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The elusive chord


bonanova
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This took me to find Bertrand's paradox. Looks like my answer covers method 2. WIll try to calculate method 1 and 3. What's the fourth?

He left out from his three what I thought was the most intuitive way to make a chord

Two points are located randomly and independently in the interior of the circle. An extended straight-line connection of the two random points determines a random chord.

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He left out from his three what I thought was the most intuitive way to make a chord

Two points are located randomly and independently in the interior of the circle. An extended straight-line connection of the two random points determines a random chord.

My problem with the method of randomly choosing two points is that it seems to me to result in an estimate of the length squared.

Here's my argument. Choose two points in the interior, B and C. Extend to form the chord intersecting the circle at A and D. Now we have a length: the distance from A to D.

Notice, no matter what two points we could have chosen between A and D, we would arrive at the very same chord. So our overall average is going to be weighted by the probability of getting two points on chord AZ.

But, if we had chosen two points L and M resulting in a much shorter chord KN, it would have been weighted by the (smaller) probability of getting two points on chord KN.

So our overall average would incorporate the length of the chord twice, once for the length of the chord, and once for the probability of picking out that particular chord.

I would think that a "randomly chosen chord" would uniformly choose between chords, with each different chord having the same weight. Unfortunately, I can imagine (before looking at Bertrand's paradox) at least two ways to choose a chord randomly, and I still see differential weighting.

Both my suggested methods involving designating one point P on the circumference of the circle. After all, we know we want something that touches the circumference. It doesn't matter where, because it's a circle. Let's just start with one point. Now:

(method 1) uniformly choose an angle between 0 and 180, measured from a tangent to P. Compute the length of the chord, average over all angles.

(method 2) uniformly choose a point Q from the circumference of the circle. Compute the length of the chord, average over all points Q.

I assume they give different results. Sorry...:-(

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My problem with the method of randomly choosing two points is that it seems to me to result in an estimate of the length squared.

Here's my argument. Choose two points in the interior, B and C. Extend to form the chord intersecting the circle at A and D. Now we have a length: the distance from A to D.

Notice, no matter what two points we could have chosen between A and D, we would arrive at the very same chord. So our overall average is going to be weighted by the probability of getting two points on chord AZ.

But, if we had chosen two points L and M resulting in a much shorter chord KN, it would have been weighted by the (smaller) probability of getting two points on chord KN.

So our overall average would incorporate the length of the chord twice, once for the length of the chord, and once for the probability of picking out that particular chord.

I would think that a "randomly chosen chord" would uniformly choose between chords, with each different chord having the same weight. Unfortunately, I can imagine (before looking at Bertrand's paradox) at least two ways to choose a chord randomly, and I still see differential weighting.

Both my suggested methods involving designating one point P on the circumference of the circle. After all, we know we want something that touches the circumference. It doesn't matter where, because it's a circle. Let's just start with one point. Now:

(method 1) uniformly choose an angle between 0 and 180, measured from a tangent to P. Compute the length of the chord, average over all angles.

(method 2) uniformly choose a point Q from the circumference of the circle. Compute the length of the chord, average over all points Q.

I assume they give different results. Sorry...:-(

I was just pointing out that Bertrand left out that method for choosing a chord. However,

Pick a random point inside the circle and spin a random angle relative to the radius and pivoting on the point creating a chord.

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Indeed, more than one way.

Bonanova, what is the goal of this puzzle?

a) show us that the notion of "randomly chosen" depends on how you define it?

b) have us show lots of ingenuity in defining truly different ways to define it?

c) elicit from us the really-really-best way to define it?

d) all of the above

e) none of the above

f) other

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I was just pointing out that Bertrand left out that method for choosing a chord. However,

Pick a random point inside the circle and spin a random angle relative to the radius and pivoting on the point creating a chord.

I agree with CaptainEd. Jaynes' solution to the Bertrand paradox shows that random radius (method 2) is the only robust theoretical means of choosing random chord.

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I agree with CaptainEd. Jaynes' solution to the Bertrand paradox shows that random radius (method 2) is the only robust theoretical means of choosing random chord.

So, then it is more random. :huh: I looked up Jaynes' proposal and it based on the fact that the size of the circle is unknown, here the OP has given us a size. Is throwing straws at a circle a better method than selecting a number at random between 0 and πr2 , letting that number represent an area and drawing a chord to section off that area?

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Indeed, more than one way.

Bonanova, what is the goal of this puzzle?

a) show us that the notion of "randomly chosen" depends on how you define it?

b) have us show lots of ingenuity in defining truly different ways to define it?

c) elicit from us the really-really-best way to define it?

d) all of the above

e) none of the above

f) other

All of the above, probably.

Let's make it a competition to show the greatest and least among any reasonable definition of randomness.

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Well the longest chord possible is the diameter, and the shortest possible is a tangent (0 length). On average, you will get something between the two so the average is half the diameter, AKA, the radius!

This is an interesting approach. The radius is a middle measure of the extremes of zero and the diameter, but It is the median, not the mean. One must represent (find an expression for) all the uncountably infinite chords and then examine the distribution of their lengths. If the distribution were found to be uniform from 0 to 2r then r would be correct. All the examples given previously in this thread, however, show the lengths not to be uniformly distributed.

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My above solution assumes that you define random in a way that makes all chord lengths equally likely.

(I hate the edit system on this site)

I'm not sure you can define random in any sense other than an unbiased selection from all available instances. The challenge that arises is that several exhaustive, random [in some sense] and uncountable subsets each yield a distinct value of average length.

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After doing some research and none of the math, I've found

The shortest mean chord length was 1.00 and the longest 1.81 depending on the method used to make a random chord.

Inscribe a regular polygon of n sides where n > 1.

Take the chord to be one side of the polygon; (n = 2 gives a diameter.)

Let n be chosen at random.

What is that average chord length?

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Inscribe a regular polygon of n sides where n > 1.

Take the chord to be one side of the polygon; (n = 2 gives a diameter.)

Let n be chosen at random.

What is that average chord length?

Quite small. The larger n is the smaller the chord length. I would argue that this is not an acceptable way to chose "random chords", however.

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