For a given mass, the acceleration is directly proportional to the net force acting on the mass, and is in the same direction as the net force. In other words, the larger the net force acting on an object, the greater its acceleration. When the net force is zero, the object is either at rest or moving with a constant velocity.
If the force is constant then acceleration is inverse related to mass.
Force = Mass x Acceleration
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 acceleration is kept constant but you vary the mass, the force will vary in direct proportion to the mass. If the mass increases, the force will also increase, and if the mass decreases the force will also decrease. Newton's 2nd Law, illustrated by the equation F=ma, illustrates this.
Newtons second law states that the acceleration of a body is proportional to the force applied to it.
force directly proportional to acceleration. so F/a is remains constant. which is equal to mass of an object
Force = (mass) times (acceleration) Constant force produces constant acceleration.
Force = Mass x Acceleration
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 the applied force is constant, the acceleration will also be constant. To know the actual amount of acceleration, you divide the force by the mass.
Directly. (F = m a) If a (acceleration) is a constant then the relationship between farce and mass is constant.
F=ma, force = mass x acceleration. Therefore, more mass means more force is required.
Both mass and acceleration will remain constant but speed will increase. Its explained in Newtons second law, in short: F=m*a
force= mass times acceleration
They are directly related. As with Newton's second law, Force = mass times acceleration, you can see that as force increases, the mass increases and vice versa. F=m*a. If you keep the acceleration constant, then as the mass increases, the force will increase as well.
If acceleration is kept constant but you vary the mass, the force will vary in direct proportion to the mass. If the mass increases, the force will also increase, and if the mass decreases the force will also decrease. Newton's 2nd Law, illustrated by the equation F=ma, illustrates this.
ma=F (mass)(acceleration)=Force
It depends on the force. The acceleration due to gravity (for small objects) is essentially independent of mass, although air friction may be worse for very small objects. If, however, you have a constant force. F = MA Force = Mass * Acceleration. Divide each side by mass and you get: Acceleration = (Force / Mass) So, for constant force, the more mass an object has, the less acceleration. Or, you could say that for constant force, the acceleration is inversely proportional to the mass.