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[[भौतिक शास्त्र]]य्, '''बल''' धागु वस्तुय् प्रवेग (एसेलेरेसन) देकिगु वा एसेलेरेसन दुगु वस्तुय् एसेलेरेसन म्होयाइगु प्रभाव खः।
 
थ्व छगु [[भेक्टर मात्रा]] खः। थुकियात "बल याकचां छुं न वस्तुयु इन्डुसयाइगु [[मोमेन्टम]]यु परिवर्तनयु दर" धका परिभाषित यागु दु।
 
== इतिहास ==
* बलयात दक्ले न्हापां [[आर्किमिडिज]]नं बयान याना दिल।.
* [[ग्यालिलियो]] नं rolling balls छ्येला [[एरिस्टोटलयु गुरुत्वाकर्षण सिद्धान्त]] मखुगु पुष्टि याना दिल।([[१६०२]] - [[१६०७]])
* [[आइज्याक न्युटन]] नं बलयु दक्ले न्हापांगु गणितीय परिभाषा बियादिल।.
* [[चार्ल्स कुलम्ब]] नं [[एलेक्ट्रिक चार्ज]]तेगु दथुइ बलयागु इन्भर्स स्क्वायर विधान पलिस्था याना दिल ([[ई सं १७८४]])
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* With the development of [[quantum field theory]] and [[general relativity]] in [[20th century|20<sup>th</sup> century]] it was realised that “force” is strictly a concept which arises from each theory in a totally different way and in both theories, it is only a helping concept which cannot be physically correct. In QFT, the force is arising from conservation of momentum of interacting [[elementary particle]]s. In GR, the [[gravitational force]] is arising from a curved [[spacetime]]. Thus currently known [[fundamental forces]] are not called forces but “[[fundamental interactions]]”.
[[Aristotle]] and others believed that it was the ''natural state'' of objects on Earth to be motionless, and that they tended toward that state (eventually settling down to inertness), if left alone. This was a common experience of humans with ordinary conditions in which friction was involved, so Newton's idea that force naturally produces a constant increase in velocity was not an obvious one. Frictional forces, acting in opposition to other kinds of forces, historically tended to hide the correct mathematical relationship between simple unopposed force and motion.
 
The correct behavior of objects accelerated by constant force was first discovered by [[Galileo]] in working with gravity (dropping stones and rolling cannonballs on an incline), although it was not until Newton that gravity was seen as a force. [[Isaac Newton|Newton]] generalized the behavior of constant acceleration, or constant momentum gain, to forces other than gravity. He asserted in his second law of motion that this behavior of constant momentum increase was characteristic of all forces-- including the “forces” of ordinary experience, such as tension or the stress produced by pushing on an object with a finger. In fact, he defined force as mass times acceleration, or more accurately, as a rate of change of momentum. Though, he understood that his definition is incorrect because it is a [[circular definition]]. The definition of term “force” needs a definition of the term [[Inertial frame of reference]] which is defined using the term “force”. Therefore the definition of the term “force” can be only [[Intuition (knowledge)|intuitive]]. This problem was solved in 20<sup>th</sup> century in [[quantum field theory]] and [[general relativity]] which use this term only secondarily and it is not necessary to define it in these theories at all.
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This is the form Newton's second law is usually taught in introductory physics courses in order to avoid calculus notation.
 
All known forces of nature are defined via the above Newtonian definition of force. For example, weight (force of gravity) is defined as mass times acceleration of free fall: w = mg; spring balance force is defined as the force equilibrating certain gravitational force (say, the weight of 1 kg mass near Earth surface results in reaction force of spring equivalent to 9.8 N), etc. Calibration of spring balances (of various kinds) using either gravitational force or motion with known acceleration is important starting procedure in measuring many other forces (such as friction forces, reaction forces, electric forces, magnetic force, etc) in various physics labs.
 
It is not always the case that ''m'' is independent of ''t''. For example, the mass of a [[rocket]] decreases as its propellant is ejected. Under such circumstances, the above equation (<math>\vec{F} = m\vec{a} </math>) is incorrect, and the original form of Newton's second law must be used.
 
