The first weather satellites allowed meteorologists and forecasters to see Earth from space and get a larger picture of cloud formations from above. The program was called TIROS and there were 10 satellites in the series. (A good link is provided below) Prior to TIROS, there were few options available to help meteorologists to predict the weather.
The force of gravity is responsible for continuously changing the velocity or speed of a satellite as it orbits around a larger body, such as a planet or a star. This change in velocity helps to maintain the satellite's orbit and keep it in motion around the larger body.
The satellite is being pulled by the earths gravity all of the time, but the satellite also has an orbital velocity, meaning that is is travelling at high speed. These two opposing forces balance out, the 'sideways' speed of the satellite wants to take it away into space, but the gravity of the earth is always pulling it in. The satellite maintains its speed as there there are no frictional forces to slow it down in space, so it maintains an orbit.
No. To remain in orbit it needs to have a certain speed, and that speed will only match the surface speed of the earth on a certain height. To go lower it'd have to go slower, and then it'd fall.
Not very much, I would say. There is no work being done in this situation so there's no change in kinetic energy. So the satellite's speed remains constant. But we already knew the speed was constant. Perhaps I'm missing something.
The period of a satellite is the time it takes for the satellite to complete one orbit around its parent body, such as a planet or a star. It is typically measured in hours, days, or years depending on the size and speed of the satellite's orbit. The period is determined by the satellite's orbital velocity and the mass of the parent body it is orbiting.
The speed of the satellite will remain the same regardless of doubling the mass, as long as the radius of its orbit remains constant. The speed of the satellite in orbit is determined by the gravitational force between the satellite and the celestial body it is orbiting, not the mass of the satellite itself.
As a satellite spirals inward, it speeds up due to the gravitational pull increasing as it gets closer to the center of the object it is orbiting.
A satellite has to maintain 1800miles/hr. around the Earth. If its speed were to speed up the satellite would fly off in to space. If the satellites speed were to slow down it would come crashing into Earth.
The speed of a satellite signal is approximately the speed of light, which is about 299,792 kilometers per second. This means that signals transmitted from a satellite to Earth or vice versa travel at this high speed.
Satellite technology increases the speed of global communications A satellite technology increases the speed of global communications
satellite modem
To maintain course and speed
The force of gravity is responsible for continuously changing the velocity or speed of a satellite as it orbits around a larger body, such as a planet or a star. This change in velocity helps to maintain the satellite's orbit and keep it in motion around the larger body.
A satellite in a closed orbit has the greatest speed when it's closest to the planet, and the lowest speed when it's farthest from the planet.
Spin motion helps stabilize the satellite and control its orientation, allowing it to maintain a consistent position in space. This is crucial for ensuring that the satellite's sensors and antennas are properly aligned. Spin motion also helps distribute heat evenly across the satellite's surface, preventing overheating.
An object moving by constant speed in space could be a spacecraft, satellite, or a celestial body like a planet or asteroid. In space, objects can maintain a constant speed due to the absence of friction or air resistance.
The three basic requirements for a satellite are: Proper elevation, Proper speed, and Proper orbit. If a satellite does not have these three things it will either float into space or crash into the earth.