5 hours
If the orbit of a satellite is tilted more, it would result in a change in the satellite's ground track and coverage area. This change in inclination would also affect the satellite's position relative to the Earth's equator, potentially altering its visibility and communication capabilities with specific regions.
A geostationary orbit would allow a satellite to see all parts of the globe as it orbits the Earth at the same speed that the Earth rotates. This means the satellite remains fixed above the same point on the equator, providing continuous coverage of that area.
A satellite stays in orbit due to a balance between its forward motion and the gravitational pull of the Earth. The velocity of the satellite allows it to continuously fall towards the Earth but also keeps missing it, causing it to remain in orbit. If there were no gravitational pull, the satellite would fly off into space.
It would move further out of the current orbit. Possibly into an unstable orbit & be flung from earth altogether (however, the people who design satellites are fairly smart and won't allow that to happen)
Items, be they planets, moons or satellites, stay in orbit because they care carefully balanced between their inertia and the gravity of the primary object. They are freely falling - AROUND the primary.A satellite in low Earth orbit goes about 18,000 miles per hour in a direction tangent, or sideways, to the Earth's surface. Without gravity, it would fly off into space. It is continually falling toward the Earth. But because the satellite is moving sideways, by the time the satellite would have fallen to the ground, the satellite has already missed; it is along in its orbit, still falling, still traveling sideways to the Earth.
If the orbit of a satellite is tilted more, it would result in a change in the satellite's ground track and coverage area. This change in inclination would also affect the satellite's position relative to the Earth's equator, potentially altering its visibility and communication capabilities with specific regions.
The most likely factor that would cause a communications satellite orbiting Earth to return to Earth from its orbit would be atmospheric drag. As the satellite moves through the Earth's atmosphere, it experiences friction with air molecules which can slow it down and cause its orbit to decay, eventually leading to re-entry into Earth's atmosphere.
A geostationary orbit would allow a satellite to see all parts of the globe as it orbits the Earth at the same speed that the Earth rotates. This means the satellite remains fixed above the same point on the equator, providing continuous coverage of that area.
Regarding the communications satellite orbit; a geosynchronous orbit is one that keeps the satellite in one position in the sky. It is a spot in space about 22,000 miles away that the satellite will orbit the earth once a day, so it is moving the same speed as the earth rotates and appears to never move. If your dish network satellite was not in geosynchrous orbit, you would need a device to turn your dish and there would be periods that the satellite would be over a different part of the world, like the sun and moon. They would slip over the horizon and you wouldn't be able to watch TV for a while.
A "geo-synchronous" orbit is one in which a satellite orbits in exactly 23 hours 56 minutes, the same rate at which the Earth spins. So while the satellite is moving and the Earth is moving, they are moving together at the same angular speed. This only works for equatorial orbits.
Yes. The whole idea of being a satellite is that the object orbits another object. If you mean 'can a satellite orbit more than one object', then the answer is also yes. Objects orbiting binary stars would be an example of this.
A satellite stays in orbit due to a balance between its forward motion and the gravitational pull of the Earth. The velocity of the satellite allows it to continuously fall towards the Earth but also keeps missing it, causing it to remain in orbit. If there were no gravitational pull, the satellite would fly off into space.
It would move further out of the current orbit. Possibly into an unstable orbit & be flung from earth altogether (however, the people who design satellites are fairly smart and won't allow that to happen)
If the satellite is in an orbit that takes it over the North and South Poles, it will eventually cover all parts of the Earth as the Earth spins beneath it. This kind of orbit is called a polar orbit.
The answer is obviously, "the moon". But if you're asking about the largest "Man Made" satellite, the answer would be the international space station.
The linear velocity of a satellite in an elliptical orbit increases as it moves from perigee (closest point to Earth) to apogee (farthest point from Earth) because the gravitational pull is weaker at apogee, causing the satellite to speed up. At perigee, the satellite moves faster due to the stronger gravitational pull from Earth.
It would need to be launched into a tangent plane parellel to that of the earth's orbit around the sun, with the same speed of rotation around the sun