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It is your weight, which manifests as a downward force exerted by your body, although it is also an acceleration to a greater force if you fall.
Force is directly proportional to acceleration, so the greater the force, the greater the acceleration.
the mass (m) of an object times its acceleration (a) is the force (f) exerted on the object. f=ma
inertial mass
To calculate the force exerted by a person on the floor, we can use Newton's second law of motion: force = mass × acceleration. In this case, the mass would be the person's weight (mass = weight / acceleration due to gravity), and the acceleration would be the force of gravity acting on the person (acceleration = 9.8 m/s^2). By multiplying the person's weight by the acceleration due to gravity, we can determine the force exerted by the person on the floor.
It is your weight, which manifests as a downward force exerted by your body, although it is also an acceleration to a greater force if you fall.
an object's mass
Force is directly proportional to acceleration, so the greater the force, the greater the acceleration.
the mass (m) of an object times its acceleration (a) is the force (f) exerted on the object. f=ma
inertial mass
To calculate the force exerted by a person on the floor, we can use Newton's second law of motion: force = mass × acceleration. In this case, the mass would be the person's weight (mass = weight / acceleration due to gravity), and the acceleration would be the force of gravity acting on the person (acceleration = 9.8 m/s^2). By multiplying the person's weight by the acceleration due to gravity, we can determine the force exerted by the person on the floor.
Changing the magnitude or direction of forces exerted on an object changes the net force (sum of all forces) exerted on the object. The net force exerted on an object is defined as mass times acceleration (F = ma), where mass, m, is constant. This means that when the net force exerted on the object changes in magnitude (or direction), its acceleration will also change in magnitude (or direction). In addition, acceleration is defined as the change in velocity, so when the magnitude (or direction) of acceleration changes, the magnitude (or direction) of velocity will also change.
The wall exerted less force, so the force exerted on the wall by the locomotive was greater than the force of the wall.
Acceleration. Force is equal to mass times the acceleration, so in this case, acceleration is how fast an object increases its velocity.
force = mass x acceleration so if force doubles acceleration doubles to 8 m/s2
The force exerted is dependent on the mass of the object.
Newton's second law of motion states that force is equal to mass times acceleration, or F = ma. So, if a force is exerted on something that has mass, it will accelerate.