Difference between revisions of "Chapter 2 Problem 16"

Problem

The position of a ball rolling in a straight line is given by ${\displaystyle x=2.0-3.6t+1.1t^{2}}$, where ${\displaystyle x}$ is in meters and ${\displaystyle t}$ in seconds.

(a) Determine the position of the ball at ${\displaystyle t=}$ 1.0 s, 2.0 s, and 3.0 s.

(b) What is the average velocity over the interval ${\displaystyle t=}$ 1.0 s to ${\displaystyle t=}$ 3.0 s?

(c) What is its instantaneous velocity at ${\displaystyle t=}$ 2.0s and at ${\displaystyle t=}$ 3.0s?

Solution

notice that if ${\displaystyle x}$ is in meters and and ${\displaystyle t}$ is in seconds, the implicit (hidden) units of the constants are ${\displaystyle 2.0\rightarrow 2.0{\textrm {m}}}$; ${\displaystyle 3.6\rightarrow 3.6{\textrm {m/s}}}$; ${\displaystyle 1.1\rightarrow 1.1{\textrm {m/s}}^{2}}$

(a)

${\displaystyle x}$(1.0s)= 2.0m−(3.6m/s)(1.0s)+(1.1m/s${\displaystyle ^{2}}$ )(1.0s)${\displaystyle ^{2}}$ =-0.5 m

${\displaystyle x}$(2.0s)= 2.0m−(3.6m/s)(2.0s)+(1.1m/s${\displaystyle ^{2}}$ )(2.0s)${\displaystyle ^{2}}$ =-0.8 m

${\displaystyle x}$(3.0s)= 2.0m−(3.6m/s)(3.0s)+(1.1m/s${\displaystyle ^{2}}$ )(3.0s)${\displaystyle ^{2}}$ = 1.1 m

(b)

${\displaystyle {\bar {v}}={\frac {\Delta x}{\Delta t}}={\frac {1.1{\textrm {m}}-(-0.5{\textrm {m}})}{2.0{\textrm {s}}}}=0.80{\textrm {m/s}}}$

(c)

${\displaystyle v(t)={\frac {dx(t)}{dt}}=-3.6{\textrm {m/s}}+1.1{\textrm {m/s}}^{2}t}$

${\displaystyle v(2.0{\textrm {s}})=-3.6{\textrm {m/s}}+(2.2{\textrm {m/s}}^{2})(2.0{\textrm {s}})=0.8{\textrm {m/s}}}$

${\displaystyle v(3.0{\textrm {s}})=-3.6{\textrm {m/s}}+(2.2{\textrm {m/s}}^{2})(3.0{\textrm {s}})=3.0{\textrm {m/s}}}$