How Does Magnet Height Affect a Pendulum's Period?

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The discussion centers on an experiment involving a pendulum with an iron mass and a magnet positioned below it, where the goal is to determine the magnetic force as a function of the distance between the two. The participants explore how to incorporate the magnetic force into the pendulum's period equation, T = 2π√(l/g), by considering the total effective acceleration due to both gravity and the magnetic force. They discuss using ratios of periods and distances to derive relationships between the magnetic force and distance, emphasizing the need to analyze data to find a linear relationship. The conversation highlights the importance of experimenting with different distances and periods to establish a connection that can be graphed and analyzed. Overall, the participants express confidence in their ability to complete the experiment with the insights gained.
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Homework Statement


this is an experiment from lab..
i have pendulum - mass (iron) hanging from a massless cord.
under the mass there is a magnet.
the movement of the pendulum is in a small angle.
i repeat the experiment 5 times - each time in a different distance between the iron mass and the magnet (the magnet is on a jack that can change its height).
the motion is recorded to the computer (multilab software)

the goal: to find from the time period (as recorded in the computer) the magnet's force as a function of the distance between the magnet and the iron mass

Homework Equations



T = 2\pi\sqrt{\frac{l}{g}}
this equation is for there is only mg present..
im not sure how to add the magnetic force..

The Attempt at a Solution


im really stuck..
ive made a force diagram with the magnetic force.. since its small angles i assumed the magnetic force is straight down (just like mg).. i also got rid of the sine \theta from the same reason..
im not sure how to use the distance between the magnet and iron mass as a variable..

any help is appreciated
thank you
 
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Hi StasKO! Welcome to PF! :smile:

T = 2\pi \sqrt{\frac{l}{a}}

Where a is the total effective acceleration downwards. So if you are in an elevator accelerating upwards with g', the effective acceleration would be (g+g') instead of g. Elevator going downwards would give (g-g'). Does this give you an idea?
 
StasKO said:

Homework Statement


this is an experiment from lab..
i have pendulum - mass (iron) hanging from a massless cord.
under the mass there is a magnet.
the movement of the pendulum is in a small angle.
i repeat the experiment 5 times - each time in a different distance between the iron mass and the magnet (the magnet is on a jack that can change its height).
the motion is recorded to the computer (multilab software)

the goal: to find from the time period (as recorded in the computer) the magnet's force as a function of the distance between the magnet and the iron mass

Homework Equations



T = 2\pi\sqrt{\frac{l}{g}}
this equation is for there is only mg present..
im not sure how to add the magnetic force..

The Attempt at a Solution


im really stuck..
ive made a force diagram with the magnetic force.. since its small angles i assumed the magnetic force is straight down (just like mg).. i also got rid of the sine \theta from the same reason..
im not sure how to use the distance between the magnet and iron mass as a variable..

any help is appreciated
thank you

Continuing what Infinitum said, to calculate the acceleration due to the magnet ONLY, think about the force exerted on the pendulum bob.
 
first of all thank you for your welcome.. this forums helped me a lot..

back to the issue..
so as i understand it, i need to replace the g in the equation to a general 'a' which represents the total acceleration downwards. this 'a' is the sum of g and the acceleration due to the magnet..
now i can find the acceleration only due to the magnet... and with Newton's 2nd law i can find the magnetic force:

Fmagnetic = miron × adue to magnet

now if this is correct, then how do i change this equation to be dependent on the distance between the magnet and the iron instead of the acceleration?
 
I believe you are given the magnetic strength/pole magnitude? If so, do you know the formula that gives you the magnetic force between the two(its an inverse square relation!)? From that force, calculate the acceleration and use time equation.
 
no.. i didnt receive any info about the magnet itself..
i know that i need (eventually) build a graph in excel.. from the slope of that graph i need to extract the magnetic force..
so if the graph equation is y=ax+b then y = T^2 and x should be the distance (something along this line).. a, which is the slope should give me the magnetic force..

the thing is that i need to find this connection between the period and the distance between the magnet and iron.. this is where I am stuck :(

edit: the only thing i know about the magnet its that it attracts the iron...
 
