3.2 Instantaneous velocity and speed

Instantaneous velocity versus average velocity

The position of a particle is given by $x(t)=3.0t+0.5t^3\text{m}$ .

1. Using [link] and [link] , find the instantaneous velocity at $t=2.0$ s.
2. Calculate the average velocity between 1.0 s and 3.0 s.

Strategy

[link] give the instantaneous velocity of the particle as the derivative of the position function. Looking at the form of the position function given, we see that it is a polynomial in t . Therefore, we can use [link] , the power rule from calculus, to find the solution. We use [link] to calculate the average velocity of the particle.

Solution

1. $v(t)=\frac{dx(t)}{dt}=3.0+1.5t^2\text{m/s}$ .
   Substituting t = 2.0 s into this equation gives $v(2.0\text{s})=[3.0+1.5{(2.0)}^2]\text{m/s}=9.0\text{m/s}$ .
2. To determine the average velocity of the particle between 1.0 s and 3.0 s, we calculate the values of x (1.0 s) and x (3.0 s):
   
   $x(1.0\text{s})=\left[(3.0)(1.0)+0.5{(1.0)}^3\right]\text{m}=3.5\text{m}$
   
   
   $x(3.0\text{s})=\left[(3.0)(3.0)+0.5{(3.0)}^3\right]\text{m}=22.5\text{m.}$
   
   Then the average velocity is
   
   $\stackrel{\text{–}}{v}=\frac{x(3.0\text{s})-x(1.0\text{s})}{t(3.0\text{s})-t(1.0\text{s})}=\frac{22.5-3.5\text{m}}{3.0-1.0\text{s}}=9.5\text{m/s}\text{.}$

Significance

In the limit that the time interval used to calculate $\stackrel{\text{−}}{v}$ goes to zero, the value obtained for $\stackrel{\text{−}}{v}$ converges to the value of v.

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