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(Chris Devlin) #1
110 CHAPTER 5 FORCE AND MOTION—I

Sample Problem 5.04 Cord accelerates box up a ramp

Many students consider problems involving ramps (inclined
planes) to be especially hard. The difficulty is probably visual
because we work with (a) a tilted coordinate system and (b) the
components of the gravitational force, not the full force. Here is
a typical example with all the tilting and angles explained. (In
WileyPLUS, the figure is available as an animation with
voiceover.) In spite of the tilt, the key idea is to apply Newton’s
second law to the axis along which the motion occurs.
In Fig. 5-15a, a cord pulls a box of sea biscuits up along a
frictionless plane inclined at angle u30.0. The box has
massm5.00 kg, and the force from the cord has magni-
tudeT25.0 N. What is the box’s acceleration aalong the
inclined plane?

KEY IDEA

The acceleration along the plane is set by the force compo-
nents along the plane (not by force components perpendi-

cular to the plane), as expressed by Newton’s second law
(Eq. 5-1).

Calculations:We need to write Newton’s second law for
motion along an axis. Because the box moves along the in-
clined plane, placing an xaxis along the plane seems reason-
able (Fig. 5-15b). (There is nothing wrong with using our
usual coordinate system, but the expressions for compo-
nents would be a lot messier because of the misalignment of
thexaxis with the motion.)
After choosing a coordinate system, we draw a free-
body diagram with a dot representing the box (Fig. 5-15b).
Then we draw all the vectors for the forces acting on the box,
with the tails of the vectors anchored on the dot. (Drawing
the vectors willy-nilly on the diagram can easily lead to errors,
especially on exams, so always anchor the tails.)
Force Tfrom the cord is up the plane and has magni-

:

θ

y

FN x

Fg

T

(b)

Cord

θ

(a)

The box accelerates.

Normal force

Cord's pull

Gravitational
force

x
T
mgsinθ

(g)(h)

θ mgcos
mg

θ

mgsinθ

y

FN x

(i)

mgcosθ

The net of these
forces determines
the acceleration.

These forces
merely balance.

(e)

Fg

(c) (d)

90°−

θ

θ 90°−θ
θ θ

(f)

θ

This is a right
triangle.

Parallel
component of
Fg

This is also.

Hypotenuse

Adjacent leg
(use cos )θ

Opposite leg
(use sin )θ

Perpendicular
component of
Fg

Figure 5-15(a) A box is pulled up a plane by a
cord. (b) The three forces acting on the
box: the cord’s force the gravitational force
and the normal force (c)–(i) Finding
the force components along the plane and
perpendicular to it.InWileyPLUS, this figure
is available as an animation with voiceover.

FN
:
Fg.
:
,

T
:
,

A


tudeT25.0 N. The gravitational force Fgis downward (of
:
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