acceleration doubles too.
The acceleration will be doubled accordingly. From 10m/s2 to 20.
you have to take mass and acceleration to get force
The cart's acceleration will be directly proportional to the net force applied to it. If the force remains constant, the acceleration will also remain constant, assuming no other external factors are affecting the cart's motion.
My bad, im asking why the formula isnt acceleration= force - mass
The law states that Force = Mass * Acceleration, and that is what the law shows.
force = mass x acceleration so if force doubles acceleration doubles to 8 m/s2
The acceleration of an object is proportional to the net force acting on it. So if the force is reduced by half, the acceleration will also be halved. Of course, it will still be accelerating in the same direction as before, but not as quickly.
Acceleration is a net force that is inversely dependent on mass, therefore if an object mass increases ,acceleration decreases
Acceleration is a net force that is inversely dependent on mass, therefore if an object mass increases ,acceleration decreases
F=ma, if "a" doubles and "m" is the same, the resultant "F" will double. Acceleration is doubled if force is doubled, a1=f/m; a2= 2f/m= 2a1.
Acceleration becomes 50% less.
It is acceleration in the horizontal direction. This would happen as a result of a net horizontal force acting on a body.
The force equal mass times acceleration, if force remains the same, and mass is doubled, then acceleration must be cut in half.
If both the mass and the net force on an object are doubled, then the object's acceleration will not change.
If you doubled the force on a moving object you would double its acceleration.
When a mass is acted on by a constant force, such as in free-fall or in orbit.
Force = mass x acceleration, therefore, acceleration = force / mass.Force = mass x acceleration, therefore, acceleration = force / mass.Force = mass x acceleration, therefore, acceleration = force / mass.Force = mass x acceleration, therefore, acceleration = force / mass.