Talk:Golden ratio: Difference between revisions

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	== ~~Mecca~~ ~~& co~~ ==		== Short description ==

	That religious stuff is nonsensical enough and was removed in the past already. If anyone insist on including this under dipsuted claims, then to the very least you need to provide proper citations (no citation needed stuff). Furthermore a consent on the discussion page is needed as well.--] (]) 23:55, 28 October 2011 (UTC)
	:I agree. —] (]) 00:07, 29 October 2011 (UTC)

	:I don't understand how these facts are nonsensical? Objectively, the values, actually, are very close to the golden ratio. Yes, they are coincidental, but isn't that exactly what adds to the aura of the golden ratio? About the citation, I am not sure whether the source that I have is applicable: It's not a journal, just an amateur website that has some calculations on it regarding this Mecca entry(which I have verified). The problem I found with the source, and the reason I hadn't posted it, is that it includes other claims that are, in fact, nonsensical: it claims that the Mecca is also longitudinally situated on the golden ratio (from east to west), which is completely arbitrary. The citation in question is: http://www.scribd.com/doc/9436715/THE-WORLDS-GOLDEN-RATIO-POINT

	:This is the entry in question:
	:In geography, the ] position of the Islamic holy city of ](Mecca) at N 21'42 corresponds closely to the golden ratio. That is the ratio of the latitudinal distance from the North Pole to the city to the latitudinal distance from the South Pole to the city equals 1/φ. In fact, any city situated near the N 21'42 line would have that same characteristic. {{Citation needed\|date=October 2011}} In religious literature, the city of Makkah once again presents itself in a position of the golden ratio. In the ](Quran), the ] holy book, the word Makkah or Bakkah, referring to the city of Makkah, appears only twice. The word first appears in ] 3: verse 96, and it does so in a golden ratio position. There are 29 letters in the verse upto, and including, the word Bakkah; whereas the entire verse consists of 47 letters. This fraction, 29/47, is appoximately 1/φ. {{Citation needed\|date=October 2011}}
	:] (]) 09:00, 29 October 2011 (UTC)
	::This article is based on ] discussing serious topics in mathematics and the arts. It is not the place to record every calculation that fringe groups may have performed. While it is mildly interesting to see how inventive minds can devise calculations to obtain some desired result, this is not the article to record such results, particularly without reliable sources. ] (]) 09:25, 29 October 2011 (UTC)

	::I am asking for this entry to be placed in the Disputed Observations section. I think this entry adds to the aura of the golden ratio. It is an instance of the golden ratio appearing coincidentally, once again, in human history. Whether this is purely coincidence or not is up for debate or further research, which is why it is 'disputed'. For me, given the significance of Mecca in human history, this entry deserves a place in this article. ] (]) 09:34, 29 October 2011 (UTC)
	:::Even disputed claims require reliable & reputable sources. If at all such a section is allowed at all it is to list ''well known'' claims published in reputable sources on which the academic community however does not agree. It is not meant as discussion forum or for including arbitrary fringe claims.--] (]) 10:53, 29 October 2011 (UTC)
	::: I can only find self-published, questionable(amateur) sources for this, although, the content seems easily verifiable. I hope we can leave this discussion up for others to see. It will save repetition of discourse. ] (]) 17:16, 29 October 2011 (UTC)
	::::That's why it doesn't belong into in the article. Numerical verification is not the issue here rather notability.--] (]) 18:49, 29 October 2011 (UTC)
	::::I understand and agree. An entry's potential to generate interest in a topic does not compensate for a lack of notability. ] (]) 22:24, 29 October 2011 (UTC)

	(indent pushed <---- thataways, sorry). For the proponents of the measurements of such cities: This is stepping away from mathematics and toward ]. Given any number, you can look and find items that closely resemble it. If not a city, then a mountain range. If not that, then the trees. There is no point whatsoever in visiting each of these. IF A NEW ARTICLE ENTITLED (words to the effect of) "Matching items to the golden ratio", then '''perhaps'''. ] (]) 21:30, 7 February 2012 (UTC)

	== A number of problems ==

	The assertion that "many artists and architects have proportioned their works to approximate the golden ratio" is misleading. If you search for actual examples, you will find that very few have. Try finding a major painting, for example, with a frame ratio of 1:1.612

	There is no evidence supporting the use of the golden ratio in the Parthenon, or Pyramids of Giza.

	Leonardo da Vinci's "Vitruvian Man" is not based on the golden ratio. It is based on a circle and a square, ratios of 1:1 not 1:1.612

	The Illustration from Luca Pacioli's De Divina Proportione does not have anything to do with the golden mean.

	You will find few postcards, playing cards, or posters with ratios of 1:1.612 as claimed by the article.

	Wide-screen televisions (16:9) have a ratio of 1:1.77 not 1:1.612

	<span style="font-size: smaller;" class="autosigned">— Preceding ] comment added by ] (]) 20:27, 28 November 2011 (UTC)</span><!-- Template:Unsigned IP --> <!--Autosigned by SineBot-->
	:Thanks, that's another nice ''Devlin's Angle'' article. <small>Please click "new section" to add a comment on a new topic to a talk page. That puts it at the bottom.</small> ] (]) 22:55, 28 November 2011 (UTC)

	8"×10" and quarter-sized 4"×5" are popular formats in photography, and it would seem logical that the half-format 8"×5" would be ''particularly'' popular — conveniently derived from the others, and a decent approximation of the golden ratio. But, instead, 5"×7" became a standard size. In , an author even writes: ''"I would recommend the 6½×8½ in preference to the 5×8, since for most work the latter is not so well proportioned."'' ] (]) 17:36, 19 December 2011 (UTC)

	== new link ==

	In spite of the warning in the external links section I went ahead and added

	*Schneider, Robert P.

	to it. I had just recently added it to the article on ], and thought it belonged here as well.

	] (]) 17:34, 16 December 2011 (UTC)

	== negative reference for golden ratio ==

	In researching photographic formats, I came across . The article mentions that a certain in-vogue format is too narrow to meet "the best proportion, according to the golden mean", continuing "Unfortunately, but little attention has been given to the beauty standard, just as is the case in the cutting of our garments, and in the same way as it is impossible to argue down a new fashioned garment, no matter how foolish and ridiculous it may be, so we should be powerless to rob a picture of its popularity."

	This makes the somewhat funny argument that while the golden mean provides the most beautiful portion, popular opinion seem to ''foolishly'' prefer others instead. And this continues with the relevant quote: "We may console ourselves with the thought that painters, on their part, trouble themselves very little about the golden mean."

