A summary of the take-home messages of Unit 2 on Constant Velocity. This infographic was made on the Avery template 5164 for Word. It requires 4" x 3.33" shipping labels for print.

1. Constant
Velocity
Model
Constant
Velocity
Model
From
a
position-­‐time
graph,
an
object's
position
can
be
predicted
From
a
position-­‐time
graph,
an
object's
position
can
be
predicted
based
on
its
starting
position,
velocity,
and
time
interval
of
travel
based
on
its
starting
position,
velocity,
and
time
interval
of
travel
Δx Δx
v= v=
x f − xi Δt x f − xi Δt
slope = slope =
t f − ti t f − ti
x = vt + xi x = vt + xi
Buggy Lab Buggy Lab
The object's The object's
When velocity is constant,
a graph of velocity v. time v = vi displacement is
equal to the area
When velocity is constant,
a graph of velocity v. time v = vi displacement is
equal to the area
will be a horizontal line under the curve will be a horizontal line under the curve
and the velocity at any and the velocity at any
time will be equal to the Δx = vt time will be equal to the Δx = vt
starting velocity starting velocity
Constant
Velocity
Model
Constant
Velocity
Model
From
a
position-­‐time
graph,
an
object's
position
can
be
predicted
From
a
position-­‐time
graph,
an
object's
position
can
be
predicted
based
on
its
starting
position,
velocity,
and
time
interval
of
travel
based
on
its
starting
position,
velocity,
and
time
interval
of
travel
Δx Δx
v= v=
x f − xi Δt x f − xi Δt
slope = slope =
t f − ti t f − ti
x = vt + xi x = vt + xi
Buggy Lab Buggy Lab
The object's The object's
When velocity is constant,
a graph of velocity v. time v = vi displacement is
equal to the area
When velocity is constant,
a graph of velocity v. time v = vi displacement is
equal to the area
will be a horizontal line under the curve will be a horizontal line under the curve
and the velocity at any and the velocity at any
time will be equal to the Δx = vt time will be equal to the Δx = vt
starting velocity starting velocity
Constant
Velocity
Model
Constant
Velocity
Model
From
a
position-­‐time
graph,
an
object's
position
can
be
predicted
From
a
position-­‐time
graph,
an
object's
position
can
be
predicted
based
on
its
starting
position,
velocity,
and
time
interval
of
travel
based
on
its
starting
position,
velocity,
and
time
interval
of
travel
Δx Δx
v= v=
x f − xi Δt x f − xi Δt
slope = slope =
t f − ti t f − ti
x = vt + xi x = vt + xi
Buggy Lab Buggy Lab
The object's The object's
When velocity is constant,
a graph of velocity v. time v = vi displacement is
equal to the area
When velocity is constant,
a graph of velocity v. time v = vi displacement is
equal to the area
will be a horizontal line under the curve will be a horizontal line under the curve
and the velocity at any and the velocity at any
time will be equal to the Δx = vt time will be equal to the Δx = vt
starting velocity starting velocity