inertial mass
That's the acceleration of gravity. It depends on the distance from the primary object it refers to. It's as constant as that distance is.
Acceleration occurs when the velocity of an object changes. Velocity is the speed and direction of an object. Newton's Second Law of Motion defines what happens when a force acts on an object. The object accelerates in the direction in which the force is acting. A force acting on a stationery object starts it moving. A force acting on a moving object will speed it up, slow it down, or change the direction in which it is movingDefinition of deceleration: (physics) a rate of decrease in velocityDefinition of acceleration: (physics) a rate of increase of velocityProps to Google :)
Assuming by "the force acting on an object" you mean the cause of its acceleration, its acceleration will be doubled. If there is more than one force acting on it, the vector of the force will have to be analyzed by its effect on each of the other forces.
F = mgThe basic formula is F = ma (F - force, m - mass, a - acclereation), but if the object is free falling we already know that his acceleration equals gravity, g.In terms of the question that was asked, which is always a nice way to respond,the ratio of force to mass for all freely falling objects is the acceleration of gravity.That's always the same number, everybody wants to know why, and this questionis a super way to explain it.The force on the falling object is its weight. F = m aDivide each side of that equation by 'm', and you have a = F/mNow look at that fraction. The 'F' on top is the Force of gravity, which we call 'weight'.The more mass an object has, the heavier it is. That means that 'F' depends on 'm'.So there's an 'm' involved in the top of the fraction, and also an 'm' on the bottom.If 'm' changes, then the top and bottom of the fraction change together, and thevalue of the whole fraction doesn't change at all. The value of the fraction staysthe same, it's the ratio of weight to mass, and that's always the same number . . .the acceleration of gravity.
So simple. Right from the ratio of the force applied to the mass of the body.
-- When the net force on an object is not zero, the object undergoes accelerated motion.-- The magnitude of the acceleration is the ratio of the net force to the object's mass.-- The direction of the acceleration is the same as the direction of the net force.
The ratio is the M/cos(x). where M is the mass on which the force is acting and x is the angle between the direction of the force and the direction of the acceleration.
That's the acceleration of gravity. It depends on the distance from the primary object it refers to. It's as constant as that distance is.
Force is force. Whether it is measured on the moon or elsewhere: it is mass*acceleration (in the direction of the force).
Acceleration occurs when the velocity of an object changes. Velocity is the speed and direction of an object. Newton's Second Law of Motion defines what happens when a force acts on an object. The object accelerates in the direction in which the force is acting. A force acting on a stationery object starts it moving. A force acting on a moving object will speed it up, slow it down, or change the direction in which it is movingDefinition of deceleration: (physics) a rate of decrease in velocityDefinition of acceleration: (physics) a rate of increase of velocityProps to Google :)
Assuming by "the force acting on an object" you mean the cause of its acceleration, its acceleration will be doubled. If there is more than one force acting on it, the vector of the force will have to be analyzed by its effect on each of the other forces.
F = mgThe basic formula is F = ma (F - force, m - mass, a - acclereation), but if the object is free falling we already know that his acceleration equals gravity, g.In terms of the question that was asked, which is always a nice way to respond,the ratio of force to mass for all freely falling objects is the acceleration of gravity.That's always the same number, everybody wants to know why, and this questionis a super way to explain it.The force on the falling object is its weight. F = m aDivide each side of that equation by 'm', and you have a = F/mNow look at that fraction. The 'F' on top is the Force of gravity, which we call 'weight'.The more mass an object has, the heavier it is. That means that 'F' depends on 'm'.So there's an 'm' involved in the top of the fraction, and also an 'm' on the bottom.If 'm' changes, then the top and bottom of the fraction change together, and thevalue of the whole fraction doesn't change at all. The value of the fraction staysthe same, it's the ratio of weight to mass, and that's always the same number . . .the acceleration of gravity.
So simple. Right from the ratio of the force applied to the mass of the body.
The ratio of (distance) / (time), called "speed".The ratio of (speed) / (time), called "acceleration".The ratio of (force) / (area), called "pressure".The ratio of (force) / (acceleration), called "mass".The ratio of (mass) / (volume), called "density".The ratio of (distance) / (volume), sometimes called "fuel economy".The ratio of ( 1 ) / (time), called "frequency".The ratio of (energy) / (time), called "power".
The force represents the ratio between the rotational work and the radius of rotation.
the ratio of the total change in velocity of the object during motion to the total time taken.
The relationship between force and acceleration mathematically is proportional, as seen in the second low of motion F = m*a. The acceleration of an object will be equal to the ratio of the net force on the object to the mass.