Asked by Larry
The period of revolution of a planet around the sun is the time it takes for the planet to complete one orbit of the sun. The period, P years, is give by Kepler's third law P^2=D^3, where D is the average distance from the sun in astronomical units (AU). One AU is the average distance f the Earth fromt he sun. Use the average distance formt he sun to find the period of revolution for Jupiter; 5.20 AU to the nearest tenth of a year.
I don't get that, the teacher said the answer was 11.9 I think. Anyone care to explain how?
Thanks
I don't get that, the teacher said the answer was 11.9 I think. Anyone care to explain how?
Thanks
Answers
Answered by
Don
Easy.
5.20 AU is the distance so:
P^2=D^3 is equivalent to:
P^2=5.20^3
5.20^3 is 140.608, 140.608 is the period.
So the new equation would be:
P^2=140.608
Since you now know that 140.608 is the period squared, the opposite of squaring is square rooting. So this is how you would write it.
ã140.608=11.85782442
It asked for the nearest tenth of the year so rounding up would make the answer 11.9
So the period of revolution for Jupiter is 11.9 years.
-Don
5.20 AU is the distance so:
P^2=D^3 is equivalent to:
P^2=5.20^3
5.20^3 is 140.608, 140.608 is the period.
So the new equation would be:
P^2=140.608
Since you now know that 140.608 is the period squared, the opposite of squaring is square rooting. So this is how you would write it.
ã140.608=11.85782442
It asked for the nearest tenth of the year so rounding up would make the answer 11.9
So the period of revolution for Jupiter is 11.9 years.
-Don
Answered by
Kiara
The period of revolution for Saturn is 29.5 years . Round this off to the neared ten
Answered by
Vanessa
No I deal
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