Impulse: Difference between revisions

Revision as of 19:21, 20 January 2010

Definition

The impulse due to a force applied over a period of time is the integral of the force over the period of time. In other words, the impulse due to a force ${\overline {F}}(t)$ (a vector quantity) from time $t=t_{1}$ to time $t=t_{2}$ is given by

$\int _{t_{1}}^{t_{2}}{\overline {F}}(t)\,dt$

Impulse is responsible for a change in the linear momentum, and the net impulse on a system equals, as a vector, the change in the linear momentum of the system. This is one of the many formulations of Newton's second law.

The concept of impulse is particularly useful for collisions, where a very large and quickly changing quantity of force is exerted by the two bodies on each other over a very short interval of time. Measuring the force as a function of time is hard, but the total value of the impulse can both be measured and theoretically predicted.

Units and dimensions

Question	Answer
Scalar or vector?	Vector
Instantaneous or time-cumulative?	Time-cumulative
MLT dimensions	$MLT^{-1}$ (type MLT;1;1;-1)
SI units	$kgm/s$ (kilogram meters per second) or $Ns$ (Newton-second)

@@ Line 18: / Line 18: @@
 | Instantaneous or time-cumulative? || Time-cumulative
 |-
-| MLT dimensions || <math>MLT^{-1}</math> (type [[MLT::1;1;-1]])
+| MLT dimensions || <math>MLT^{-1}</math> (type [[MLT::MLT;1;1;-1]])
 |-
 | SI units || <math>kgm/s</math> (kilogram meters per second) or <math>Ns</math> (Newton-second)
 |}