Hmm, I am not completely sure of this. But it does seem to be very interesting. Here's something you can try, for two different pendulum lengths,

T_1 = 2\pi \sqrt{\frac{l_1}{g+a_1}}

T_2 = 2\pi \sqrt{\frac{l_2}{g+a_2}}

Now taking ratio of T and sqrt(l) you get \sqrt{(g+a_2)/(g+a_1)} From here, get a relation between the magnetic forces.
 
well.. the thing is that the pendulum's length is not changing..
its the magnet that changes its position (only vertically).. the magnet is on a jack..

it might help to tell you that we had a similar experiment but with no magnet.. only pendulum.. so we measured the period T and length l... we repeated the experiment with different lengths l..
we squared the equation of period time to get a linear relationship between the period T and length l... we marked - y = T^2 and x=l... the coefficient a=(4*pi^2)/g..
we built the graph in excel and managed to extract the g to get its value from the slope which is 'a'...

now its the same procedure but with a magnet (and this time g is given)..
and now instead of finding g (through the relationship between period and length) i need to find the magnetic force (through the relationship between period and distance of magnet and iron mass)..

edit: i have the numbers for the different periods with respect to different distances of magnet and iron.. I am stuck at finding the connection between them lol
 
Ah, yes. Let the length of pendulum be the same in the above two equations, then. This means taking their ratios will give you

\frac{T_1}{T_2} = \sqrt{\frac{g+a_2}{g+a_1}}

Now, you know all the other values, hence you can find a relation between a1 and a2. Let these be done at different heights from magnet r1 and r2. From measurements say,

r_1 = kr_2
and from calculations,
a_1 = pa_2

For some constants k and p. So a distance of r1 gives acceleration a1, and a distance of (r1/k) gives an acceleration of (a1/p). Observe data's for yet more values of r and T. See what happens to the relations between force and distance and generalize it to obtain a conclusion.

PS : This is only an idea, which I think would work. I don't see why it shouldn't :rolleyes:
 
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  • #10
by 'm' you mean a coefficient and not mass right?

and instead the a's i can put (magnetic force)/(mass of iron) right?

i had a thought and not sure if its true..
is it possibe that instead of the length l of the pendulum i'll put the total length - pendulum + distance to magnet?
 
  • #11
StasKO said:
by 'm' you mean a coefficient and not mass right?

I edited the m thinking that it might cause confusion :wink: its p now, and yes, a coefficient.

and instead the a's i can put (magnetic force)/(mass of iron) right?

Yep!

i had a thought and not sure if its true..
is it possibe that instead of the length l of the pendulum i'll put the total length - pendulum + distance to magnet?

Nope, the total pendulum length still remains the length from the point of suspension to the center of mass of the bob.
 
  • #12
im still not sure i really understand your solution...
on what basis do you say that the ratio between two distances is equal to the ratio between two (corresponding) accelerations?
 
  • #13
StasKO said:
im still not sure i really understand your solution...
on what basis do you say that the ratio between two distances is equal to the ratio between two (corresponding) accelerations?

Why not? :confused:
 
  • #14
because it should be derived from some kind of equation i think..

can i say that the period T is proportional to the distance r so that T=kr for some constant k?

then find k by building a linear graph (y=T, x=r) and determining k from the slope of that graph..
then plug T=kr into the time period equation.. and solve for the magnetic force thus creating a function of the magnetic a force as a function of the distance r..

does this even makes sense?
 
  • #15
StasKO said:
because it should be derived from some kind of equation i think..

can i say that the period T is proportional to the distance r so that T=kr for some constant k?

then find k by building a linear graph (y=T, x=r) and determining k from the slope of that graph..
then plug T=kr into the time period equation.. and solve for the magnetic force thus creating a function of the magnetic a force as a function of the distance r..

does this even makes sense?

Actually, the acceleration ratio and distance ratio are equal. I know this example, isn't related in anyway to this problem, but just for intuition,

$$ \frac{s_1}{s_2}=\frac{\frac{1}{2}a_1t^2}{\frac{1}{2}a_2t^2}=\frac{a_1}{a_2} $$

Once again, the above example is NOT related to the problem, but it is just meant for intuition.
 
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  • #16
StasKO said:
because it should be derived from some kind of equation i think..

But my procedure is derived from an equation...

can i say that the period T is proportional to the distance r so that T=kr for some constant k?

then find k by building a linear graph (y=T, x=r) and determining k from the slope of that graph..
then plug T=kr into the time period equation.. and solve for the magnetic force thus creating a function of the magnetic a force as a function of the distance r..

does this even makes sense?

Hmm this would work, IF the time period was directly proportional to r. Try out experimenting a few times, and see if the relation is a linear one.

on what basis do you say that the ratio between two distances is equal to the ratio between two (corresponding) accelerations?

Didn't say that. I derived

\frac{T_1}{T_2} = \sqrt{\frac{g+a_2}{g+a_1}}

from which, I found the relation between the two distances by measurement.

r_1 = kr_2

and the relation between accelerations was derived from the time period equation. By multiple observations, you can find the relation between r and a.
 
  • #17
ohh ok... now i got it lol

anyways i think now i have enough info and tools to solve this experiment.. now I am going to sit on my as* and finish this...

thank you so much for the brain storming.. it is much appreciated (be ware i might be back for more questions lol)
 
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