Because momentum is a [[vector (physics)|vector]], then force, being its time derivative, is also a vector - it has [[magnitude]] and [[Direction (geometry, geography)|direction]], and [[four-force]] is a [[four-vector]] in relativity. Vectors (and thus forces) are added together by their [[Spacial vector|componentcomponents]]s. When two forces act on an object, the resulting force, the ''resultant'', is the [[vector addition|vector sum]] of the original forces. This is called the principle of [[superposition]]. The magnitude of the resultant varies from the difference of the magnitudes of the two forces to their sum, depending on the angle between their lines of action. As with all vector addition this results in a [[parallelogram rule]]: the addition of two vectors represented by sides of a parallelogram, gives an equivalent resultant vector which is equal in magnitude and direction to the transversal of the parallelogram. If the two forces are equal in magnitude but opposite in direction, then the resultant is zero. This condition is called [[static equilibrium]], with the result that the object remains at its constant velocity (which could be zero). Static equilibrium is mathematically equivalent to the motion expected with equal and oppositely directed [[acceleration]]s (of course it is the same motion as with no acceleration).
 
As well as being added, forces can also be broken down (or 'resolved'). For example, a horizontal force pointing northeast can be split into two forces, one pointing north, and one pointing east. Summing these component forces using vector addition yields the original force. Force vectors can also be three-dimensional, with the third (vertical) component at right-angles to the two horizontal components.
 
In most explanations of [[mechanics]], force is usually defined only implicitly, in terms of the equations that work with it. Some physicists, philosophers and mathematicians, such as [[Ernst Mach]], [[Clifford Truesdell]] and [[Walter Noll]], have found this problematic and sought a more explicit definition of force.
 
=== Force in special relativity ===
In the [[special theory of relativity]] mass and [[energy]] are equivalent (as can be seen by calculating the work required to accelerate a body). When an object's velocity increases so does its energy and hence its mass equivalent (inertia). It thus requires a greater force to accelerate it the same amount than it did at a lower velocity. The definition <math>\vec{F} = \mathrm{d}\vec{p}/\mathrm{d}t </math> remains valid, but the momentum is given by:
 
:<math> \vec{p} = \frac{m\vec{v}}{\sqrt{1 - v^2/c^2}}</math>
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:<math> \gamma = \frac{1}{\sqrt{1 - v^2/c^2}}</math>
 
Here a constant force does not produce a constant acceleration, but an ever decreasing acceleration as the object approaches the speed of light. Note that <math> \gamma</math> is [[Division by zero|undefined]] for an object with a non zero [[Invariant mass|rest mass]] at the speed of light, and the theory yields no prediction at that speed.
 
One can however restore the form of
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== Force and potential ==
Instead of a force, the mathematically equivalent concept of a [[potential energy]] field can be used for convenience. For instance, the gravitational force acting upon a body can be seen as the action of the [[gravitational field]] that is present at the body's location. Restating mathematically the definition of [[energy]] (via definition of [[Mechanical work|work]]), a potential field <math>U(\vec{r})</math> is defined as that field whose [[gradient]] is equal and opposite to the force produced at every point:
 
:<math>\vec{F}=-\vec{\nabla} U</math>
 
Forces can be classified as [[Conservative force|conservative ]] or nonconservative. Conservative forces are equivalent to the [[gradient]] of a [[potential]], and include [[gravity]], [[Electromagnetism|electromagnetic]] force, and [[Hooke's law|spring]] force. Nonconservative forces include [[friction]] and [[drag (physics)|drag]]. However, for any sufficiently detailed description, all forces are conservative.
 
== Types of force ==
Many forces exist: the [[Coulomb's law|Coulomb force]] (between [[electrical charge]]s), [[gravitation|gravitational force]] (between [[mass]]es), [[magnetic field|magnetic force]], [[friction]]al forces, [[centrifugal force|centrifugal]] forces (in [[rotating reference frame]]s), [[Hooke's law|spring force]], [[magnetism|magnetic forces]], [[tension (mechanics)|tension]], [[chemical bonding]] and [[contact force]]s to name a few.
 
Only four [[fundamental force]]s of nature are known: the [[strong force]], the [[Electromagnetism|electromagnetic force]], the [[weak force]], and the gravitational force. All other forces can be reduced to these fundamental interactions.
 