	The author, H. Vogel, ]. And his nationality (German) and the timing fit with the spread of the golden-ratio-as-beautiful meme. ] (]) 17:23, 19 December 2011 (UTC)

	:Good find! ] (]) 17:47, 19 December 2011 (UTC)

	== Blogs ==

	Per ] and ] - ''Blogs'' especially this one, are not ]. -- ]<font color="#964B00">☆</font>] <sup> ]</sup> 07:24, 20 December 2011 (UTC)
	:Also, regardless if the blog is reliable or not, common practise is actually discuss with an editor on the talk page, rather ], and the possibility of violating ]. Thank you, -- ]<font color="#964B00">☆</font>] <sup> ]</sup> 07:29, 20 December 2011 (UTC)

	"Per ] and ] - ''Blogs'' especially this one" I think you are discriminating Google Blog Service which I find excellent (or which do you find "honorable"), plus, none of your references is mentioned this blog or blogs in general are not ]. And I remind you that ] also applies to everyone, YOU included. Also, you should have started the talk request clarification before undoing it to explain in detail your IMO invalid reasons. Is there another instance or arbiter that can decide this besides you?
	:Don't know what ] you are trying to prove, but an editor specifically told you they have issue with this blog being unreliable. I didn't warn you about the 3RR - another ] user did - and you haven't broken 3RR anyway - that warning is to tell you, that you're a close to it. Don't tell me what I should and shouldn't have done, I did my job. Also, everyone's IMO is valid. Not just yours. -- ]<font color="#964B00">☆</font>] <sup> ]</sup> 08:00, 20 December 2011 (UTC)

	== the arcticle's writer ==

	who is the writer of this arcticle, im doing a work on the golden ratio in the pyramids so please help. <span style="font-size: smaller;" class="autosigned">— Preceding ] comment added by ] (]) 11:58, 9 February 2012 (UTC)</span><!-- Template:Unsigned IP --> <!--Autosigned by SineBot-->

	== Amen break ==

	From ], "Self-published material may be acceptable when produced by an established expert on the topic of the article whose work in the relevant field has previously been published by reliable third-party publications." That seems to fit the situation to a tee. He has a masters in Mathematics Education, and his book "A Beginner's Guide To Constructing The Universe: The Mathematical Archetypes Of Nature, Art and Science" has been published by a non-vanity press (HarperPerennial). Further, we are giving it as his POV, as with some of the other examples (e.g. Roy Howat). ] - ] 07:27, 14 February 2012 (UTC)
	:This concerns an edit ({{diff\|Golden ratio\|prev\|476764222\|diff}}) which added text "{{xt\|The mathematician Michael Schneider analysed the waveform of the ] and found that the peaks are spaced at intervals in the golden ratio.}}"
	:The problem is that people have found the golden ratio in all sorts of things: looking hard enough often locates a pattern. The author's writings suggest a specialty in finding mathematical relationships, which is not what is needed in this article. Has the author analyzed other popular tunes looking for the golden ratio? If a significant proportion of such tunes fits a predefined pattern, a suitably qualified person might conclude something significant had been observed. Otherwise, it's just like noticing the decimal digits of the golden ratio in a car number plate. ] (]) 07:55, 14 February 2012 (UTC)
	:: In an article for which we can find tens of thousands of actually-reliably-published sources, and on a subject on which many people have written and published many ridiculous things, I tend to think we should use stricter standards than Also, is a drum solo from the 1960's really central enough to the subject of this article to devote a whole paragraph to it? And finally, is it much of a surprise that you can take a sequence of 13 beats, break it up into 8 and 5, and find the golden ratio? It just looks like more numerology of a type we have too much of here already, to me. —] (]) 08:08, 14 February 2012 (UTC)
	:::I agree. This is a topic with many dubious claims, but a wealth of (highly) reliable/reputable sources available, so we should stick to the latter and avoid any content that is somewhat dubious or of less or unclear notability to begin with.--] (]) 10:12, 14 February 2012 (UTC)
	::I think we should try to base our discussion on actual policy. You haven't directly addressed ]. David Eppstein, it isn't a question of a master's degree "IN SCIENCE!". It's a master's in Mathematics Education, which seems relevant to the topic at hand. I don't think the fact that it's from the 1960's makes it less relevant. It's been used in many notable songs since then, and there's no time limit on notability; that's why we have an article on it. Johnuniq, I would be more concerned if the author found spurious golden ratios in every populuar song. It seems relevant that it's specifically this break. Quite unlike a car number plate, there is no suggestion that the Amen break was generated randomly or automatically.

	::Finally, the point of the mention is not to say definitely that the song uses the golden ratio. It is to relay his POV that it does. If we have to tweak the wording, that's fine. ] - ] 04:01, 20 February 2012 (UTC)
	:::If you want argue from the point of WP:RS is kinda simple, as there are enough "high quality" source on subject hence there is no need to relax the criteria on sources. So if it is ''not'' published in a reputable (academic) journal, a book from a reputable academic publisher and/or by an particularly reputable academic/scholar then it stays ''out'' as in that case it is neither reliable nor notable enough for inclusion.--] (]) 04:23, 20 February 2012 (UTC)
	::I'm certainly not arguing that Amen Break is a bad subject for an encyclopedia article. It might even be reasonable to mention its mathematical analysis within the Amen Break article itself. I just don't think it is sufficiently important to the topic of the Golden ratio to mention it in this article, and that the quality of sourcing (relative to the total volume and quality of sources for topics related to the golden ratio) is low. —] (]) 05:45, 20 February 2012 (UTC)
	::I agree with David Eppstein. If this isn't important enough to mention in the ] article, why is it important enough to mention here? —] (]) 17:24, 20 February 2012 (UTC)

	== Reversion of edit without adequate explanation ==

	I made an edit which made several improvements to this article. The edit was reverted with an enigmatic edit summary of "An edit that removes the numeric value from the lede is unacceptable," I'm putting the improvements back in. If anyone would like to make additional improvements, please feel free to do so, but don't simply revert a major, good-faith edit containing several changes without discussing it here first. (If that edit summary comment was about moving the equations from the introduction, please read WP:MOSINTRO before making any further edits.) <b>] (]•])</b> 05:01, 2 March 2012 (UTC)
	:You are seriously mischaracterizing my edit summary, which invited you to discuss this here per ] rather than as you say didn't discuss it. And, ] is not about redoing your edits until the other editors give up in frustration: it's about actually discussing it before trying it again, which you haven't done. As for MOSINTRO: it says not to have unnecessary formulas in the intro, a very different thing than having no formulas at all. In a math article such as this one, some amount of math may be necessary to satisfy the other requirements of the MOS, that the lead section actually summarize the article and provide a concise description of the subject. In this particular case, it is absolutely essential that the approximate numeric value 1.618 be included in the lead, and that's not possible without a little bit of math to explain how that value relates to the English-language description. —] (]) 05:12, 2 March 2012 (UTC)
	:PS I just realized that until about a month ago what MOSINTRO actually said was "Mathematical equations and formulas should not be used except in mathematics articles." So you are edit-warring based on a change to MOSINTRO that has barely had time to have the ink dry and that has never been discussed with ]. And if you go back to that is leading to this interpretation, and read the edit summary, you will see that the intent of the change was not to restrict the use of mathematical formulas in mathematics articles, but rather to broaden their use to allow formulas in other technical article leads. So your edit seems to be based on mistaken premises to me. —] (]) 05:19, 2 March 2012 (UTC)
	::Thank you taking the time to discuss this here. The edit made several improvements to the article, including improvements to the layout, and several others plus the moving of the equations. I was concerned that all of the changes were reverted (not just the equation-moving part). If the equations are the only concern, then please put back the other improvements and then we can discuss the equation issue in the following section. <b>] (]•])</b> 05:41, 2 March 2012 (UTC)
	:::I'd rather you broke down your changes into smaller chunks and tried them again separately. The removal of all the mathematics from the lead was what I primarily objected to, but in part that was because you made a lot of changes and it was difficult to tell what the effect of them was all at once. —] (]) 05:55, 2 March 2012 (UTC)
	::::Okay, I did the edits separately, except for moving the equations which I'll hold off on until we work it out. <b>] (]•])</b> 06:58, 2 March 2012 (UTC)
	:::::I don't believe the changes were improvements. -- ] (]) 11:52, 2 March 2012 (UTC)
	:::I think I would agree that there are too many illustrations in the lead, and I'd move the "construction" to a golden rectangle section below. But leave the basic rectangle division, which is such an important part of the concept. ] (]) 16:24, 2 March 2012 (UTC)

