Vectors 257
10N15NFigure 24.22The horizontal component of the 15N force is 15cos0◦
and the horizontal component of the 10N force is
10cos90◦
The total horizontal component of the two velocities,
H=15cos0◦+10cos90◦= 15 + 0 = 15The vertical component of the 15N force is 15sin0◦
andthevertical component ofthe10Nforceis10sin90◦
The total vertical component of the two velocities,
V=15sin0◦+10sin90◦= 0 + 10 = 10Magnitude of resultant vector
=√
H^2 +V^2 =√
152 + 102 =18.03NThe direction of the resultant vector,
θ=tan−^1(
V
H)
=tan−^1(
10
15)
= 33. 69 ◦Thus,the resultant of the two forces is a single vector
of 18.03N at 33. 69 ◦to the 15N vector.
There is an alternative method of calculating the resul-
tant vector in this case.
If we used the triangle method, then the diagram would
be as shown in Fig. 24.23.
15NR 10NFigure 24.23
Since a right-angled triangle results then we could use
Pythagoras’s theoremwithout needing to go through
the procedure for horizontal and vertical components.
In fact, the horizontal and vertical components are 15N
and 10N respectively.
This is, of course, a special case. Pythagorascan only be
used when there is an angle of 90◦between vectors.
This is demonstrated in the next worked problem.Problem 9. Calculate the magnitude and
direction of the resultant of the two acceleration
vectors shown in Fig. 24.24.15m/s^228m/s^2Figure 24.24The 15m/s^2 acceleration is drawn horizontally, shown
as 0 ain Fig. 24.25.
From the nose of the 15m/s^2 acceleration, the 28m/s^2
acceleration is drawn at an angleof 90◦tothehorizontal,
shown asab.a 01528bR Figure 24.25The resultant acceleration,R, is given by length 0 b.
Since a right-angled triangle results, the theorem of
Pythagoras may be used.0 b=√
152 + 282 =31.76m/s^2and α=tan−^1(
28
15)
= 61. 82 ◦Measuring from the horizontal,
θ= 180 ◦− 61. 82 ◦= 118. 18 ◦