This caculation for the change in height of the bob is incorrect. Draw yourself a diagram showing the initial and final positions of the bob and recalculate the initial height.looi76 said:
cos60*40 is the vertical distance below the pivot point. To find the change in height, you must subtract this from the length of the string. Luckily, 40 - 20 = 20.looi76 said:
Ok! Thanks...The speed of the pendulum bob is determined by the length of the pendulum, the gravitational acceleration, and the angle at which the pendulum is released. It can be calculated using the equation v = √(g * L * (1-cosθ)), where v is the speed, g is the gravitational acceleration, L is the length of the pendulum, and θ is the angle of release.
No, the mass of the pendulum bob does not affect its speed. The speed of the pendulum is determined by the length and angle of release, not the mass of the bob.
Changing the length of the pendulum will affect its speed. As the length increases, the speed decreases. This is because a longer pendulum has a longer period of oscillation, meaning it takes longer to complete one cycle, resulting in a lower speed.
Yes, the speed of the pendulum bob can be increased by increasing the angle of release. This will result in a larger initial velocity, leading to a higher speed.
Air resistance can have a significant effect on the speed of the pendulum bob. As the bob swings, it will encounter air resistance which will slow it down. This can be minimized by using a streamlined bob and conducting the experiment in a vacuum.