Difference between revisions of "Acceleration"
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The rate of change of an object's [[velocity]].<ref>Wile, Dr. Jay L. ''Exploring Creation With Physical Science''. Apologia Educational Ministries, Inc. 1999, 2000</ref>. For an object to undergo an acceleration, a [[force]] needs to be exerted on the object. An example is a falling object on [[Earth]], which is subject to a [[gravity|gravitational force]]. The resulting acceleration ''g'' is independent of the mass of the object, and is approximately 9.8 [[meter]] per [[second]] per [[second]] near the Earth's surface<ref>Marcelo Alonso and Edward J. Finn, ''Fundamental University Physics'', Addison-Wesley.</ref>. | The rate of change of an object's [[velocity]].<ref>Wile, Dr. Jay L. ''Exploring Creation With Physical Science''. Apologia Educational Ministries, Inc. 1999, 2000</ref>. For an object to undergo an acceleration, a [[force]] needs to be exerted on the object. An example is a falling object on [[Earth]], which is subject to a [[gravity|gravitational force]]. The resulting acceleration ''g'' is independent of the mass of the object, and is approximately 9.8 [[meter]] per [[second]] per [[second]] near the Earth's surface<ref>Marcelo Alonso and Edward J. Finn, ''Fundamental University Physics'', Addison-Wesley.</ref>. | ||
| − | Calculation of acceleration is done with the formula F=MA, where F=force and is measured in Newtons, M=mass and is measured in kilograms, and A=acceleration. Using the formula we can find that A=F/M. | + | Calculation of acceleration is done with the formula <math>F=MA</math>, where F=force and is measured in Newtons, M=mass and is measured in kilograms, and A=acceleration. Using the formula we can find that <math>A=F/M</math>. |
==References== | ==References== | ||
Revision as of 11:58, August 17, 2007
The rate of change of an object's velocity.[1]. For an object to undergo an acceleration, a force needs to be exerted on the object. An example is a falling object on Earth, which is subject to a gravitational force. The resulting acceleration g is independent of the mass of the object, and is approximately 9.8 meter per second per second near the Earth's surface[2].
Calculation of acceleration is done with the formula 
, where F=force and is measured in Newtons, M=mass and is measured in kilograms, and A=acceleration. Using the formula we can find that 
.
