In the equation: F is force, m is mass, and a is acceleration. Divide both sides by a, and you have:m = F/a, which is Force divided by acceleration.
Thanks to Isaac Newton's Second Law of Motion, one can determine the mass of an object if he or she knows both the force acting upon the object and the acceleration of the object. Newton's equation is as follows: F = ma; where "F" is the force acting upon the object, "m" is the mass of the object. and "a" is the acceleration of the object. Solving for "m", the equation can be rewritten as: m = F/m. Substitute force for "F", and acceleration for "a", and you can solve for the mass of the object.
vf=vi+at equation can be solved by substituting the letters in the equation with there actual values where vf is the finall velocity, vi is the initial velocity, a is the acceleration and t is the time.
A equals Vf minus Vi divided by time equals triangle v divided by time
solve it
You have a contradiction in your question. Instantaneous acceleration is the acceleration at a certain moment in time. Average acceleration is the average over a time interval.
Acceleration is the derivative of the velocity expression. If you have an equation for velocity, simply take the derivative of it and you will have an equation for the average acceleration.
Average speed = Distance travelled/time to travel the distance . Average acceleration = Change of speed/time for the change .
In the equation: F is force, m is mass, and a is acceleration. Divide both sides by a, and you have:m = F/a, which is Force divided by acceleration.
There are various equations that involve acceleration; the simplest one is the definition of acceleration: acceleration = (change of velocity) / time.
The acceleration of the ball would depend on its mass and the force of the push. This is because force = mass times acceleration. You could manipulate this equation to solve for acceleration by dividing each side by mass. Acceleration therefore equals force/mass.
The acceleration of the ball would depend on its mass and the force of the push. This is because force = mass times acceleration. You could manipulate this equation to solve for acceleration by dividing each side by mass. Acceleration therefore equals force/mass.
F=ma, where F is force, m is mass, and acceleration is a. F/a=m
You can write an equation, using the definition of "average", then solve it. The equation would look like this:"the average of a and -5" is 10 (a - 5) / 2 = 10
Thanks to Isaac Newton's Second Law of Motion, one can determine the mass of an object if he or she knows both the force acting upon the object and the acceleration of the object. Newton's equation is as follows: F = ma; where "F" is the force acting upon the object, "m" is the mass of the object. and "a" is the acceleration of the object. Solving for "m", the equation can be rewritten as: m = F/m. Substitute force for "F", and acceleration for "a", and you can solve for the mass of the object.
Rewrite the equation F = ma to solve for acceleration a = F / m = 600 / 100 = 6 m/s^2
vf=vi+at equation can be solved by substituting the letters in the equation with there actual values where vf is the finall velocity, vi is the initial velocity, a is the acceleration and t is the time.