	== Equations in intro ==

	I feel the article would be improved by moving the equations from the intro. If this were only a mathematics article, then the equations would be appropriate in the introduction, however, this article covers a broad number of disciplines, including the arts, music, nature and many others. Readers will be coming to this article from many differing areas and with a variety of levels of understanding of mathematics. If there was no other way to introduce the subject and explain what the ratio is, then the equations would be needed, however, the prose, along with the graphical representation to the right of the intro adequately explain the ratio. Plus, the equations are revealed in the very next section of the article. <b>] (]•])</b> 05:41, 2 March 2012 (UTC)
	:Sparkie82, be aware that this article has a long history of attention and compromise by lots of good editors. If you have an "improvement" you want to make, make your case here. We have no problem assuming your edit was in good faith, but perhaps more of a problem believing that removing the symbol, value, and defining relationship from the lede is an "improvement". As for the rest of your edit that was reverted, you can try less controversial parts again; it will be best to make changes in smaller chunks that can be digested by others, and discussed as needed. If you look at , you can see it's got a lot going on, making it hard to review. And don't take out the blank lines after headings, or I'll revert you just for that. As for the field of this article, it's basically mathematics; the "applications" in all those other areas are interesting, too, but not the real topic. ] (]) 05:48, 2 March 2012 (UTC)
	::I looked at the talk page before making the edit and didn't see anything pertaining to the changes I was making, but yeah, I see what you mean about bunching them up in one edit. I did some of changes again -- a bit at a time -- so it's clearer. Regarding the stuff removed from the intro, I was more concerned about the two equations themselves. The value and the symbol, as part of the explanation text needs to be in the intro, I think. I stumbled upon this article by looking up something I saw on TV -- a news program -- so the concept is definitely part of the popular culture. And the goal of the style guide is to make article introductions accessible to those who read them. <b>] (]•])</b> 07:20, 2 March 2012 (UTC)
	:::I disagree that the prose adequately explains the ratio. The formulas should be retained. They are accessible to anyone with a minimal background in algebra. Our readers might not always have a college degree but they are not idiots. ] (]) 09:09, 2 March 2012 (UTC)
	::::If the text is rewritten to include the value and the symbol and explains that the value is derived, then the text, along with the graphic to the right, would explain the concept adequately for purposes of an introduction. Remember, this is not a mathematics-only article. Even though most people (maybe) would be able to understand the equations, there is likely a significant fraction who would not and would avoid the article if the equations were in the intro, which is why WP:MOSINTRO advises against including them in introductions. I know in the US, most people would not understand the equations, unfortunately. If you doubt that some readers of WP are this ignorant, just look at some of the feedback comments at ]. <b>] (]•])</b> 23:46, 2 March 2012 (UTC)

	::::The concept is not adequately explainable without the formulae. -- ] (]) 11:50, 2 March 2012 (UTC)
	:::::I agree. But we're not talking about removing them from the article completely, just moving them out of the lead. <b>] (]•])</b> 00:06, 3 March 2012 (UTC)
	::::::There is no need to remove them from the lead, the lead is fine as it is. Various style guides are merely a rule of thumb and have to understood in the context of the given article. The formulas given in the lead are as easy as to understand as the text description, people really struggling with them are unlikely to properly understand the plain text description either. Furthermore the concrete value belongs definitely in the lead and is actually the easiest thing to understand. Even if you don't understand the concept then you still get an idea of what the actual number is.--] (]) 01:04, 3 March 2012 (UTC)
	:::::::The lead is fine as it is. In the spirit of the ], a compact algebraic definition and a numeric formula are central to the subject, and are appropriately placed where they can be quickly seen. Readers will not be helped by pushing those items further down into the article. __ ] (]) 03:15, 3 March 2012 (UTC)

	I find it very difficult to imagine anyone who would find Sparkie82's proposed replacement lede easier to understand than the one that was there before.
	The phrase "the ] of the sum of the quantities to the larger quantity is ] the ratio of the larger quantity to the smaller one" does not communicate anything that is not communicated by "(a+b)/a = a/b", and it does so in a way that is much harder to understand. I am doubtful that there is anyone who will understand phrases of the form "the ratio of the quantity… to …" who will not also understand a simple division sign, and I cannot believe that there is anyone who will understand the phrase "is equal to" but not the = sign.

	In fact, I think Sparkie82's change, and the rationale for it, is is completely misconceived. The phrase "the ratio of the sum of the quantities to the larger quantity is equal to the ratio of the larger quantity to the smaller one" is in fact an equation—that is, it is an assertion of the equality of two quantities. Sparkie82 has not removed the equations from the lede; instead, this user has removed ''one'' of the equations, and the one that was most clearly expressed. —] (]) 15:42, 3 March 2012 (UTC)
	:Thank you for your comments, Mark. I think a key point you made above is:
	:::"''I find it very difficult to imagine anyone who would...''"
	:It is very hard for those of us with a talent for understanding technical subjects to place ourselves in the minds of those who have difficulty with math and science. The reason for making a change to the intro is to make it more accessible ''for those who don't have a talent for math.'' Most people experience math anxiety. And a significant portion of those people also suffer from ], a condition which interferes with the brain's ability to process numbers. The condition effects people across the entire IQ spectrum. Many of those with the condition are able to understand advanced mathematical concepts and relationships. Dyscalculia is just one example; there are many other forms of learning disabilities and a full spectrum of talents in various areas. For example, many people who may be talented in science and math have trouble in social situations because they have a diminished ability for empathy. Everyone is different. This is why WP has an accessibility policy. It's like installing ramps instead of stairs in public places so those with physical disabilities can have access. It costs a little more and maybe even slightly inconveniences those who are able-bodied, put it's part of living in a civil society.
	:A quick glance at the backgrounds of those commenting here shows that this discussion has been dominated by those with exceptional talent in science or math. With your permission, I would like to solicit input from others who may have math anxiety or otherwise have difficulty with math in hopes of gathering more diverse input and perhaps improving this article. This is a very good article with a lot to offer and it would be a shame to drive off a significant portion of potential readers because the intro makes it look like math talent is required to read it. <b>] (]•])</b> 18:00, 3 March 2012 (UTC)
	::The point is not "could a total mathematical ignoramus understand the lead". Because, a total mathematical ignoramus isn't going to get anything out of the article no matter what we do. The question is, rather, does the lead summarize the rest of the article accurately and in a way that's accessible to as many readers as possible. As many as possible is very different from all of them. The mathematics in the lead as it stands is really rather basic, at a level I'd expect my 7th-grade son to be able to read. But more to the point, the mathematics is central to the article; a lead which didn't include it would seriously misrepresent the subject and would do a disservice to the many readers for whom this is accessible. —] (]) 19:24, 3 March 2012 (UTC)
	:::Your comments are offensive and inappropriate. Please reread my previous post and do some research of the issue of dyscalculia and math anxiety in general and then come back here and apologize for you comments. <b>] (]•])</b> 20:31, 3 March 2012 (UTC)
	::::Frankly, I find your overreaction and your demand for an apology offensive and inappropriate. —] (]) 20:36, 3 March 2012 (UTC)

