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v t = d x d t đ x = v t đ t Δ x = v t đ t

This relation yields an expression of position in "t" after using initial conditions of motion.

Problem : The acceleration of a particle along x-axis varies with time as :

a = t - 1

Velocity and position both are zero at t= 0. Find displacement of the particle in the interval from t=1 to t = 3 s. Consider all measurements in SI unit.

Solution : Using integration result obtained earlier for expression of acceleration :

Δ v = v 2 - v 1 = a t đ t

Here, v 1 = 0 . Let v 2 = v , then :

v = 0 t a t đ t = 0 t t - 1 đ t

Note that we have integrated RHS between time 0 ans t seconds in order to get an expression of velocity in “t”.

v = t 2 2 t

Using integration result obtained earlier for expression of velocity : Δ x = v t đ t = t 2 2 t d t

Integrating between t=1 and t=3, we have :

Δ x = 1 3 t 2 2 t đ t = [ t 3 6 t 2 2 ] 1 3 = 27 6 9 2 1 6 + 1 2 = 5 4 = 1 m

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Problem : If the velocity of particle moving along a straight line is proportional to 3 4 th power of time, then how do its displacement and acceleration vary with time?

Solution : Here, we need to find a higher order attribute (acceleration) and a lower order attribute displacement. We can find high order attribute by differentiation, whereas we can find lower order attribute by integration.

v t 3 4

Let,

v = k t 3 4

where k is a constant. The acceleration of the particle is :

a = đ v ( t ) đ t = 3 k t 3 4 - 1 4 = 3 k t - 1 4 4

Hence,

v t - 1 4

For lower order attribute “displacement”, we integrate the function :

đ x = v đ t Δ x = v đ t = k t 3 4 đ t = 4 k t 7 4 7 Δ x t 7 4

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Velocity and acceleration is expressed in terms of time “x”

Let the expression of acceleration in x given as function a(x). Now, the defining equation of instantaneous acceleration is:

a x = đ v đ t

In order to incorporate differentiation with position, “x”, we rearrange the equation as :

a x = đ v đ x X đ x đ t = v đ v đ x

We obtain expression for velocity by rearranging and integrating :

v d v = a x d x

This relation yields an expression of velocity in x. We obtain expression for position/ displacement by using defining equation, rearranging and integrating :

v x = đ x đ t đ t = đ x v x Δ t = đ x v x

This relation yields an expression of position in t.

Problem : The acceleration of a particle along x-axis varies with position as :

a = 9 x

Velocity is zero at t = 0 and x=2m. Find speed at x=4. Consider all measurements in SI unit.

Solution : Using integration,

v đ v = a x đ x 0 v v đ v = 2 x 9 x đ x [ v 2 2 ] 0 v = 9 [ x 2 2 ] 2 x v 2 2 = 9 x 2 2 36 2 v 2 = 9 x 2 36 = 9 x 2 4 v = ± 3 x 2 4

We neglect negative sign as particle is moving in x-direction with positive acceleration. At x =4 m,

v = 3 4 2 4 = 3 12 = 6 3 m / s

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Acceleration in terms of velocity

Let acceleration is expressed as function of velocity as :

a = a v

Obtaining expression of velocity in time, “t”

The acceleration is defined as :

Arranging terms with same variable on one side of the equation, we have :

đ t = đ v a v

Integrating, we have :

Δ t = đ v a v

Evaluation of this relation results an expression of velocity in t. Clearly, we can proceed as before to obtain expression of position in t.

Obtaining expression of velocity in time, “x”

In order to incorporate differentiation with position, “x”, we rearrange the defining equation of acceleration as :

a v = đ v đ x X đ x đ t = v đ v đ x

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Source:  OpenStax, Physics for k-12. OpenStax CNX. Sep 07, 2009 Download for free at http://cnx.org/content/col10322/1.175
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