-- the object's mass
-- the net force acting on it
The two factors are 1. the mass of the object, and 2. the force exerted on it.
Objects fall at a constant acceleration. For an object on the planet Earth, that acceleration is 9.8m/s^2, or 32ft/s^2.
When falling to the ground (or even just in the air), the acceleration of an object depends on the gravitational pull of the object it is falling towards. Here on earth, all things fall relative to the earth which causes an acceleration of 9.81 m/s^2
If the object is moving in a positive direktion along its x-axis and the acceleration is in the opposite direction (negative acceleration, i.e. retardation), then yes. Lets say the acceleration is -2 m/s^2 and its increasing with a magnitude of 2 then the new acceleration would be -4 m/s^2. Sure, the object was already slowing down but now its slowing down even more.
The acceleration of gravity due to a single object is(Universal gravitational constant) x (Mass of the object)/(distance from the object's center of mass)2
The two factors are 1. the mass of the object, and 2. the force exerted on it.
When the acceleration is constant then s= 1/2 at^2 and the acceleration is a=2s/t^2.
Objects fall at a constant acceleration. For an object on the planet Earth, that acceleration is 9.8m/s^2, or 32ft/s^2.
Acceleration is 1.7m/s^2
When falling to the ground (or even just in the air), the acceleration of an object depends on the gravitational pull of the object it is falling towards. Here on earth, all things fall relative to the earth which causes an acceleration of 9.81 m/s^2
If the object is moving in a positive direktion along its x-axis and the acceleration is in the opposite direction (negative acceleration, i.e. retardation), then yes. Lets say the acceleration is -2 m/s^2 and its increasing with a magnitude of 2 then the new acceleration would be -4 m/s^2. Sure, the object was already slowing down but now its slowing down even more.
work = force * distance and force = mass * acceleration and acceleration = change in velosity/change in time so work = mass * acceleration * distance , as a result work = mass * change in velosity/change in time * distance, hence the velocity of the object affected by : 1.mass of the object. 2. gravitational acceleration which reduces the speed of the object when go up and increases the speed of the object when it come down.. 3. look at the rules etc........thx..............with best regards
Both objects would eventually reach terminal velocity which means they would both fall at the same speed.- But - compared to the falling object, the downward acceleration of a thrown object is the same.
The acceleration of gravity due to a single object is(Universal gravitational constant) x (Mass of the object)/(distance from the object's center of mass)2
If the object is moving in a positive direktion along its x-axis and the acceleration is in the opposite direction (negative acceleration, i.e. retardation), then yes. Lets say the acceleration is -2 m/s^2 and its increasing with a magnitude of 2 then the new acceleration would be -4 m/s^2. Sure, the object was already slowing down but now its slowing down even more.
2
I'm not sure exactly what you're asking, but hopefully this answers your question. A=Acceleration F=Force M=Mass The acceleration of an object is dependent on the mass of the object and the force exerted on it. The greater the force is, the greater the acceleration. The greater the mass is, the lower the acceleration. The greater the mass of the object, the more force required to obtain the same acceleration. Examples: Let's say you have an object of mass 8. If you were to exert 16 force, then the acceleration would be 2, but if you exert 4 force, the acceleration is 1/2. Similarly, if you exert 8 force on 2 objects, with masses 16 and 4, then the object with mass 16 would have an acceleration of 1/2, while the object with a mass of 4 would have an acceleration of 2. Hopefully this helped, sorry if it wasn't what you were asking. Also, I think this should be in physics/science, not algebra.