	:::: Imho you better let this go. From where I stand I find rather your tinkering at the article than David's comment as somewhat inappropriate and your arguments regarding the lead have a touch of ]. There are enough articles that need real help, so your energy is better spend there rather than picking a fight over rather marginal aspect in a well established article.--] (]) 20:44, 3 March 2012 (UTC)
	:::::The issue about discalculia (hope I spelled it correctly) is an interesting one. Perhaps a way of solving it is by creating a separate article on the golden ratio in the "simple english" wiki? Arguably formulas should be left out of the lede there. ] (]) 22:06, 3 March 2012 (UTC)
	::::::] still uses algebraic notation, as it should. Simple English uses limited vocabulary and simple syntax because it is aimed at an audience whose first language is not English. (How well it succeeds with that aim is another question.) Arguably, mathematical notation is more universally understood than any ] or dialect of English. __ ] (]) 22:45, 3 March 2012 (UTC)

	::::Is it being alleged that people with discalculia have troulbe with equations? That seems like a misinterpretation. Also not very relevant to how best to write this article. ] (]) 00:55, 4 March 2012 (UTC)
	::I will be very interested to see a cite for your claim that persons suffering from discalculia will understand an equation in the form "the ratio of the sum of the quantities to the larger quantity is equal to the ratio of the larger quantity to the smaller one" but not in the form "(a+b)/a = a/b". Until then, I will continue to believe that your changes are ill-conceived. —] (]) 01:17, 4 March 2012 (UTC)
	:I agree with the comments above to the effect that the established lead is fine, and it would not be assisted by removing formulas. While it would be great to have an article that appealed to everyone, that is simply not possible. There is always ]. ] (]) 02:16, 4 March 2012 (UTC)

	::The phrase cited above, "the ratio of the sum of the quantities to the larger quantity is equal to the ratio of the larger quantity to the smaller one", does not seem very effective. However, one might be able to devise a more effective phrase, not necessarily for inclusion in the lede, but perhaps elsewhere in the article. The trick would be to use the concept of the ]. This already incorporates the idea of choosing the bigger side and dividing by the smaller. Thus, one could define the golden ratio as the aspect ratio of a rectangle with the property that, when it is cut into two smaller equal rectangles, the smaller rectangle has the same aspect ratio as the bigger one. Any takers? ] (]) 16:57, 4 March 2012 (UTC)
	:::You've just defined the ], not the golden rectangle. —] (]) 18:17, 4 March 2012 (UTC)
	::::Just now I learned about the silver rectangle, but actually Tkuvho defined the related ]. __ ] (]) 18:28, 4 March 2012 (UTC)
	:::::Sorry, just daydreaming. ] (]) 18:40, 4 March 2012 (UTC)
	:::::A variation on a theme: cut a big rectangle into a square and a small rectangle so that the big and small rectangles have the same aspect ratios. Hope I got it right this time. ] (]) 18:42, 4 March 2012 (UTC)
	::::::That's more like it, and is shown in ] near the top of this article. Looking further into it, it appears the "Lichtenberg ratio" is just a fancy term, newly coined, for a ratio of 1:√2. __ ] (]) 18:53, 4 March 2012 (UTC)

	I'm testing a proposed new introduction for the article and requested those who are unfamiliar with the topic to comment on it. Those of you who are already familiar with the Golden ratio can continue to comment here. <b>] (]•])</b> 05:24, 5 March 2012 (UTC)
	:Re Dicklyon inquiry about the usability test, because this is a first test, it is open structured so that comments will be open-ended. Users will likely (hopefully) compare the proposed version with the existing version when making comments, but that's up to them. <b>] (]•])</b> 05:32, 5 March 2012 (UTC)

	== Introduction - Usability test ==

	This is a proposed replacement for the introduction of the ] article. If you are unfamiliar with the golden ratio, please add a comment at the bottom of this section. Your comments will be used to help improve this article.

	----

	In ] and the ]s, two quantities are said to have the ''']''' when the ratio between the larger and the smaller quantity is equal to the ratio between their sum and the larger quantity.

	Expressed graphically,

			There appears to be an idea that the "short description" is strictly limited by character count, for something to do with the technologically handicapped who can't see a full screen. In which case I can't get too worked up about it, but fwiw... I don't think a proper description could be shorter than the first sentence of the lead. The "symbolic version" ((a + b) : a :: a : b) is not very transparent to the non-mathematical, but any very condensed prose version is unlikely to be understood by anyone who couldn't understand the symbolic version. I suggest another possibility, which is something like "A ratio (approx. 1.618) which has been ascribed mystic properties." The point is that the purpose of the short description has to be (I think) to confirm to those who have heard of it that it is indeed what they are thinking of, or to hint to those who haven't why this article exists; the purpose is not to give a mathematical definition of its value.
	]

			Aside: a lot of good work has been done on these number articles, but I cannot help feeling that a problem is that while there is more than enough mathematical expertise (which is needed of course) there is a slight shortage of sensitivity to the English language. ] (]) 07:54, 25 December 2023 (UTC)
	When it is calculated, the ratio is 1.61803398...

