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force= mass times acceleration
Regarding their magnitudes . . . Acceleration is the time rate of change of velocity. Regarding their directions . . . There's not necessarily any relationship between the two.
The two are unrelated. Potential energy depends on height; acceleration due to gravity is more or less constant.
When the pendulum swings up, it gains potential energy, but loses kinetic energy. Therefore when it swing down, it gains kinetic energy, but loses potential energy.
A swinging pendulum demonstrates primarily two types of energy - kinetic energy when the pendulum is in motion, and potential energy - based on how high it is above the mid-point of the swing. If not for friction, a pendulum would continue to swing forever, with the sum of the kinetic and potential energy remaining constant but the distribution between the two constantly changing as the pendulum moved through its swings.
For small angles, the formula for a pendulum's period (T) can be approximated by the formula:T = 2 * pi * sqrt(L/g), where L is the length of the pendulum length, and g is acceleration due to gravity. See related link for Simple Pendulum.
No Gravitational potential energy equals no force and thus no acceleration.
well the relationship between mass and force is..........*relationship... Force=mass x acceleration
There's no relationship between the length of the pendulum and the number of swings.However, a shorter pendulum has a shorter period, i.e. the swings come more often.So a short pendulum has more swings than a long pendulum has in the same amountof time.
Force in Newtons = mass in kilograms * acceleration ( can be gravitational acceleration )F = maThe mathematical relationship between force and acceleration is directly proportional.
What relationship "defines" acceleration? What relationship "states" how acceleration is produced? Please clarify.
T=1/2l
sorry '=
Acceleration is force divided by mass.
F=m•A Force=mass•acceleration
force= mass times acceleration
Regarding their magnitudes . . . Acceleration is the time rate of change of velocity. Regarding their directions . . . There's not necessarily any relationship between the two.