url=https://archive.org/details/beginningsofwest00lind|url-access=registration|year=1992|publisher=The University of Chicago Press|location=Chicago|page=[https://archive.org/details/beginningsofwest00lind/page/108 108-110]|isbn=9780226482316}}</ref><ref>{{cite book|last=Grant|first=Edward|title=A History of Natural Philosophy|url=https://archive.org/details/historynaturalph00gran|url-access=limited|year=2007|publisher=Cambridge University Press|location=New York|page=[https://archive.org/details/historynaturalph00gran/page/n324 309]-10}}</ref>
Later developments in the field of statics are found in works of [[Thābit ibn Qurra|Thebit]].<ref name="holme">{{cite book|last=Holme|first=Audun|title=Geometry : our cultural heritage|url=https://archive.org/details/geometryourcultu00ahol|url-access=limited|date=2010|publisher=Springer|location=Heidelberg|isbn=978-3-642-14440-0|edition=2nd|page=[https://archive.org/details/geometryourcultu00ahol/page/n206 188]}}</ref>

==Background==

===Force===
''[[Force]]'' is the action of one body on another. A force is either a push or a pull, and it tends to move a body in the direction of its action. The action of a force is characterized by its magnitude, by the direction of its action, and by its ''point of application'' (or ''point of contact''). Thus, force is a vector quantity, because its effect depends on the direction as well as on the magnitude of the action.<ref>Meriam, James L., and L. Glenn Kraige. ''Engineering Mechanics'' (6th ed.)  Hoboken, N.J.: John Wiley & Sons, 2007; p. 23.</ref>

Forces are classified as either contact or body forces. A [[contact force]] is produced by direct physical contact; an example is the force exerted on a body by a supporting surface. A [[body force]] is generated by virtue of the position of a body within a [[force field (physics)|force field]] such as a gravitational, electric, or magnetic field and is independent of contact with any other body; an example of a body force is the weight of a body in the Earth's gravitational field.<ref>''Engineering Mechanics'', p. 24</ref>

===Moment of a force===
In addition to the tendency to move a body in the direction of its application, a force can also tend to rotate a body about an axis. The axis may be any line which neither intersects nor is parallel to the [[line of action]] of the force. This rotational tendency is known as ''[[moment of force]]'' ('''M'''). Moment is also referred to as ''torque''.

====Moment about a point====
[[File:Diagram of the moment arm of a force F.svg|thumb|Diagram of the moment arm of a force F.]]
The magnitude of the moment of a force at a point ''O'', is equal to the perpendicular distance from ''O'' to the line of action of ''F'', multiplied by the magnitude of the force: {{nowrap|1=''M'' = ''F'' &middot; ''d''}}, where

: ''F'' = the force applied
: ''d'' = the perpendicular distance from the axis to the line of action of the force. This perpendicular distance is called the moment arm.

The direction of the moment is given by the right hand rule, where counter clockwise (CCW) is out of the page, and clockwise (CW) is into the page. The moment direction may be accounted for by using a stated sign convention, such as a plus sign (+) for counterclockwise moments and a minus sign (−) for clockwise moments, or vice versa. Moments can be added together as vectors.

In vector format, the moment can be defined as the [[cross product]] between the radius vector, '''r''' (the vector from point O to the line of action), and the force vector, '''F''':<ref>{{cite book|last=Hibbeler|first=R. C.|title=Engineering Mechanics: Statics, 12th Ed.|url=https://archive.org/details/staticsstudypack00russ|url-access=registration|year=2010|publisher=Pearson Prentice Hall|location=New Jersey|isbn=978-0-13-607790-9}}</ref>

:<math>\textbf{M}_{O}=\textbf{r} \times \textbf{F}</math>
:<math>r=\left(
\begin{array}{cc}
 x_{00} & ...  & x_{0j}\\
 x_{01} & ...  & x_{1j}\\
 ... & ... & ... \\
  x_{i0} & ...  & x_{ij}\\
 
\end{array}
\right)</math>
:<math>F=\left(
\begin{array}{cc}
 f_{00} & ...  & f_{0j}\\
 f_{01} & ...  & f_{1j}\\
 ... & ... & ... \\
  f_{i0} & ...  & f_{ij}\\
 
\end{array}
\right)</math>
:

====Varignon's theorem====
''[[Varignon's theorem (mechanics)|Varignon's theorem]]'' states that the moment of a force about any point is equal to the sum of the moments of the components of the force about the same point.