			:The "mystic properties" part is bullshit though (as the article takes pains to explain). Any such "mystic properties" are not really of special mathematical or cultural significance.
	The symbol for the golden ratio is the Greek letter ](<math>\varphi</math>). The golden ratio is often called the '''golden section''' (Latin: ''sectio aurea'') or '''golden mean'''.<ref name="livio">{{Cite book\|last=Livio\|first=Mario\|year=2002\|title=The Golden Ratio: The Story of Phi, The World's Most Astonishing Number\|publisher=Broadway Books\|location=New York\|isbn=0-7679-0815-5\|url=http://books.google.com/books?id=w9dmPwAACAAJ}}</ref><ref>Piotr Sadowski, ''The Knight on His Quest: Symbolic Patterns of Transition in Sir Gawain and the Green Knight'', Cranbury NJ: Associated University Presses, 1996</ref><ref name="dunlap">Richard A Dunlap, ''The Golden Ratio and Fibonacci Numbers'', World Scientific Publishing, 1997</ref> Other names include '''extreme and mean ratio''',<ref name="Elements 6.3">Euclid,'''', Book 6, Definition 3.</ref> '''medial section''', '''divine proportion''','''divine section''' (Latin: ''sectio divina''), '''golden proportion''','''golden cut''',<ref>Summerson John, ''Heavenly Mansions: And Other Essays on Architecture'' (New York: W.W. Norton, 1963) p. 37. "And the same applies in architecture, to the ]s representing these and other ratios (e.g. the 'golden cut'). The sole value of these ratios is that they are intellectually fruitful and suggest the rhythms of modular design."</ref>'''golden number''', and '''mean of ]'''.<ref>Jay Hambidge,''Dynamic Symmetry: The Greek Vase'', New Haven CT: Yale University Press, 1920</ref><ref>William Lidwell, Kritina Holden, Jill Butler, ''Universal Principles of Design: A Cross-Disciplinary Reference'', Gloucester MA: Rockport Publishers, 2003</ref><ref name = "Pacioli">Pacioli, Luca. '']'', Luca Paganinem de Paganinus de Brescia (Antonio Capella) 1509, Venice.</ref>
			:The most important and characteristic feature of this ratio is that it is the ratio of the diagonal to the side of the regular pentagon, which is why it features prominently everywhere that 5-fold symmetry appears. Because of the ] (in this case meaning small algebraic numbers based on a polynomial of low degree with small integer coefficients), it also appears in other places, e.g. the solution to various combinatorial problems, which don't at first glance have a direct relation to 5-fold symmetry (but can usually be explained/interpreted that way with some effort). –] ] 08:06, 25 December 2023 (UTC)
			::We really shouldn't be trying to find short descriptions that take mathematical understanding to decode or that point to the most salient properties of the topic. That is not what short descriptions are for. They're mainly for things like: in mobile, you search for something, and you get multiple results that match your search. Which one do you want to read? So they should be short, and they should disambiguate the topic, without just repeating the title, but they are not intended to be a rigorous and completely unambiguous description of the topic. I think "Number, approximately 1.618" is better for this than either trying to spell out the extreme and mean ratio or trying to describe some geometric property that fits the golden ratio. —] (]) 08:13, 25 December 2023 (UTC)
			:::Correct. I just used the Misplaced Pages app on a phone to search for "golden". It showed "Golden ratio / Number, approximately 1.618" with the image from the infobox. That is perfect for finding the correct article to read. The short description is for disambiguation. It is not a Google snippet or an alternative to reading the article. ] (]) 08:30, 25 December 2023 (UTC)
			:::I think "Number, approximately 1.618" is good enough for the purposes of a short description. (I also think that "short description" might not be the best short description of what a short description is supposed to do.) ] (]) 16:20, 25 December 2023 (UTC)
			Just to comment briefly again: I said "'''ascribed'''" magic properties; that is true and notable, even though of course the magic properties are nonsense. ] (]) 08:11, 16 May 2024 (UTC)

			== Semi-protected edit request on 25 January 2024 ==
	At least since the ], many ]s and ]s have proportioned their works to approximate the golden ratio—especially in the form of the ], in which the ratio of the longer side to the shorter is the golden ratio—believing this proportion to be] pleasing (see ] below). ]s have studied the golden ratio because of its unique and interesting properties. The golden ratio is also used in the analysis of ], in strategies such as ].
	----

			{{edit semi-protected\|Golden ratio\|answered=yes}}
	Please add your comments below. (If you are already familiar with the golden ratio, or want to comment on the usability test itself, please use another section.) Thank you. <b>] (]•])</b> 05:15, 5 March 2012 (UTC)
			Pleas add the hexadecimal form to the infobox. More specifically, add {{para\|hexadecimal\|1.9E37&thinsp;79B9&thinsp;7F4A&thinsp;7C15...}}, which will fit well and produce
	=====Comments: (click the first ''edit'' link to the right) ---->=====
			: '''Hexadecimal'''&emsp;1.9E37 79B9 7F4A 7C15...
	<!--Add comments below this line-->

			The digits are the result of a routine ]ulation with the ] commands <code>16 o 50 k 1 5 v + 2 / p</code>, which produces <code>1.9E3779B97F4A7C15F39CC0605CEDC8341082276BF2</code> (the last digit isn't trustworthy). ] appears to prefer upper-case letters A–F.
	=====Discussion=====

			The hexadecimal form is useful in software development because it's used by various hashing functions as the "most irrational" number. See ],
	How are you going to find people unfamiliar with the golden ratio to come here and take the test? And how are you going to compare the usability with the usability of what we have already? And why not express the ratio by using the aspect ratio of rectangles, as is pretty typical? ] (]) 05:23, 5 March 2012 (UTC)
	*'''I strongly prefer the existing lead'''. The wide horizontal separation of the two graphical representations of ratios makes it hard to tell that the pieces within them are supposed to be the same height as each other, I dislike mixing pictures and text as if the pictures are parts of speech (and doing so has severe usability issues for blind readers of Misplaced Pages), and the new version loses important information (the golden ratio has an exact value involving the square root of five, not just an approximate decimal value). And the "when it is calculated" phrasing makes no sense — it has that value whether or not some person happens to be calculating it. —] (]) 05:36, 5 March 2012 (UTC)
	*A "usability test" should be conducted somewhere else as there are eight editors who have disagreed with the premise behind the proposal (], ], ], ], ], ], ], ]). There is no reason to spend further time discussing this non-issue. <small>And the proposed diagrams do not help. Why are two adjacent lines a "ratio"?</small> ] (]) 06:31, 5 March 2012 (UTC)
	:*That's fine. Examining the user pages of this small cadre, I see: a computer science professor, a research engineer, a computer programmer and student of mathematics, a programmer with an interest in math, a BSEE (I think), a mathematician, an editor with "Lists of mathematics topics" on his page, and an IP address. An exceptional list of people with exceptional talents for math. I get that you disagree with me and don't understand how the article could be improved and that some folks are scared by formulas. I understand that you don't understand. That's not wrong. Adults don't understand children, men don't understand women. That's why corporations spend billions of dollars each year in market research. And that's why I'm doing this simple little user test, because I don't completely understand either. But I'm willing to try in hopes of improving Misplaced Pages.
	::So yes, it's probably best that we step aside for a few weeks and let the general readership of this article provide input. Thank you for your comments. <b>] (]•])</b> 18:20, 5 March 2012 (UTC)
	:::But you won't find the general readership on this talk page. This page is for editors to discuss how to improve the article. Your survey needs a different venue if you expect it to do anything. ] (]) 19:47, 5 March 2012 (UTC)
	*Sparkie, I'd encourage you to take a look at some of the topics linked in the navbox ] for a sense of the amount of study that has gone into the presentation of quantitative subject matter so people can grasp it easily. If the bulk of that seems daunting, I highly recommend finding a paper copy of ]'s ''The Visual Display of Quantitative Information'' to start with. Suggesting that others "don't understand how the article could be improved" seems premature at this point. __ ] (]) 19:30, 5 March 2012 (UTC)

