If you have the mass, you can find the acceleration from Newton's Second Law, a=F/m where a is the acceleration, m is the mass, and F is the force. Then the velocity is given by the standard formula v=vo+at where v is the final velocity, vo the velocity at t=0, probably 0 in your case. If so v=at.
You do not need force. Velocity is the integral of acceleration with respect to time. The orthogonal components of acceleration can be integrated independently to give the orthogonal components of velocity.
Force equals mass times acceleration.
Velocity = (velocity when time=0) + (Force x time)/(mass) ===> F = MA A = F/M V = V0 + A T
Without distance, you have to know time, initial velocity, and acceleration, in order to find final velocity.
There is not enough information. Force = Mass*Acceleration. Acceleration is the rate of change in velocity. This requires information on change in velocity as well as the time over which the change took place. There is no information at all on the latter.
You do not need force. Velocity is the integral of acceleration with respect to time. The orthogonal components of acceleration can be integrated independently to give the orthogonal components of velocity.
Force equals mass times acceleration.
Work W=Pt power times time, W = FVt.
Not enough information. You can calculate force by Newton's Second Law, but in this case, there is no way to know how fast the velocity changes - or whether it changes at all.
Velocity = (velocity when time=0) + (Force x time)/(mass) ===> F = MA A = F/M V = V0 + A T
To get the potential energy when only the mass and velocity time has been given, simply multiply mass and the velocity time given.
Velocity can only be identified by acceleration or time, even though we can also find it using force
Time equals velocity divided by acceleration. t=v/a
Without distance, you have to know time, initial velocity, and acceleration, in order to find final velocity.
There is not enough information. Force = Mass*Acceleration. Acceleration is the rate of change in velocity. This requires information on change in velocity as well as the time over which the change took place. There is no information at all on the latter.
Equation: Force=Mass X AccelerationIf you are looking for the force, use the equation as is.To find the following, it's assumed that you are given the other two values:Mass= Force / AccelerationAcceleration= Force / MassRemember your labels in your calculations.Mass= force x accelerationForce = mass x accelerationmass = force / accelerationacceleration = force / massSince acceleration = velocity / time we can also substitute velocity / time for acceleration in any of the above.Since velocity = speed / time, we can also substitute speed / time for velocity or speed / (time * time) for acceleration in any of the above.
You can't. The mass is irrelevant to velocity. You need the distance.