The distance of a planet from the Sun affects its time to revolve around the Sun because the circumference of its orbit is larger; hence, the planet has to travel a longer line to complete one revolution.
Earth, for example, travels along its orbit at over 29 kilometers per second. The planet Mars travels along its orbit at about 24 kilometers per second, so not much slower. However, Mars is farther away and hence its journey is longer, so it still takes about 687 days for Mars to complete one revolution versus Earth's 365 days.
This only addresses how distance from the Sun can influence the revolution time -- tidal effects on the planets also affect how quickly they move along their orbit.
distance from a source of light and how long it takes to orbit that source
planets have revoloution times because back before clocks, they used the sun and some odd looking statues placed correctly to tell the times, so therefore by giving a planet a revolution time they could tell what time of day or year it was by looking at the position of the sun.
A longer orbital period, meaning it takes more time to complete one revolution around the sun. This results in a larger average distance from the sun compared to planets with shorter orbits. This increased distance can lead to colder temperatures on the planet.
Plantes differ in there speed around the sun because they are all different distances from the sun. The closest planet to the sun in our solar system takes much less time then the farthest because it has much less distance to go.
All 8 planets, including dwarf planet Pluto, orbit the Sun. As their distance from the Sun increases, the time it takes for the planet to complete one revolution around the Sun increases as well. In order from shortest orbital period to longest orbital period:MercuryVenusEarthMarsJupiterSaturnUranusNeptune
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 square of the time period of revolution is directly proportional to the cube of the mean distance between the planet and its Sun. T2 α R3T = Time Period R = Length of the semi-major axis
distance from a source of light and how long it takes to orbit that source
Nothing in the positions of the planets affects humans. There is no proven connection between planetary activity and any individual's life.
planets have revoloution times because back before clocks, they used the sun and some odd looking statues placed correctly to tell the times, so therefore by giving a planet a revolution time they could tell what time of day or year it was by looking at the position of the sun.
Because they're farther away. Also, they move more slowly as the distance from the Sun increases.
A longer orbital period, meaning it takes more time to complete one revolution around the sun. This results in a larger average distance from the sun compared to planets with shorter orbits. This increased distance can lead to colder temperatures on the planet.
Plantes differ in there speed around the sun because they are all different distances from the sun. The closest planet to the sun in our solar system takes much less time then the farthest because it has much less distance to go.
No, it is the sun's gravity that affects the planets revolutions. The planet's distance from the sun is also very important in the time it takes to revolve around the sun.
All 8 planets, including dwarf planet Pluto, orbit the Sun. As their distance from the Sun increases, the time it takes for the planet to complete one revolution around the Sun increases as well. In order from shortest orbital period to longest orbital period:MercuryVenusEarthMarsJupiterSaturnUranusNeptune
there is no true relationship between distance from the sun and orbit time as some planets go revolves at a different velocity.
A planet farther from the sun has a longer period of revolution because it has a greater distance to travel in its orbit around the sun, which takes more time. This is in accordance with Kepler's second law of planetary motion, which states that planets sweep out equal areas in equal times, meaning that planets move more slowly in their orbits when they are farther from the sun.