			Providing 64 bits after the decimal place helpfully matches the largest common numeric data type. This is one more digit than is provided in decimal, compensated by saving one space due to grouping the digits in fours rather than threes.
	== "At least since the Renaissance" ==
			] (]) 03:01, 25 January 2024 (UTC)

	~~"At~~ ~~least~~ ~~since~~ the ~~Renaissance"~~ is in ~~dispute.~~ In ~~fact,~~ ~~there~~ is no ~~concurrent~~ ~~evidence~~ of ~~Renaissance~~ ~~artists~~ ~~using~~ ~~this~~ ~~ratio;~~ ~~everything~~ is ~~line-drawing~~ and ~~measuring~~ ~~after~~ the ~~fact, which~~ is ~~notably~~ ~~vulnerable~~ to ~~selection~~ ~~bias~~. ] (]) 23:02, 13 ~~March~~ ~~2012~~ (UTC)		: I'm looking at the articles in which the infobox is also used: ], ], ], ], ], etc and it seems the hexadecimal is not provided on any of these entries. – ] (]) 14:31, 25 January 2024 (UTC)
			::It was recently removed from a bunch of these (including this article at ]), because it is not considered important enough to focus attention on. There was some meta discussion at ]. –] ] 15:53, 25 January 2024 (UTC)
	:You don't think Pacioli counts as concurrent evidence? —] (]) 23:19, 13 March 2012 (UTC)
			:97.102.205.224: If you are putting this in software, you should probably write it in as {{nobr\|(1 + sqrt(5))/2}}, which is much more legible than a string of hexadecimal digits and should be correctly rounded if you can trust sqrt. In most contexts your programming language will be smart enough to just do this computation once (e.g. at compile time). If you are concerned with ], the appropriate place to include a hexadecimal string is there, not in the infobox here. –] ] 16:03, 25 January 2024 (UTC)
	::It doesn't appear to. He describes the geometric properties, and delves into its relationship to the Platonic solids, not its use in art. The part about the divinity of numbers is more mystical than aesthetic. And there's no evidence of anyone — even Da Vinci, who illustrated the book! — having followed up with actual art or architecture devised around the golden ratio, until at least the 19th century. ] (]) 19:54, 16 March 2012 (UTC)
			::{{ping\|jacobolus\|The Grid}} Er, except that the computation you suggest will generally be done in IEEE double precision (1+52 bits of mantissa) rather than in 64-bit integer math. There's a reason I did my computation in an arbitrary-precision math package.
	::From http://www.emis.de/journals/NNJ/Frings.html#anchor656497: "Neither in the text nor in the illustrations is the Golden Ratio recommended for practical use." ] (]) 20:53, 16 March 2012 (UTC)
			:: The value is used is numerous ''integer'' arithmetic contexts (see the four links provided in the original request, or do your own web searches for "9E3779B9" and "61C88647") where it's implicitly divided by 2<sup>32</sup> or 2<sup>64</sup>. And such applications often require, for compatibility, a bit-exact value; rounding error is not acceptable. A hex literal plus a comment is an easier way to get the exact value desired. (This is also the reason that ] was added to ], ], and POSIX.)
			:: (Tangent: In general, adding an exact integer to an already-rounded square root risks ] if the addition increases the exponent and shifts lsbits off the mantissa. For {{mvar\|φ}} and binary floating-point specifically, this will not happen because {{math\|2 < {{sqrt\|5}} < 1+{{sqrt\|5}} < 4}}, so both have the same exponent and no such shift will take place. Division by 2 is an exponent adjustment with no additional rounding.)
			:: One simple application is ]s. It turns out that the additive sequence {{math\|''k''×''i'' mod 1}}, for {{math\|1=''i'' = 1, 2, 3, ...}} achieves the lowest possible discrepancy (most uniform possible distribution on the unit interval) if {{math\|1=k = φ}}. This can, and often is, done in integer arithmetic by scaling by 2<sup>32</sup> and taking advantage of the automatic modulo-2<sup>32</sup> operation of integer arithmetic.
			:: This is the basis of ].
			:: However, you have to be sure to round to an ''odd'' value when converting to integer form (so that the multiplication by {{mvar\|k}} is invertible modulo-2<sup>32</sup>; see ]), an operation which is not easily achieved in a compile-time computable expression. If you don't allow for this, you might get ''φ''<sup>−1</sup> = 0x0.9E37 79B9 7F4A 7C15 F... rounded to ...7C16, which wouldn't do at all. And if you are using 64-bit words, not even IEEE double will provide enough precision.
			:: This property also makes it a good multiplier for hashing purposes. (] vol. 3 2nd ed. pp. 517–518 & Ex. 9 p. 550).
			:: The binary form of this particular value does come up surprisingly often, which is why I thought it worth including. Ultimately it's an ] judgement. The nice thing about an infobox is that it's easy to skim and ignore irrelevant details; you're not reading it linearly like main article prose. I do note that ] already shows seven existing appearances in Misplaced Pages (plus one I just added to ]). And Knuth judges it useful enough to include a table of the binary (octal, actually) forms of numerous mathematical constants in TAOCP (vol. 3 2nd ed. pp. 748 ''et seq.'').
			:: (The linked debates as to whether mathematical constants should even ''have'' infoboxes is a larger issue I prefer not to get dragged into. My edit request is assuming an infobox exists. If people would ''like'' a larger edit request, I could rework the above application examples into a new subsection of {{alink\|Applications and observations}}, as I see it's not mentioned at present. But to do a good job would be a wider-ranging edit; e.g. the name "" is best mentioned in {{alink\|Continued fraction and square root}} near the discussion of the Hurwitz inequality.)
			:: ] (]) 20:11, 25 January 2024 (UTC)
			:::{{tq\|i=yes\|such applications often require, for compatibility, a bit-exact value; rounding error is not acceptable}} – if you have a ] claiming this, that would be a good argument for including it as part of the section {{slink\|Hash function#Fibonacci hashing}}. Some of the people chatting at the stack exchange links you posted earlier claim that the precise constant is largely irrelevant as long as it is sufficiently mixed up.
			:::Low-discrepancy sequences like your link are calculated in floating point and are not sensitive to slight roundoff error in the 16th decimal place. I liked that blog post, tried to promote it, recommended it to many people, and corresponded with the author, but it's not a reliable source by Misplaced Pages standards. If you can find peer-reviewed sources about that, it would perhaps be worth adding a new subsection to {{slink\|low discrepancy sequence#Construction of low-discrepancy sequences}} (edit: it's discussed at {{slink\|Low-discrepancy_sequence#Additive_recurrence}}, though would benefit from a source other than a blog post). The n-dimensional generalization is out of scope for this article, but the 1-dimensional version based on the golden ratio is discussed at {{slink\|Golden ratio#Golden angle}} and ].
			:::{{tq\|i=yes\| The nice thing about an infobox is that it's easy to skim}} – the bad thing about an infobox is that it's a magnet for heaps of marginally relevant trivia. –] ] 20:26, 25 January 2024 (UTC)
			::::{{ping\|jacobolus}} Er, yes, for strictly ''internal'' hashing, the exact constant is not too critical, although there are arguments (Knuth has the most thorough treatment) that 1/''φ'' or its negative are the ''best'' values. There have been some notable failures due to oversimplified constants chosen to be easier to multiply by. (ISTR this happened in the Linux kernel history... aha, see https://git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git/commit/include/linux/hash.h?id=689de1d6ca95b3b5bd8ee446863bf81a4883ea25 )
