CHAPTER 21. MOTION IN ONE DIMENSION 21.6
Vivian’s velocity is:
v=∆∆~xt=xtf−xi
f−ti
=^100100 ms−−^00 sm
= 1m·s−^1Vivian’s velocity is 1 m·s−^1. This means that she walked 1 m in the first second, another
metre in the second second, and another in the third second, and so on. For example, after
50 s she will be 50 m from home. Her position increases by 1 m every 1 s. A diagram of
Vivian’s position is shown below:
bx= 100 mt = 0 s t = 50 s t = 100 s
x= 0 m x= 50 mb bWe can now draw graphs of position vs.time (~xvs.t), velocity vs. time (~vvs.t) and ac-
celeration vs.time (~avs.t) for Vivian moving at a constant velocity. The graphs are shown
here:
0204060801000 20 40 60 80 100positionx(m)timet(s)b∆tb ∆xb0120 20 40 60 80 100velocityv(m−·s1 )
timet(s)b b b0120 20 40 60 80 100accelerationa(m−·s2 )
timet(s)b b bGraphs for motion at constant velocity (a) position vs. time (b) velocity vs. time (c) accel-
eration vs. time. The area of the shaded portion in thevvs.tgraph corresponds to the
object’s displacement.
In the evening Vivian walks 100 m from the bus stop to her house in 100 s. Assume that
Vivian’s house is the origin. The following graphs can be drawn to describe the motion.
Physics: Mechanics 409