You can see it is R/r local revolutions of the small circle. Then you need to add one global revolution from going around the large circle. So R/r + 1.
This is of course what the article is saying pretty much.
Are there other situations that require a similar reasoning?
> You can see it is R/r local revolutions of the small circle. Then you need to add one global revolution from going around the large circle. So R/r + 1.
I understand the article, but I don't I think I quite get or buy your explanation.
I'm curious about your linguistic separation of "local" and "global". What is local and what is global in this situation? I wonder if you are the frame of reference concept? Could you unpack what you mean?
I don't think the terms quite fit. You did when you wrote it; do you still? By this I mean: do you think the way you're using the terms local and global would be intuitive to, say, an audience with a high-school level background in geometry? This is an empirical question, but my inclination would be to say 'probably not'.
I find the article's emphasis on decomposing sliding (i.e. translation) from rotating to be much more intuitive. (Of course people will vary.)
Still, I'm curious. I'm searching for a sense in which this linguistic global/local distinction adds explanatory power. Care to elaborate?
Yes, the missing phrase from the article was clearly "frame of reference". Ie the coin makes 4 rotations if we stretch the larger circle out into a straight line, which we do implicitly when doing our mathematical calculation, but we should be aware that this frame of reference is also making a full rotation.
Yes I’m thinking in terms of different frames of reference.
Imagine that you’re a tiny ant that lives on the large circle. When you push the small circle around the large circle you will see it make four rotations before you get back to the starting point. This is the local frame of reference.
Now imagine you’re a giant living in the space with the circles. You see the small circle do five full rotations. Four are the same that the ant sees but you also see the ant itself do one rotation simultaneously as it walks along the large circle making five in total.
It would be more accurate to say that you have 4 local rotations and that the local frame rotates one full turn in the global frame.
Does this make sense to someone with a high-school level of geometry knowledge? Not as I wrote it I initially (but there was no such goal). The analogy with the giant and the ant together with some nice illustrations maybe?
Here's another way of putting it, without explicitly mentioning frames of reference:
Before starting, imagine drawing a radius on the moving coin from its center to its point of contact with the stationary coin. It is pointing down.
As the moving coin goes clockwise around the fixed coin, this radius will also rotate clockwise around the center of the moving coin.
The next time the end of the radius is in contact with the fixed coin is after the moving coin has gone 1/4 of the way around the fixed one - but now the radius is pointing to the left. It has passed the point where it is pointing down again (which is when the moving coin has made one full revolution) and gone a 1/4 turn beyond that.
> Each of the above explanations describes the circle's movement as a decomposition into rotation and revolution, but in reality no such decomposition is taking place.
Comments:
1. This is a specific instance of a widely taught principle from Buddhism: “Concepts are not real things; a conceptualized world is a dead world. Living actualities lose their life when put into concepts.” ― Gyomay M. Kubose, Everyday Suchness: Buddhist Essays on Everyday Living
2. For a broader audience, I'd probably rephrase the above as: "Concepts are human representations; they are different than the actual phenomena."
3. The above decomposition is represented in many of our brains. In that sense it is "real" as any other form of physical matter. Why? The concept is (somehow) encoded in the structure and relationships of neurons (as I understand it).
4. I'm torn: saying that "decomposition" isn't "taking place" is simultaneously insightful and obvious. In any case, as phrased, for a modern audience, it risks missing the point; namely, a decomposition is a useful way of understanding the world. For example, the idea of decomposing motion into {rotation and translation} is similar to decomposing the position of a point by referring to its {position in a coordinate system}, whether it be Cartesian, polar, barycentric, or otherwise. Doing so helps us bring analytic methods to bear.
You're reading too much into it. "Reality" here is used as a metaphor to aid in learning. Given equivalent mathematical descriptions of something, they are all just as true, or just as false. None of them is more "real". The metaphor uses that word, but it doesn't make them unequal in any other way than comprehension by humans.
