you tell my the answer
12/6.4=1.9m/sec2
1.88m/s^2
12/6.4=1.9m/sec2
12/6.4=1.9m/sec2
since force is mass and acceleration the force needed to knock over a bowling depends on the mass of bowling and it acceleration.
No. Acceleration is proportional to the applied force.
Acceleration is 2m/s^2
Acceleration due to gravity is related to the gravitational force (or, more accurately, the gravitational field). This field causes an acceleration of 9.8 meters/second2. This is equivalent to 9.8 newton/kilogram, that is, every kilogram of mass is subject to a force of 9.8 newton. The gravitational field is often expressed in acceleration units, but the two are really equivalent: a net force of 9.8 newton, applied to a mass of 1 kilogram, will cause that much acceleration.
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.
Acceleration increases as force increases.
the weight of a body is the force exerted by gravity to the body and is proportional to the mass of the body. A force applied to a body will give him an acceleration. The relation between the force f applied to the body, its mass m and the acceleration a is given by Newton's second law of motion ; f = ma The acceleration given by gravity to bodies at sea level is referred to as the standard gravity acceleration and has the value of 9.81 m/s2 (rounded to 3 digits). So, if you have a body with mass 0.5 kg, the weight of it at sea level would be, 0.5 kg x 9.81 m/s2 = 4.9 newtons When a body is subject to the standard gravity acceleration a mass of one kilogram (mass kilogram) weights one kilogram (force kilogram). In the International Units System, the unit for mass is the kilogram and the unit of force is the newton. The force kilogram is avoided as to not produce confusion.
When the applied force increases, the acceleration increases When the applied force decreases, the acceleration decreases. This can be explained using Newton's second law of motion. F = ma
Acceleration is directly proportional to applied force. When acceleration increases, force also increases. If the force is tripled, the acceleration will also be tripled. Note that the mass must remain constant...
Acceleration is in the same direction as the applied force.