a) 41.7 J
b) 4.6 W
c) [tex]79.8^{\circ}[/tex]
Explanation:
a)
The work done by a force on an object is given by
[tex]W=F\cdot d[/tex]
where
F is the force
d is the displacement of the object
[tex]\cdot[/tex] is the scalar product
In this problem, the force is:
[tex]F = (2.00i + 9.00j + 5.30k) N[/tex]
The initial position is
[tex]r_1 = (2.70i - 2.90j + 5.50k)m[/tex]
While the final position is
[tex]r_2 = (-4.10i + 3.30j + 5.40k) m[/tex]
So, the displacement is the difference between r1 and r2:
[tex]d=r_2-r_1=((-4.10-2.70)i+(3.30-(-2.90))j+(5.40-5.50)k)m =\\=(-6.80i+6.20j-0.10k)m[/tex]
And so, the work done is:
[tex]W=F\cdot d=(2.00i+9.00j+5.30k)\cdot (-6.80i+6.20j-0.10k)=\\((2.00\cdot (-6.80))i+(9.00\cdot 6.20)j+(5.30\cdot (-0.10))k)=-13.6+55.8-0.5=\\41.7 J[/tex]
b)
The average power is calculated as the work done divided by the time taken:
[tex]P=\frac{W}{t}[/tex]
where
W is the work done
t is the time taken to do that work
In this problem:
W = 41.7 J is the work done by the force
t = 9.10 s is the time taken for this work to be done
Therefore, the power used is:
[tex]P=\frac{41.7}{9.10}=4.6 W[/tex]
c)
Given two vectors [tex]u,v,[/tex] the angle between the two vectors can be found using
[tex]cos \theta = \frac{u\cdot v}{|u||v|}[/tex]
where
[tex]u\cdot v[/tex] is the scalar product between u and v
[tex]|u|[/tex] is the magnitude of u
[tex]|v|[/tex] is the magnitude of v
Here the two vectors that we have are:
[tex]r_1 = (2.70i - 2.90j + 5.50k)m[/tex]
[tex]r_2 = (-4.10i + 3.30j + 5.40k) m[/tex]
Their magnitudes are:
[tex]|r_1|=\sqrt{(2.70)^2+(-2.90)^2+(5.50)^2}=6.78 m[/tex]
[tex]|r_2|=\sqrt{(-4.10)^2+(3.30)^2+(5.40)^2}=7.54 m[/tex]
The scalar product is:
[tex]r_1\cdot r_2=((2.70\cdot (-4.10))+((-2.90)\cdot 3.30)+(5.50\cdot 5.40))=9.06[/tex]
Therefore, the angle is:
[tex]\theta=cos^{-1}(\frac{9.06}{(6.78)(7.54)})=79.8^{\circ}[/tex]
