Centripetal force is what keeps a satellite in orbit around a celestial body, like Earth. This force is due to the gravitational attraction between the satellite and the celestial body. Electrical forces play a role in satellite communication and operation, but they are not directly responsible for keeping the satellite in orbit.
The force that keeps a satellite in motion is the gravitational force of the planet it is orbiting. This force acts as a centripetal force, pulling the satellite towards the planet and keeping it in its orbit.
No, centripetal force is the force required to keep an object moving in a circular path, while gravitational force is the force of attraction between two objects due to their mass. In the case of a satellite orbiting a planet, the centripetal force required to keep the satellite in orbit is provided by the gravitational force between the satellite and the planet.
The gravitational force between Earth and the Sun provides the centripetal force needed to keep Earth in orbit. This force keeps Earth moving in a circular path around the Sun.
The centripetal force acting on satellites is gravity, specifically the gravitational force between the satellite and the celestial body it is orbiting. This force pulls the satellite towards the center of the orbit, continuously changing its direction of motion and keeping it in a circular or elliptical orbit around the celestial body.
The centripetal force that keeps the International Space Station in orbit around the Earth is due to the gravitational pull between the Earth and the space station. This gravitational force causes the space station to constantly fall towards Earth, but its tangential velocity keeps it moving sideways, resulting in a stable orbit.
The force that provides the centripetal acceleration for a satellite in orbit is the gravitational force between the satellite and the celestial body it is orbiting, such as Earth. This gravitational force acts as the centripetal force that keeps the satellite in its circular path around the celestial body.
The centripetal force acts towards the center of the circular path followed by the satellite, allowing it to maintain its orbit. In the case of a satellite orbiting Earth, the force of gravity provides the centripetal force required to keep the satellite in its orbit.
The force that keeps a satellite in motion is the gravitational force of the planet it is orbiting. This force acts as a centripetal force, pulling the satellite towards the planet and keeping it in its orbit.
Centripetal force wants to move something towards the centre. So in a satellites case that would be the Gravity of the Earth. If you had a rock tied to a string you were spinning around, the Centripetal Force would be the tension in the string acting towards the centre.
by means of the gravitational forces between it and the planet
by means of the gravitational forces between it and the planet
The force that keeps an object moving in a circle or an arc is called a centripetal force. Gravity is an example of centripetal force that keeps a satellite in a circular orbit around a planet. Another example is when you ride on a merry-go-round - the rotating play structure imparts a centripetal force upon you, forcing you to also travel in a circle.
Centripetal force is the force that keeps an artificial satellite in orbit around a celestial body, such as Earth. It is provided by the gravitational force between the satellite and the planet. The centripetal force acts as the inward force that continually changes the direction of the satellite's motion, allowing it to orbit the planet in a stable path.
force is mass x acceleration which for orbit is mass (m) x velocity squared (v^2)divided by radius (R) above center of earth. Since there is also acceleration of gravity (g) then g = v^2/R. You can now calculate velocity of satellite to stay in orbit - it is about 17.500 mph
Air resistance is the primary force that would cause a satellite to descend low enough to burn up in Earth's atmosphere. As a satellite orbits, it experiences centripetal force that keeps it in orbit, but if it loses altitude due to drag from air resistance, the friction generated at lower altitudes can lead to increased heating and ultimately result in the satellite burning up. Gravitational force also plays a role, but it typically keeps the satellite in orbit rather than causing it to descend.
Its a centripetal force, whose origin/source is gravitation.
The natural satellite is held in orbit by the gravitational pull of the planet it orbits. This gravitational force acts as a centripetal force, keeping the satellite in a stable orbit around the planet.