Answer: 8 years
Explanation:
According to Kepler’s Third Law of Planetary motion “The square of the orbital period of a planet is proportional to the cube of the semi-major axis (size) of its orbit”:
[tex]T^{2}\propto a^{3}[/tex] (1)
In other words: this law states a relation between the orbital period [tex]T[/tex] of a body (moon, planet, satellite, comet, asteroid) orbiting a greater body in space (the Sun, for example) with the size [tex]a[/tex] of its orbit.
However, if [tex]T[/tex] is measured in years (Earth years), and [tex]a[/tex] is measured in astronomical units (equivalent to the distance between the Sun and the Earth: [tex]1AU=1.5(10)^{8}km[/tex]), equation (1) becomes:
[tex]T^{2}=a^{3}[/tex] (2)
This means that now both sides of the equation are equal.
Knowing [tex]a=4 AU[/tex] and isolating [tex]T[/tex] from (2):
[tex]T=\sqrt{a^{3}}[/tex] (3)
[tex]T=\sqrt{(4 AU)^{3}}[/tex] (4)
Finally:
[tex]T= 8 years[/tex]This is the period of the asteroid
