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The formula for force is( Force=mass multiplied by acceleration). To answer your question, we can see that as and distance are directly proportional. If you increase mass, to get to your target force, you will not need as much acceleration.
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...
If both the mass and the net force on an object are doubled, then the object's acceleration will not change.
Doc. Newton tells us in his second law thatF=maor force equals mass times acceleration where the mass is Kilograms, the acceleration is meters/second and force is in Newtons.Measure the mass of the soccerball, guestimate the acceleration of the ball (change in speed divided by the elapsed time) and multiply them. Bingo, force.
Mass doesn't like to move. Rather, it doesn't like to be forced to move. The first law of motion by Newton states that an object in motion will stay in motion until an external force is acted upon it. The second law of motion by Newton states that force is equal to mass multiplied by acceleration. The more something weighs, or the more mass it has, the more acceleration or force is required to move it. So to answer your question shortly, increase in mass affects how much acceleration or force is needed to move that mass.
It depends on the amount of force force=distance*acceleration
Force equals mass times acceleration.
since force is mass and acceleration the force needed to knock over a bowling depends on the mass of bowling and it acceleration.
The formula for force is( Force=mass multiplied by acceleration). To answer your question, we can see that as and distance are directly proportional. If you increase mass, to get to your target force, you will not need as much acceleration.
By definition, if two things are proportional to one and other, they are connected by a multiplying constant. If F = m + a you would simple say F is a bigger than m and it would also require that force, mass and acceleration all shared the same dimensions and units. Clearly mass is a scalar and force and acceleration are vectors, so that is not the case. Also, if they shared the same dimensions, they would effectively be the same thing so F = m + a would be the same as F(total) = F(1) + F(2) which wouldn't tell us very much about the laws of physics at all. Also, you don't say force is proportional to mass times acceleration (it's EQUAL to mass times acceleration). It's either force is proportional to mass (in which case acceleration is the factor of proportionality) or force is proportional to acceleration (in which case it is mass).
Well according to the equation Force = Mass x Acceleration. A bowling ball has more mass than a feather but it all depends on how much acceleration each is undergoing. Potentially a feather can have more force (if the bowling ball has an acceleration of zero, then there is no force being produced, and if the feather is accelerating at any speed greater than zero, thentechnicallyit has more force)
Force is equal to Mass times Acceleration. So if you are given an equation where you know two of the three variables you can find the third. You can also manipulate the equation as needed.
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...
If both the mass and the net force on an object are doubled, then the object's acceleration will not change.
Doc. Newton tells us in his second law thatF=maor force equals mass times acceleration where the mass is Kilograms, the acceleration is meters/second and force is in Newtons.Measure the mass of the soccerball, guestimate the acceleration of the ball (change in speed divided by the elapsed time) and multiply them. Bingo, force.
Mass doesn't like to move. Rather, it doesn't like to be forced to move. The first law of motion by Newton states that an object in motion will stay in motion until an external force is acted upon it. The second law of motion by Newton states that force is equal to mass multiplied by acceleration. The more something weighs, or the more mass it has, the more acceleration or force is required to move it. So to answer your question shortly, increase in mass affects how much acceleration or force is needed to move that mass.
Any amount of force, no matter how large or small, will increase or decrease the speed of any mass, no matter how large or small. But if you specify how much you want the object's speed changed and how quickly you want it done, then you have specified the acceleration you want. In that case, the larger the mass is, the more force it will take to accomplish that assignment.