Effects of gravity on a pendulum

AI Thread Summary
Gravity influences a pendulum's motion by accelerating it downward, increasing its speed as it descends and slowing it as it ascends. While gravity affects the oscillation, air resistance and friction are the primary factors that can halt its movement. The relationship between gravity and the pendulum's period is tied to gravitational acceleration, which determines the time it takes to complete a cycle. Understanding these dynamics is essential for conducting experiments related to gravitational acceleration. For a deeper analysis, researching "simple harmonic motion" can provide further insights.
bryans1mic
Messages
3
Reaction score
0
hi,
i have been doing research on the effects of gravity on a pendulum but i still can't seem to find the relationship between the two.

what i got so far is that gravity won't stop the pendulum but air resistance and friction would do the job and that gravity will only affect its oscillation? by making its trip smaller?

also a pendulum runs on sine/cosine curve?? how will gravity affect the period that it takes a pendulum to cycle through?

thanks
 
Physics news on Phys.org
Hello bryans1mic.Google "time period of a pendulum".
 
--^^ hi, i checked the link but it really didnt help much

im doing a gravitational acceleration lab and I am trying to understand how gravity works on a pendulum.

thanks

-bryan
 
Hello bryan.In a nutshell as the pendulum moves down gravity causes it to speed up and as it rises gravity causes it to slow down.The full analysis is well documented but a bit lengthy and I am confident you will get the information at the level you need by googling "simple harmonic motion".Have a look and if there is anything you don't understand then come back here.
 
Last edited:

Thread 'Derivation of Hamilton's Principle: Questions'

I have recently been really interested in the derivation of Hamiltons Principle. On my research I found that with the term ##m \cdot \frac{d}{dt} (\frac{dr}{dt} \cdot \delta r) = 0## (1) one may derivate ##\delta \int (T - V) dt = 0## (2). The derivation itself I understood quiet good, but what I don't understand is where the equation (1) came from, because in my research it was just given and not derived from anywhere. Does anybody know where (1) comes from or why from it the...
View full post »

Similar threads

A Modeling the damping of a physical rigid pendulum
Replies
1
Views
2K
Question regarging pendulum axis and its motion
Replies
5
Views
1K
Relationship between mass and acceleration
Replies
9
Views
3K
I How does a large-angle pendulum oscillate?
Replies
7
Views
3K
How Does Energy Transfer Work in Pendulums?
Replies
3
Views
2K
Pendulum is vibrating freely in unforced oscillation
Replies
1
Views
2K
Rolling Pendulum: Solving the Dynamics Equations
Replies
2
Views
3K
Pendulum Damping force effect on amplitude over time
Replies
1
Views
3K
Simple Harmonic Motion: why sin(wt) instead of sin(t)?
Replies
3
Views
7K
Looking for observed rotation periods of various Foucault pendulums at different latitudes
Replies
6
Views
848

Hot Threads

Recent Insights

Back
Top