As humans, especially in mathematics, concepts are all we have. Dig deep enough, and you'll hit the wall of the unknown rather than the real. What is an electron, really? Is this question even answerable, or is it more refined concepts all the way down? Can you even perceive anything real, raw, without interpreting it into a high level concept like a color or a neuron firing (Kant comes to mind).
The decomposition is taking place. The decomposition isn't taking place. It's all the same.
What do you mean by this? I'm getting it wrong? I'm mistaking the author's meaning? (How do you know what the author's meaning is?) I shouldn't reflect on this? Something else?
> Given equivalent mathematical descriptions of something, they are all just as true, or just as false.
I don't mean to discount this statement, but it is a tautology.
> ... it doesn't make them unequal in any other way than comprehension by humans.
Spot on.
> As humans, especially in mathematics, concepts are all we have. Dig deep enough, and you'll hit the wall of the unknown rather than the real. What is an electron, really? Is this question even answerable, or is it more refined concepts all the way down? Can you even perceive anything real, raw, without interpreting it into a high level concept like a color or a neuron firing (Kant comes to mind).
Your comments and questions are temporally relevant to my recent experience; I'm listening to a podcast discussion between Tim Mauldin and Sam Harris: "#318, Physics & Philosophy, A Conversation with Tim Maudlin", "the author of books on the foundations of physics, logic, and foundations of mathematics. His books include Quantum Non-Locality and Relativity, Truth and Paradox, The Metaphysics Within Physics, Philosophy of Physics: Space and Time, and Philosophy of Physics: Quantum Theory." My background includes engineering and philosophy, and I plan on reading more of Mauldin's work.
To your credit, your paragraph above is in some ways a better summary of the concepts in play than the podcast above. [1] This particular interview shows Harris not at his best, but Mauldin shines.
That said, I'm puzzled by your sentence "Dig deep enough, and you'll hit the wall of the unknown rather than the real."
I claim that reality is still there, whether or not we see it or understand it. This is known as epistemological realism. Do you hold this view?
I agree that humans have the feeling of unknown as we do deeper "down the stack"; e.g. from molecules to atoms to quarks and so on. So why do we go deeper? Where do we stop? Scientists seek models for explanation and prediction. Philosophers seek truth. At some point, we stop. Why? Likely because (1) we run of technical ability; and/or (2) going further involves adding more words and concepts without aiding our 'project', whether it be models or truth.
I agree ([2]) with your rhetorical question "What is an electron, really?". An electron is either a composite of deeper things -- or we stop and say "it exists".
[1] Generally speaking, I've gained a lot of insight from Harris, his guests, and the ideas he highlights. ¶ I don't care much for caricatured or uncharitable characterizations of Harris (or anyone). These 'controversies' to me seem to be more of a sign of attention-seeking, brand-building, and tribe-definition than truth-seeking.
"Reading too much" means that the article is not using "reality" in the philosophical sense, and while it's not "wrong" to think about it, it's also orthogonal to the apparent purpose of the article, which is teaching.
I'm not saying whether the reality exists or not. I'm saying that you are not able to learn (about) it without wrapping it in concepts. I doubt there's any such thing as naked, concept-less reality. You can always dig deeper, but if you try, you'll either find more concepts, or the naked unknown, but not the naked real.
Saying "it exists" is different, but does not free us of concepts. It is accepting that all we have is this concept, and that there's nothing more real than this concept.
This, by the way, is why there is a thing called "sidereal time", with days that are slightly shorter than 24h.
The commonly used 24h days are solar days, defined relative to the sun, but since the earth goes around the sun too, that makes an extra rotation relative to the star background, which means a year has 366.25 sidereal days instead of the usual 365.25.
It's funny, I usually only think about circles this way when trying to construct mutually tangent circular arcs, because if you have one circle inside (or outside) the other, their arcs are tangent at the point where they touch.
I used circles a lot when doing CADs because they let you measure all the points a certain distance away from a given point, so intersecting two of them lets you do a lot of construction, like finding the two possibilities for the center of a circular arc that passes through two points of a given radius, assuming that they're not too far apart for that to exist.