===Equilibrium equations===
The [[mechanical equilibrium|static equilibrium]] of a particle is an important concept in statics. A particle is in equilibrium only if the resultant of all forces acting on the particle is equal to zero. In a rectangular coordinate system the equilibrium equations can be represented by three scalar equations, where the sums of forces in all three directions are equal to zero. An [[engineering]] application of this concept is determining the tensions of up to three cables under load, for example the forces exerted on each cable of a hoist lifting an object or of [[guy wires]] restraining a [[hot air balloon]] to the ground.<ref>{{cite book|last=Beer|first=Ferdinand|title=Vector Statics For Engineers|publisher=McGraw Hill|year=2004|isbn=0-07-121830-0}}</ref>

===Moment of inertia===
In classical mechanics, ''[[moment of inertia]]'', also called mass moment, rotational inertia, polar moment of inertia of mass, or the angular mass, (SI units kg·m²) is a measure of an object's resistance to changes to its rotation. It is the inertia of a rotating body with respect to its rotation. The moment of inertia plays much the same role in rotational dynamics as mass does in linear dynamics, describing the relationship between angular momentum and angular velocity, torque and angular acceleration, and several other quantities. The symbols I and J are usually used to refer to the moment of inertia or polar moment of inertia.

While a simple scalar treatment of the moment of inertia suffices for many situations, a more advanced tensor treatment allows the analysis of such complicated systems as spinning tops and gyroscopic motion.

The concept was introduced by [[Leonhard Euler]] in his 1765 book ''Theoria motus corporum solidorum seu rigidorum''; he discussed the moment of inertia and many related concepts, such as the principal axis of inertia.

==Applications==

===Solids===
Statics is used in the analysis of structures, for instance in [[architectural engineering|architectural]] and [[structural engineering]]. ''[[Strength of materials]]'' is a related field of mechanics that relies heavily on the application of static equilibrium. A key concept is the [[center of gravity]] of a body at rest: it represents an imaginary point at which all the [[mass]] of a body resides. The position of the point relative to the [[Foundation (engineering)|foundation]]s on which a body lies determines its [[Stability theory|stability]] in response to external forces. If the center of gravity exists outside the foundations, then the body is unstable because there is a torque acting: any small disturbance will cause the body to fall or topple. If the center of gravity exists within the foundations, the body is stable since no net torque acts on the body. If the center of gravity coincides with the foundations, then the body is said to be [[metastable]].

===Fluids===
''[[Hydrostatics]]'', also known as ''[[fluid statics]]'', is the study of fluids at rest (i.e. in static equilibrium). The characteristic of any fluid at rest is that the force exerted on any particle of the fluid is the same at all points at the same depth (or altitude) within the fluid. If the net force is greater than zero the fluid will move in the direction of the resulting force. This concept was first formulated in a slightly extended form by [[France|French]] [[mathematician]] and [[philosopher]] [[Blaise Pascal]] in 1647 and became known as [[Pascal's law]]. It has many important applications in [[hydraulics]]. [[Archimedes]], [[Abū Rayhān al-Bīrūnī]], [[Al-Khazini]]<ref name=Rozhanskaya-642>Mariam Rozhanskaya and I. S. Levinova (1996), "Statics", p. 642, in {{Harv|Morelon|Rashed|1996|pp=614–642}}: {{quote|"Using a whole body of mathematical methods (not only those inherited from the antique theory of ratios and infinitesimal techniques, but also the methods of the contemporary algebra and fine calculation techniques), Arabic scientists raised statics to a new, higher level. The classical results of Archimedes in the theory of the centre of gravity were generalized and applied to three-dimensional bodies, the theory of ponderable lever was founded and the 'science of gravity' was created and later further developed in medieval Europe. The phenomena of statics were studied by using the dynamic approach so that two trends - statics and dynamics - turned out to be inter-related within a single science, mechanics. The combination of the dynamic approach with Archimedean hydrostatics gave birth to a direction in science which may be called medieval hydrodynamics. [...] Numerous experimental methods were developed for determining the specific weight, which were based, in particular, on the theory of balances and weighing. The classical works of al-Biruni and al-Khazini may be considered the beginning of the application of experimental methods in [[medieval science]]."}}</ref> and [[Galileo Galilei]] were also major figures in the development of hydrostatics.

==See also==
*[[Cremona diagram]]
*[[Dynamics (mechanics)|Dynamics]]
*[[Solid mechanics]]
{{Portal|Physics}}

==Notes==
{{Reflist}}

==References==
*{{cite book|author1=Beer, F.P.  |author2=Johnston Jr, E.R. |name-list-style=amp |title=Statics and Mechanics of Materials|year=1992|publisher=McGraw-Hill, Inc}}
*{{cite book|author1=Beer, F.P.|author2=Johnston Jr, E.R.|author3=Eisenberg|title=Vector Mechanics for Engineers: Statics, 9th Ed.|year=2009|isbn=978-0-07-352923-3|publisher=McGraw Hill}}
* {{Citation |editor-last1=Morelon |editor-first1=Régis |editor-last2=Rashed |editor-first2=Roshdi |year=1996 |title=Encyclopedia of the History of Arabic Science |volume=3 |publisher=Routledge |isbn=978-0415124102 |title-link=Encyclopedia of the History of Arabic Science}}

==External links==
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{{Wikibooks|Statics}}

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