			::::However, some hashing is part of an externally-visible interface, e.g. the symbol table hash in ] or some ] formats. The former don't happen to use ''φ'' internally, but there exist rigidly-defined hash functions using ''φ'' which ''could'' be used in an external-facing application; ]'s comes to mind, but I don't have a specific application example where that hash value ''is'' exported. It's certainly plausible that one exists.
			:::: (The crypto applications of course require bit-exact values, but they're random-looking ]s rather than caring about the numeric value.)
			:::: A semi-crypto application is the Java . Is uses a ] with 2<sup>64</sup>/''φ'' as the increment, and officially supports portable deterministic-seeded applications, where the same seed is expected to produce the same output on different systems.
			:::: One thing that's annoying about the somewhat deliberate pace of Misplaced Pages discussions is that I forget things between rounds. I know this whole thing started when I came to this page expecting to find the hex value for some reason, but I've since forgotten what it was!
			:::: I will claim that the scaled integer form of ''φ'' is used in computer software more than any other irrational mathematical constant. In floating point, of course, ''π'' and 2''π'' win hands-down.
			:::: (Trivia found as part of my research for this discussion: https://www.guinnessworldrecords.com/world-records/100485-most-irrational-number )
			:::: ] (]) 22:48, 25 January 2024 (UTC)
			:::::Fair enough, but if a bit-exact value is needed and it has to be rounded to an error in the last place because of extra constraints, then someone who needs to know this should be finding it in a specification, not copying it out of a loosely related Misplaced Pages article. Indeed, the latter is certain to cause an error in this instance! It seems like a decent argument for adding a more specific section about the application to hashing though, and perhaps including 1 or 2 of these hexadecimal values there. –] ] 22:55, 25 January 2024 (UTC)
			:::::: {{ping\|jacobolus}} As I mentioned, I could adapt the preceding discussion into a whole new subsection (two, actually) under the applications section. It would, however, be a lot more work to cut and paste in. Also, I'd very much like to introduce the phrase "most irrational number", as it combines a fairly lay-accessible concept with a mathematically interesting property.
			:::::: The issue is already referred to in {{alink\|Continued fraction and square root}} and {{alink\|Golden angle}}, but I'm not sure if I should expand one or the other, or pull some of it out to a separate section. Since it would come up ''again'' in any discussion of Fibonacci hashing, a separate section seems appropriate, but moving text around at much makes posing an edit-request diff to a talk page a real PITA.
			:::::: Aha! ] will accept revision IDs for two separate articles! The syntax is "Special:Diff/1181263486/1194109625" (not linked because that's not a useful example). So I can come up with something in the Draft namespace. There don't appear to be any good patch/merge tools in Misplaced Pages, but at least the common ancestor would be clearly labelled.
			:::::: Given that, do you have any suggestions for organization? I'm inclined to introduce the phrase, without references, in a summary in the lead section, and then fill in the details in the later sections, with {{alink\|Continued fraction and square root}} containing the formal details, while {{alink\|Golden angle}}, (not yet written) {{alink\|Fibonacci hashing}} and {{alink\|Low-discrepancy sequence}} will describe themselves as applications of the principle.
			:::::: The big question is, should I go for it? (If you say yes, you're volunteering to be nagged to review it when it's finished.) ] (]) 00:39, 26 January 2024 (UTC)
			:::::::I don't really like the "most irrational number" label, since I think it easily leads to misconceptions about what it really means. As you noticed, the article already says "The consistently small terms in its continued fraction explain why the approximants converge so slowly." This could be elaborated but is precise and not misleading, and doesn't overhype the observation. (A different way to look at the same observation is to notice that any rational number is extremely hard to approximate by rational numbers other than itself; the golden ratio is the irrational number closest to sharing this property, so in this sense it is the "''least irrational number''"!) @] what do you think? –] ] 00:45, 26 January 2024 (UTC)
			:::::::As for the annoyance of making edit requests: sorry about the semi-protected status of this article. It got that way because this otherwise is a magnet for vandals and cranks. I made a page at ] that you are welcome to use for whatever chunks of draft text you like: copy whole sections there, move them around, rewrite them, etc. Or you could also consider making an account; once you have had it for 4 days and made 10 edits, you can freely edit semi-protected pages, make new pages, etc. –] ] 01:14, 26 January 2024 (UTC)
			::::::::I think "most irrational" is misleading. Many people would think of it as some kind of qualitative distinction; that transcendental numbers are more irrational than algebraic numbers and that somehow this is the most transcendental among the transcendental numbers (obviously untrue). And "hardest to approximate" is also misleading, because there is no computational difficulty in approximating it. Instead I would prefer phrasing like "least accurately approximated by rationals". —] (]) 01:47, 26 January 2024 (UTC)
			::::::::: H'm... I agree that just by itself, the moniker "most irrational number" is easy to misinterpret (as ] has noted), but with an appropriate explanation (which obviously this article would have) it's always been a useful mnemonic for me. I think ]'s example comparing the ''best'' rational approximation of an irrational number with the ''second-best'' approximation of a rational number is starting out biased. Saying that "exact isn't an approximation" is basically arguing that "zero isn't a number", and I thought we'd put ''that'' to bed at least a sesquimillenium ago.
			::::::::: Even if you think it's misleading, it ''is'' a widely-used phrase, and should be addressed for that reason alone. I'll definitely keep the phrase "least accurately approximated by rationals" in mind!
			::::::::: Anyway, it's the wee hours here and I'm for bed. I'll have to pause my side of this discussion for a while. ] (]) 02:29, 26 January 2024 (UTC)
			::::::::::It's unfortunate that the more accurate phrasing is also significantly less catchy. —] (]) 07:20, 26 January 2024 (UTC)
			::::::::::What I'm thinking about is not "second best approximation", but instead something like: if you start plotting rational numbers, there is something like a "hole" around every integer where no other rational numbers can fit until they start to have very big denominators; to a lesser extent there is a similar "hole" around every rational number; the simpler the number, the bigger the hole (] give one visual explanation for this phenomenon). The number which creates the next biggest kind of hole around itself, besides integers and rational numbers, is the golden ratio. The denominators of rational approximations to the golden ratio at any particular level of approximation grow more quickly than for any other irrational number, while still growing less quickly than for the "second best" approximation to any rational number. So in a certain sense the golden ratio is balanced on the edge between "rational" and "irrational", just on the irrational side. This is why it might be in a certain sense called the "least irrational". A related idea: the golden ratio is the algebraic irrational number with by some definition the simplest ]; it can't get any simpler without being rational. –] ] 08:07, 26 January 2024 (UTC)