Satellites in sun-synchronous orbits need to precess (their orbital plane must slowly rotate) because of this situation to actually stay sun-synchronous.
the 24-hour day is a construct of mean solar time. Because the speed of the Earth varies through the year (fastest at perihelion - see Kepler I and II), the apparent or true solar day varies in duration throughout the year.
> I figured the answer must be four revolutions. So imagine my surprise when I saw that the answer was given to be five!
The answer is four from the reference frame of the small moving circle (the fifth rotation belongs now to the big circle). Imagine two circles fixed and both rotating together, like connected gears. The question is fun but only surprising because it’s ambiguous and assuming a specific reference frame without saying it (which would be a clue to what’s really being asked.)
22 comments
[ 3.2 ms ] story [ 55.3 ms ] threadYou can see it is R/r local revolutions of the small circle. Then you need to add one global revolution from going around the large circle. So R/r + 1.
This is of course what the article is saying pretty much.
Are there other situations that require a similar reasoning?
I understand the article, but I don't I think I quite get or buy your explanation.
I'm curious about your linguistic separation of "local" and "global". What is local and what is global in this situation? I wonder if you are the frame of reference concept? Could you unpack what you mean?
I don't think the terms quite fit. You did when you wrote it; do you still? By this I mean: do you think the way you're using the terms local and global would be intuitive to, say, an audience with a high-school level background in geometry? This is an empirical question, but my inclination would be to say 'probably not'.
I find the article's emphasis on decomposing sliding (i.e. translation) from rotating to be much more intuitive. (Of course people will vary.)
Still, I'm curious. I'm searching for a sense in which this linguistic global/local distinction adds explanatory power. Care to elaborate?
Imagine that you’re a tiny ant that lives on the large circle. When you push the small circle around the large circle you will see it make four rotations before you get back to the starting point. This is the local frame of reference.
Now imagine you’re a giant living in the space with the circles. You see the small circle do five full rotations. Four are the same that the ant sees but you also see the ant itself do one rotation simultaneously as it walks along the large circle making five in total.
It would be more accurate to say that you have 4 local rotations and that the local frame rotates one full turn in the global frame.
Does this make sense to someone with a high-school level of geometry knowledge? Not as I wrote it I initially (but there was no such goal). The analogy with the giant and the ant together with some nice illustrations maybe?
Before starting, imagine drawing a radius on the moving coin from its center to its point of contact with the stationary coin. It is pointing down.
As the moving coin goes clockwise around the fixed coin, this radius will also rotate clockwise around the center of the moving coin.
The next time the end of the radius is in contact with the fixed coin is after the moving coin has gone 1/4 of the way around the fixed one - but now the radius is pointing to the left. It has passed the point where it is pointing down again (which is when the moving coin has made one full revolution) and gone a 1/4 turn beyond that.
Repeat until you are back at the top again.
Comments:
1. This is a specific instance of a widely taught principle from Buddhism: “Concepts are not real things; a conceptualized world is a dead world. Living actualities lose their life when put into concepts.” ― Gyomay M. Kubose, Everyday Suchness: Buddhist Essays on Everyday Living
2. For a broader audience, I'd probably rephrase the above as: "Concepts are human representations; they are different than the actual phenomena."
3. The above decomposition is represented in many of our brains. In that sense it is "real" as any other form of physical matter. Why? The concept is (somehow) encoded in the structure and relationships of neurons (as I understand it).
4. I'm torn: saying that "decomposition" isn't "taking place" is simultaneously insightful and obvious. In any case, as phrased, for a modern audience, it risks missing the point; namely, a decomposition is a useful way of understanding the world. For example, the idea of decomposing motion into {rotation and translation} is similar to decomposing the position of a point by referring to its {position in a coordinate system}, whether it be Cartesian, polar, barycentric, or otherwise. Doing so helps us bring analytic methods to bear.
As humans, especially in mathematics, concepts are all we have. Dig deep enough, and you'll hit the wall of the unknown rather than the real. What is an electron, really? Is this question even answerable, or is it more refined concepts all the way down? Can you even perceive anything real, raw, without interpreting it into a high level concept like a color or a neuron firing (Kant comes to mind).
