How do I solve this? A pendulum on a grandfather clock is supposed to oscillate once...
Suppose you are the proud owner of a grandfather clock that has a pendulum with a nominal length of 1 meter. You find that the clock runs fast so that it gains 1 second every hour. Should the pendulum be shortened or lengthened to make the clock run on time? By how much?
A grandfather clock has a pendulum that consists of a thin brass
disk of radius 37 cm and mass 1.6 kg that is attached to a long,
thin rod of negligible mass. The pendulum swings freely about an
axis perpendicular to the rod and through the end of the rod
opposite the disk. The pendulum should be designed so that its
period is 2 s for small oscillations when the gravitational
acceleration is 9.8 m/s2.
(a) What should the length...
Your grandfather clock's pendulum has a length of 0.9930 m. If the clock runs slow and loses 18 s per day, how should you adjust the length of the pendulum? Note: due to the precise nature of this problem you must treat the constant g as unknown (that is, do not assume it is equal to exactly 9.80 m/s2).
A grandfather clock has a pendulum that consists of a thin brass
disk of radius 27 cm and mass 1.1 kg that is attached to a long,
thin rod of negligible mass. The pendulum swings freely about an
axis perpendicular to the rod and through the end of the rod
opposite the disk. The pendulum should be designed so that its
period is 2 s for small oscillations when the gravitational
acceleration is 9.8 m/s2.
(a) What should the length...
A grandfather clock has a pendulum that consists of a thin brass disk of radius r = 14.38 cm and mass 0.8261 kg that is attached to a long thin rod of negligible mass. The pendulum swings freely about an axis perpendicular to the rod and through the end of the rod opposite the disk, as shown in the figure. If the pendulum is to have a period of 1.592 s for small oscillations at a place where g =...
A grandfather clock has a pendulum that consists of a thin brass disk of radius 40 cm and mass 1.9 kg that is attached to a long, thin rod of negligible mass. The pendulum swings freely about an axis perpendicular to the rod and through the end of the rod opposite the disk. The pendulum should be designed so that its period is 2 s for small oscillations when the gravitational acceleration is 9.8 m/s2. (a) What should the length...
once I find out per day 90/60*24*60, how do you get
period. fully explain each step and why please. know answer need to
know why
PHY 162 NOT Problems 453 r 7. A clock is constructed so that it keeps perfect time when its simple pendulum has a period of 1.000 s at locations where g = 9.800 m/s. The pendulum bob has length L 0.2482 m, and instead of keeping perfect time, the clock runs slow by 1.500 minutes...
You are visiting your grandparents in Boston. There is an antique grandfather clock keeping time in one of the rooms. Your grandmother enters the room and tells you that she had it calibrated professionally in Denver and it kept perfect time for years. After they moved it here to their Massachusetts house, it has not been accurate. It runs too fast and has to be reset to the correct time every few days. You find some papers associated with the...
You are visiting your grandparents in Boston. There is an antique grandfather clock keeping time in one of the rooms. Your grandmother enters the room and tells you that she had it calibrated professionally in Denver and it kept perfect time for years. After they moved it here to their Massachusetts house, it has not been accurate. It runs too fast and has to be reset to the correct time every few days. You find some papers associated with the...
a 2kg mass attached to a spring of k = 32 N/m is free to
oscillate on a horizontal frictionless surface. the mass is
displaced 8 cm to the the right of its equilibrium and set into
motion with a leftward push of speed 40 cm/s
c) now consider a simple pendulum that undergoes half as many
oscillations per unit time as this mass. the pendulum is released
from rest at position 1 and oscillates between position 1 and 3....