ok what is the point in haveing this question even up if it doesnt have a goddamn answer up yet!!!?!?!?!?
A planet's orbital radius directly affects its orbital period through Kepler's third law of planetary motion. The farther a planet is from the star it orbits, the longer its orbital period will be, assuming all other factors remain constant. This relationship is expressed mathematically as T^2 ∝ r^3, where T is the orbital period and r is the orbital radius.
Jupiters orbital speed in relation to the sun is 13.07 km/sec on average.
Jupiter's orbit is an ellipse with an eccentricity of 0.048, which means that it looks like a circle with the Sun off-centre by an amount equal to 0.048 times the average radius. Uranus has an eccentricity of 0.047 and that is the closest among the other planets.
The orbital period of Jupiter is about 11.9 Earth years. This means it takes Jupiter approximately 11.9 Earth years to complete one orbit around the Sun.
The radius of the Sun is 697,000 km, which means that the volume of the Sun is about 1,418,364,847.22 billion cubic km. The radius of Jupiter is 71,492 km, which gives us a volume of 1,530,600.9 billion cubic km. This means that inside the Sun, you could probably in about 926 Jupiters!
4332.589.
The diameter of Jupiter is 142,984km, and it's radius is 71,492km.
If you decrease a planet's orbital radius, its surface temperature will increase.
A planet's orbital radius directly affects its orbital period through Kepler's third law of planetary motion. The farther a planet is from the star it orbits, the longer its orbital period will be, assuming all other factors remain constant. This relationship is expressed mathematically as T^2 ∝ r^3, where T is the orbital period and r is the orbital radius.
Jupiters orbital speed in relation to the sun is 13.07 km/sec on average.
Neptune has the largest orbital radius among the eight planets in our solar system. Its average distance from the Sun is about 4.5 billion kilometers.
Orbital speed of a satellite: v - orbital speed G - gravitational consatnt R - radius of earth h - height of orbit
Uranus' orbital radius is about 19.22 times the average distance from Earth to the Sun (1 astronomical unit). This makes Uranus' average distance to the Sun approximately 19.22 astronomical units.
Being a gaseous planet, Jupiter is flattened at the poles and bulges at its equator. Its mean radius is 69,900 km.
Yes, spot on, good guess . .
Jupiter's orbit is an ellipse with an eccentricity of 0.048, which means that it looks like a circle with the Sun off-centre by an amount equal to 0.048 times the average radius. Uranus has an eccentricity of 0.047 and that is the closest among the other planets.
Using Newton's law of universal gravitation and the fact that the gravitational force is equal to the centripetal force, we can set up an equation to find the orbital radius of Los. By equating the gravitational forces of both Los and Ratipuj, we can find the orbital radius of Los to be approximately 1.49 x 1010 km.