The decomposition is taking place. The decomposition isn't taking place. It's all the same.
What do you mean by this? I'm getting it wrong? I'm mistaking the author's meaning? (How do you know what the author's meaning is?) I shouldn't reflect on this? Something else?
I don't mean to discount this statement, but it is a tautology.
> ... it doesn't make them unequal in any other way than comprehension by humans.
Spot on.
> As humans, especially in mathematics, concepts are all we have. Dig deep enough, and you'll hit the wall of the unknown rather than the real. What is an electron, really? Is this question even answerable, or is it more refined concepts all the way down? Can you even perceive anything real, raw, without interpreting it into a high level concept like a color or a neuron firing (Kant comes to mind).
Your comments and questions are temporally relevant to my recent experience; I'm listening to a podcast discussion between Tim Mauldin and Sam Harris: "#318, Physics & Philosophy, A Conversation with Tim Maudlin", "the author of books on the foundations of physics, logic, and foundations of mathematics. His books include Quantum Non-Locality and Relativity, Truth and Paradox, The Metaphysics Within Physics, Philosophy of Physics: Space and Time, and Philosophy of Physics: Quantum Theory." My background includes engineering and philosophy, and I plan on reading more of Mauldin's work.
To your credit, your paragraph above is in some ways a better summary of the concepts in play than the podcast above. [1] This particular interview shows Harris not at his best, but Mauldin shines.
That said, I'm puzzled by your sentence "Dig deep enough, and you'll hit the wall of the unknown rather than the real."
I claim that reality is still there, whether or not we see it or understand it. This is known as epistemological realism. Do you hold this view?
I agree that humans have the feeling of unknown as we do deeper "down the stack"; e.g. from molecules to atoms to quarks and so on. So why do we go deeper? Where do we stop? Scientists seek models for explanation and prediction. Philosophers seek truth. At some point, we stop. Why? Likely because (1) we run of technical ability; and/or (2) going further involves adding more words and concepts without aiding our 'project', whether it be models or truth.
I agree ([2]) with your rhetorical question "What is an electron, really?". An electron is either a composite of deeper things -- or we stop and say "it exists".
[1] Generally speaking, I've gained a lot of insight from Harris, his guests, and the ideas he highlights. ¶ I don't care much for caricatured or uncharitable characterizations of Harris (or anyone). These 'controversies' to me seem to be more of a sign of attention-seeking, brand-building, and tribe-definition than truth-seeking.
[2] Can one agree with a rhetorical question?
I'm not saying whether the reality exists or not. I'm saying that you are not able to learn (about) it without wrapping it in concepts. I doubt there's any such thing as naked, concept-less reality. You can always dig deeper, but if you try, you'll either find more concepts, or the naked unknown, but not the naked real.
Saying "it exists" is different, but does not free us of concepts. It is accepting that all we have is this concept, and that there's nothing more real than this concept.
The commonly used 24h days are solar days, defined relative to the sun, but since the earth goes around the sun too, that makes an extra rotation relative to the star background, which means a year has 366.25 sidereal days instead of the usual 365.25.
I guess I'm one of today's lucky 10,000!
https://xkcd.com/1053/
I used circles a lot when doing CADs because they let you measure all the points a certain distance away from a given point, so intersecting two of them lets you do a lot of construction, like finding the two possibilities for the center of a circular arc that passes through two points of a given radius, assuming that they're not too far apart for that to exist.
https://en.wikipedia.org/wiki/Sun-synchronous_orbit
https://en.wikipedia.org/wiki/Solar_time
This is one of the causes of the analemma.
https://en.wikipedia.org/wiki/Analemma
The answer is four from the reference frame of the small moving circle (the fifth rotation belongs now to the big circle). Imagine two circles fixed and both rotating together, like connected gears. The question is fun but only surprising because it’s ambiguous and assuming a specific reference frame without saying it (which would be a clue to what’s really being asked.)
[0] https://math.stackexchange.com/questions/1351058/circle-revo...