Answer:
a) Figure attached
b) For this case w have that A =(2.4 km)j, B= (-1.9 km) i , C= (-4.7 km)j
And the final position vector can be calculated adding the 3 vectors like this:
[tex] s = A +B+C[/tex]
[tex] s= (-1.9 km)i +(2.4 -4.7 km) j= (-1.9km)i + (-2.3 km)j[/tex]
We can find the magnitude of s like this:
[tex] |s| = \sqrt{(-1.9)^2 +(-2.3)^2}=2.983[/tex]
And then we can find the angle with this formula:
[tex] \theta = \tan^{-1} (\frac{-2.3 km}{-1.9 km})=50.44 [/tex]
The other possibility is [tex] \theta = 50.44+180 =230.44[/tex]
And since they want the angle measured from East the correct angle would be [tex] \theta = 230.44[/tex]
Step-by-step explanation:
Part a
On the figure attached we have the vectors for the pattern described.
Part b
For this case w have that A =(2.4 km)j, B= (-1.9 km) i , C= (-4.7 km)j
And the final position vector can be calculated adding the 3 vectors like this:
[tex] s = A +B+C[/tex]
[tex] s= (-1.9 km)i +(2.4 -4.7 km) j= (-1.9km)i + (-2.3 km)j[/tex]
We can find the magnitude of s like this:
[tex] |s| = \sqrt{(-1.9)^2 +(-2.3)^2}=2.983[/tex]
And then we can find the angle with this formula:
[tex] \theta = \tan^{-1} (\frac{-2.3 km}{-1.9 km})=50.44 [/tex]
The other possibility is [tex] \theta = 50.44+180 =230.44[/tex]
And since they want the angle measured from East the correct angle would be [tex] \theta = 230.44[/tex]