The modern quantum mechanical view of the first three fundamental forces (all except gravity) is that particles of matter ([[fermions]]) do not directly interact with each other but rather by exchange of [[virtual particles]] ([[bosons]]) (as, for example, virtual [[photons]] in case of interaction of [[electric charges]]).
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== Units of measurement ==
The [[SI]] unit used to measure force is the [[newton]] (symbol N), which is equivalent to kg·m·s<sup>&minus;2−2</sup>. The earlier [[CGS]] unit is the [[dyne]]. The relationship '''F'''=''m''·'''a''' can be used with either of these. In [[Imperial unit|Imperial]] engineering units, if ''F'' is measured in "[[Pound-force|pounds force]]" or "lbf", and ''a'' in feet per second squared, then ''m'' must be measured in [[slug (mass)|slugslugs]]s. Similarly, if mass is measured in [[pound-mass|pounds mass]], and ''a'' in feet per second squared, the force must be measured in [[poundal]]s. The units of [[slugs]] and [[poundal]]s are specifically designed to avoid a constant of proportionality in this equation.
 
A more general form '''F'''=''k''·''m''·'''a''' is needed if consistent units are not used. Here, the constant ''k'' is a conversion factor dependent upon the units being used.
 
When the standard [[acceleration due to gravity|'g']] (an acceleration of 9.80665 m/s²) is used to define pounds force, the mass in pounds is numerically equal to the weight in pounds force. However, even at sea level on Earth, the actual acceleration of free fall is quite variable, over 0.53% more at the poles than at the equator. Thus, a mass of 1.0000 lb at ''sea level'' at the equator exerts a force due to gravity of 0.9973 lbf, whereas a mass of 1.000 lb at ''sea level'' at the poles exerts a force due to gravity of 1.0026 lbf. The normal average sea level acceleration on Earth (World Gravity Formula 1980) is 9.79764 m/s², so on average at ''sea level'' on Earth, 1.0000 lb will exerts a force of 0.9991 lbf.
 
The equivalence 1 lb = 0.453&nbsp;592&nbsp;37 kg is always true, by definition, anywhere in the universe. If you use the standard [[Acceleration due to gravity|'g']] which is official for defining kilograms force to define pounds force as well, then the same relationship will hold between pounds-force and kilograms-force (an old non-SI unit is still used). If a different value is used to define pounds force, then the relationship to kilograms force will be slightly different&mdash;butdifferent—but in any case, that relationship is also a constant anywhere in the universe. What is not constant throughout the universe is the amount of force in terms of pounds-force (or any other force units) which 1 lb will exert due to gravity.
 
By analogy with the slug, there is a rarely used unit of mass called the "metric slug". This is the mass that accelerates at one metre per second squared when pushed by a force of one [[Kilogram-force|kgf]]. An item with a mass of 10 kg has a mass of 1.01972661 metric slugs (= 10 kg divided by 9.80665 kg per metric slug). This unit is also known by various other names such as the [[slug|hyl]], TME (from a German acronym), and mug (from metric slug).
 
Another unit of force called the [[poundal]] (pdl) is defined as the force that accelerates 1 lbm at 1 foot per second squared. Given that 1 lbf = 32.174 lb times one foot per second squared, we have 1 lbf = 32.174 pdl.
The [[kilogram-force]] is a unit of force that was used in various fields of science and technology. In 1901, the [[CGPM]] improved the definition of the kilogram-force, adopting a standard acceleration of gravity for the purpose, and making the kilogram-force equal to the force exerted by a mass of 1 kg when accelerated by 9.80665 m/s². The kilogram-force is not a part of the modern [[SI]] system, but is still used in applications such as:
* Thrust of [[jet engine|jet]] and [[rocket engine]]s
* Spoke tension of [[bicycle]]s
* Draw weight of [[Bow (weapon)|bows]]
* [[Torque wrench]]es in units such as "meter kilograms" or "kilogram centimetres" (the kilograms are rarely identified as units of force)
* Engine torque output (kgf·m expressed in various word orders, spellings, and symbols)
* Pressure gauges in "kg/cm²" or "kgf/cm²"
 
In colloquial, non-scientific usage, the "kilograms" used for "weight" are almost always the proper SI units for this purpose. They are units of mass, not units of force.
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The symbol "kgm" for kilograms is also sometimes encountered. This might occasionally be an attempt to distinguish kilograms as units of mass from the "kgf" symbol for the units of force. It might also be used as a symbol for those obsolete torque units (kilogram-force metres) mentioned above, used without properly separating the units for kilogram and metre with either a space or a centered dot.
 
=== Conversions ===
Below are several conversion factors between various measurements of force:
* 1 dyne = 10<sup>-5</sup> newtons
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* [[वेग]]
 
== श्रोत ==
{{Citations missing|date=December 2006}}
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