When force is constant, mass and acceleration are inversely related.
ma=k, m=k/a or a=k/m.
The smaller the mass, the greater the acceleration.
The greater the mass the smaller the acceleration.
Because force and acceleration are both vectors, the direction of acceleration is the same as the direction of force.
For constant force the relationship of mass and acceleration is an Hyperbolic relationship. This means the product of mass and acceleration is a constant and as mass goes up the acceleration goes down and vice versa. In other words the mass and acceleration are inversely related; F=ma=k; m=k/a and a=k/m.
When force is constant, mass and acceleration are inversely related.
ma=k, m=k/a or a=k/m.
The smaller the mass, the greater the acceleration.
The greater the mass the smaller the acceleration.
Because force and acceleration are both vectors, the direction of acceleration is the same as the direction of force.
If force is constant, then the product of (mass x acceleration) is constant,
so they must be inversely proportioinal.
Directly, double the force = double the acceleration, half the force = half the acceleration etc
F = m a
(Mass) x (Acceleration)
acceleration
According to Newton's second law of motion, the acceleration of a body is directly proportional to the net force and inversely proportional to its mass. a = F/m This law is most often used relating force to mass and acceleration, in which the net force is directly proportional to a body's mass and acceleration, F = ma.
F = ma Force is equal to mass times acceleration.
For where F=force, m=mass, and a= acceleration: F=ma
(Mass) x (Acceleration)
acceleration
Force is the product of mass and acceleration, F= ma.
Force=mass*acceleration
No Gravitational potential energy equals no force and thus no acceleration.
Mass
Force = Mass X Acceleration Or just Force, Mass, Acceleration.
Newton's Second Law: force = mass x acceleration
Acceleration is proportional to the force applied and inversely proportional to the mass
According to Newton's second law of motion, the acceleration of a body is directly proportional to the net force and inversely proportional to its mass. a = F/m This law is most often used relating force to mass and acceleration, in which the net force is directly proportional to a body's mass and acceleration, F = ma.
According to newtons second law of motion when the net force on an object is greater than 0, F=m*a where a is the acceleration, m is the mass, and F is the force.
the second law of motion states the relationship between force, mass and acceleration. acceleration= force/mass