F = M A
F = force
M = mass of the object being forced
A = the object's acceleration
You want A = 1.8 G = 1.8 x 9.8 = 17.64 meters per second2
Fnewtons = (17.64) x (Mkilograms)
And what is the question?If you want to figure out the mass of the planet: First, use the formula for centripetal acceleration to get the acceleration. Then, use the gravitation formula to calculate the mass required to produce that acceleration.And what is the question?If you want to figure out the mass of the planet: First, use the formula for centripetal acceleration to get the acceleration. Then, use the gravitation formula to calculate the mass required to produce that acceleration.And what is the question?If you want to figure out the mass of the planet: First, use the formula for centripetal acceleration to get the acceleration. Then, use the gravitation formula to calculate the mass required to produce that acceleration.And what is the question?If you want to figure out the mass of the planet: First, use the formula for centripetal acceleration to get the acceleration. Then, use the gravitation formula to calculate the mass required to produce that acceleration.
Where the question says "2.8 g", we understand that to mean2.8 times the acceleration of gravity = 27.44 m/sec2 .F = M A = (1.2 kg) x (27.44 m/s2) = 32.928 newtons
Gravity must be the only force acting on the object, to produce downwards vertical acceleration. There is no force acting in the horizontal direction because there is no acceleration.
As per Newton's first law of motion, if the applied force remains the same, an increase in mass will result in a decrease in acceleration. In contrast, if the acceleration were to remain the same when the mass increases, there must be a greater force applied.
When you apply a force to a mass you produce acceleration. "Tiny" and "large" are not well defined here, but the basic equation is F = ma, so if the forces are proportional to the masses in each case (for example, a 0.1 N force applied to a 0.1 g object and a 1000 N force applied to a 1000 g object) then you will produce the same acceleration for both objects.
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.
And what is the question?If you want to figure out the mass of the planet: First, use the formula for centripetal acceleration to get the acceleration. Then, use the gravitation formula to calculate the mass required to produce that acceleration.And what is the question?If you want to figure out the mass of the planet: First, use the formula for centripetal acceleration to get the acceleration. Then, use the gravitation formula to calculate the mass required to produce that acceleration.And what is the question?If you want to figure out the mass of the planet: First, use the formula for centripetal acceleration to get the acceleration. Then, use the gravitation formula to calculate the mass required to produce that acceleration.And what is the question?If you want to figure out the mass of the planet: First, use the formula for centripetal acceleration to get the acceleration. Then, use the gravitation formula to calculate the mass required to produce that acceleration.
Where the question says "2.8 g", we understand that to mean2.8 times the acceleration of gravity = 27.44 m/sec2 .F = M A = (1.2 kg) x (27.44 m/s2) = 32.928 newtons
Gravity must be the only force acting on the object, to produce downwards vertical acceleration. There is no force acting in the horizontal direction because there is no acceleration.
Newtons 2nd law means that when force is applied on any object an acceleration is produced in the direction of force which is applied on it. The acceleration produced in the object is directly proportional to the force applied on the object i.e. if force increases then acceleration will also increase and the acceleration is inversely proportional to the mass of object i.e. if the mass of the body decreases then acceleration will increase. If force is represented by 'F', acceleration by 'a' and mass by 'm' then a is directly proportional to F a is inversely proportional to m
As per Newton's first law of motion, if the applied force remains the same, an increase in mass will result in a decrease in acceleration. In contrast, if the acceleration were to remain the same when the mass increases, there must be a greater force applied.
There is no such law. Newton's Second Law states that: force = mass x acceleration So, more force will produce more acceleration. More mass will result in less acceleration. However, the mass of a body usually doesn't change - but you can use this law to compare the same force applied to different objects, of a different mass.
When you apply a force to a mass you produce acceleration. "Tiny" and "large" are not well defined here, but the basic equation is F = ma, so if the forces are proportional to the masses in each case (for example, a 0.1 N force applied to a 0.1 g object and a 1000 N force applied to a 1000 g object) then you will produce the same acceleration for both objects.
200 backwards force.
In very general terms, the application of a force will produce an acceleration.
Yes it can, and if less force is needed if you eliminate the possibility of friction. You can find many examples of this, but i think this is an excellent opportunity to devise an experiment and practice your scientific methods.
You can use Newton's Second Law to calculate this.