Suppose the acceleratio due to gravity at thth's surface is `10ms^-2` and at the surface of Mars it is `4.0ms^-2`. A passenger goes from the to the mars in a spacehip with a constant velocity. Neglect all other object in sky. Which part of figure best represent the weight (net gravitational force) of the passenger as a function of time?

Suppose the acceleration due to gravity at earth's surface is 10ms^-2 and at the surface of Mars it is 4.0ms^-2 . A passenger goes from the to the mars in a spaceship with a constant velocity. Neglect all other object in sky. Which part of figure best represent the weight (net gravitational force) of the passenger as a function of time?

Suppose the acceleration due to gravity at earth's surface is 10ms^-2 and at the surface of Mars it is 4.0ms^-2 . A passenger goes from the earth to the mars in a spaceship with a constant velocity. Neglect all other object in sky. Which part of figure best represent the weight (net gravitational force) of the passenger as a function of time?

Suppose the acceleration due to gravity at earth's surface is 10ms^-2 and at the surface of Mars it is 4.0ms^-2 . A passenger goes from the earth to the mars in a spaceship with a constant velocity. Neglect all other object in sky. Which part of figure best represent the weight (net gravitational force) of the passenger as a function of time?

If the acceleration due to gravity on 3.8 ms^-2 , then what would be the weight object on mars which has a mass of 10 kg on moon.

If accleration due to gravity on the surface of earth is 10ms^(-2) and let acceleration due to gravitational acceleration at surface of another planet of our solar system be 5ms^(-2) An astronaut weighing 50kg on earth goes to this planet in spaceship with a constant velcity The weight of the astronaut with time of fiight is roughly given by .

If accleration due to gravity on the surface of earth is 10ms^(-2) and let acceleration due to gravitational acceleration at surface of another planet of our solar system be 5ms^(-2) An astronaut weighing 50kg on earth goes to this planet in spaceship with a constant velcity The weight of the astronaut with time of fiight is roughly given by .