The period of revolution of a planet (time taken to complete one orbit around the sun) is directly proportional to its average distance from the sun. This relationship is described by Kepler's third law of planetary motion. Planets that are farther from the sun take longer to complete an orbit compared to planets that are closer to the sun.
The farther away from the sun, the longer the period of revolution takes.
How does a planet's distance from the sun affect its period of revolution?
The farther it is from the sun the longer its period of revolution (its "year").
A planets period or revolution, the time taken to orbit its star, is dependant on its mass, the stars mass and the distance between the two. See Kepler's laws of planetary motion for further information.
Yes, the square of the orbital period of a planet is proportional to the cube of the average distance of the planet from the Sun. This relationship is known as Kepler's Third Law of Planetary Motion. It describes the mathematical relationship between a planet's orbital period and its average distance from the Sun.
The relationship between the planet's SPEED and its distance from the Sun is given by Kepler's Third Law.From there, it is fairly easy to derive a relationship between the period of revolution, and the distance.
the planets
The farther away from the sun, the longer the period of revolution takes.
The period of revolution (time taken to complete one orbit around the sun) increases with distance from the sun. This relationship is described by Kepler's third law of planetary motion, which states that the square of the period of revolution is proportional to the cube of the average distance from the sun (semi-major axis) for a planet.
The relationship that exists between a planet's distance from the Sun and its period of revolution is that the closer the planet is from the Sun, the less amount of time it takes for the planet to complete its period of revolution.
Johannes Kepler stated the relationship in his third law of planetary motion. This law, formulated in the early 17th century, describes the relationship between a planet's orbital period and its average distance from the sun.
How does a planet's distance from the sun affect its period of revolution?
F is directly porportional to P
Time = distance3/2Kepler's 3rd Law of Planetary Motion gives this relationship:The cube of the average distance from the Sun is proportional to the square ofthe period of revolution (year).So: (Distance)3 is proportional to (year)2
The farther it is from the sun the longer its period of revolution (its "year").
The farther it is from the sun the longer its period of revolution (its "year").
How does a planet's distance from the sun affect its period of revolution?