Respuesta :
Answer:8.28 km
Explanation:
Given
First it drifts [tex]45^{\circ}[/tex] 2.5 km
[tex]r_1=2.5cos45 i+2.5sin45 j[/tex]
Secondly it drifts [tex]60^{\circ}[/tex] 4.70 km
[tex]r_{12}=4.7cos60 i-4.7sin60 j[/tex]
After that it drifted along east direction 5.1 km
[tex]r_{23}=5.1 i[/tex]
After that it drifts [tex]55^{\circ}[/tex] 7.2 km
[tex]r_{34}=-7.2cos55 i-7.2sin55 j[/tex]
After that it drifts [tex]5^{\circ}[/tex] 2.8 km
[tex]r_{54}=-2.8cos5 i+2.8sin5 j[/tex]
[tex]r_{5O}[/tex]=[tex]\left [ 2.5cos45+4.7cos60+5.1-7.2cos55-2.8cos5\right ]\hat{i}[/tex]+[tex]\left [ 2.5sin45-4.7sin60-7.2sin55+2.8sin5\right ]\hat{j}[/tex]
[tex]r_{5O}=2.299\hat{i}-7.95\hat{j}[/tex]
[tex]|r_{5O}|=8.28 km[/tex]
for direction
[tex]tan\theta =\frac{7.95}{2.299}=3.4580[/tex]
[tex]\theta =73.87^{\circ}[/tex] south of east
Explanation:
Let us assume the direction east as i, direction west as -i, direction north as j and direction south as j.
Now, we define each of the straight lines as a vector with components along each of these unit vectors, we get
A : 2.5 km 45° north of west
A = 2.5 cos45 (-i) + 2.5 cos45 (j)
= -1.77(i) + 1.77(j)
B : 4.7 km 60° south of east
B = 4.7 cos60 (i) + 4.7 sin60 (-j)
= 2.35(i) - 4.07(j)
C : 5.1 km straight east
C = 5.1(i)
D : 7.2 km 55° south of west
D = 7.2 cos55 (-i) + 7.2 sin55 (-j)
= -4.13(i) - 5.9(j)
E: 2.8 km 5° north of east
E = 2.8 cos5 (i) + 2.8 sin5 (j)
= 2.79(i) + 0.24(j)
The resultant sum of all these vectors is as follows.
R = A + B + C + D + E
The sum of all the above yields,
R = 4.34(i) + 7.96(-j)
The magnitude of the resultant is as follows.
[tex] |R| = \sqrt{4.34^{2} + (-7.96)^{2}}[/tex]
= 9.07
The angle that the resultant makes is as follows.
[tex] \theta = tan^{-1}(\frac{7.96}{4.34}) = 61.4^{o}[/tex]
So, his final position relative to the island is as follows.
9.07 km, 61.4° south of east.
Thus, we can conclude that final position of Gilligan in kilometers and degrees south of east relative to the island is 9.07 km, 61.4° south of east.