			] '''Not done for now:''' please establish a ] for this alteration ''']''' using the {{Tlx\|Edit semi-protected}} template.<!-- Template:ESp --> Clearly this is not an uncontroversial edit. ] (]) 18:22, 25 January 2024 (UTC)
	The German WP article has some sourced information on that. According to that there's a number of renaissance artwork in which the golden section "appears numerically" (da Vinci among others). The notion that this was designed and influenced by Pacioli and there there was a cooperation on that between Pacioli and da Vinci was promoted by the philosopher and golden section guru Zeising the 19th century. However Zeising's arguments are merely speculative and have not substantiated by direct/hard evidence ever since. There has been actually some systematic x-ray analysis of those renaissance paintings by some art expert to verify actual construction sign of the golden section among the paint, but they haven't turned up anything. The explicit, verified use of the golden section doesn't seem to take off before the 19th century.--] (]) 01:56, 18 March 2012 (UTC)
			: {{ping\|PianoDan}} Yes, clearly. Didn't expect that, but it appears to be a good discussion. ] (]) 20:11, 25 January 2024 (UTC)

			Does anyone else have thoughts about this? –] ] 23:01, 25 January 2024 (UTC)
	== Removal of Pacioli woodcut ==

			:Yes, I don't think this sort of thing belongs. WP is supposed to be an encyclopedia, not a geeks' handbook; if we put in a hex approximation, why not add octal and binary? This is all stuff that can be calculated easily if required, and no sensible programmer would rely on a value in WP anyway. ] (]) 03:56, 26 January 2024 (UTC)
	The image http://en.wikipedia.org/File:Divina_proportione.png does not illustrate the golden ration, despite its caption. '''None of the lines or rectangles appear to illustrate the golden ratio'''! It appears to illustrate a system of integer division — 1, 1, 2, 2 for the horizontal divisions, and then a ratio of 6:7 for the box as a whole. 6:7 is not a very good approximation of ''phi''. The horizontal division is clearly by ''half''. So even if this image is well-sourced, it does not appear to be an appropriate illustration. http://www.emis.de/journals/NNJ/Frings.html#anchor656497 confirms that this image illustrates the Vitruvian section, not ''phi''. ] (]) 20:55, 16 March 2012 (UTC)

			== Negative Reciprocal of Golden Ratio ==
	:I agree. I had looked for sources connecting it to phi, and found none; but I hadn't found that source with "Vitruvian section". Good find. ] (]) 15:24, 17 March 2012 (UTC)

			The golden ratio can be calculated from "(1+√5)/2." Using the positive value for √5 gives 1.6180. Using the negative value for √5 gives the negative of the reciprocal of 1.6180, -0.6180. Is this just a coincidence? Does this have any significance? ] (]) 16:52, 20 February 2024 (UTC)
	== Two Platonic solids ==
			:It is not a coincidence. These are the roots of a quadratic equation. The sum of the roots is 1 which is the negative of the linear term's coefficient. The product of the roots is −1 which is the constant term. So the equation is ''x''<sup>2</sup> −''x'' −1 = 0. Just what we need. ] (]) 02:19, 21 February 2024 (UTC)
			:To put it another way, the golden number is the unique number with this "coincidence"; that is what makes it special. Kinda like asking whether it is a coincidence that the ] is the one latitude where the duration of daylight never varies. ] (]) 17:16, 27 March 2024 (UTC)

			== Simple Construction of a Golden Rectangle using two 2x1 Rectangles: ==
	[[File:Academ_Platonic_icosahedron_from_its_dual.svg\|thumb\|left\|upright=2\|'''Platonic dodecahedron and
	icosahedron.'''<br id="top_dd"/>In green, red, blue and yellow, the succession of four lengths is with common ratio φ, the golden ratio.]]
	]
	]
	[[File:Academ Regular_polygons built with_a_golden_puzzle.svg\|thumb\|left\|upright=2\|'''Regular pentagons and
	decagons.'''<br id="rgptdc"/>The ten thick semi-transparent lines are the sides of a stellated regular decagon: an image under a vertical othogonal projection of ten segments, which extend ten edges ]]]
	There is no image about regular polyhedra in the In my opinion, we have to talk about the two Platonic For example, two opposite edges of a Platonic icosahedron are two smaller sides of a
	<br/>— ] (]) 11:59, 17 March 2012 (UTC)

			Constructing a golden rectangle using two 2x1 rectangles. Width = 2, Height = 1 +√5.
	:Good idea; though this one is awful busy, and the "yellow" is not really recognizable as such. ] (]) 15:25, 17 March 2012 (UTC)

			Align the diagonal (√5) of one of these rectangles (A) with the short side of the other rectangle (B) such that the sum of these two elements is now = 1 + √5. This line together with the long side of rectangle (B) form two sides of a Golden Rectangle.
	::About the good idea, thank you. About colours, how might we name the golden tint associated to the fourth and last length of the increasing sequence? Weak ocher? This is depending on our screens and our eyes and our terminology. Anyway, stripes have to draw our attention all the more when they take up less space in the image. Actually, we find the weakest colour because it is the one of the largest length, equal to the sum of some lengths very well marked, and because of this equality written within the image: {{Nowrap\|1=<sup>''a'' </sup>/<sub> φ</sub> + ''a'' = φ ''a.''}}

			This practical method was developed at a local MenzShed for use by woodworkers with no maths.
	::In the current section that is the first image shows The text deals with pentagon and icosahedron…<br/>— ] (]) 09:16, 19 March 2012 (UTC)

			We have a diagram which we can't seem to upload. ] (]) 01:55, 14 March 2024 (UTC)
	<br/>The two ] show the same twelve points built through of a Platonic dodecahedron. More informations in several images, of course.<br/>— ] (]) 16:01, 20 March 2012 (UTC)

	~~Those~~ ~~images~~ ~~look~~ ~~extremely~~ ~~busy~~ ~~and~~ ~~confusing~~ to me. —] (]) 17:11, 20 March ~~2012~~ (UTC)		:It's not new, but I agree a diagram would be appropriate. ] (]) 16:32, 27 March 2024 (UTC)

			:: This is roughly the same idea as this diagram from the article, except this one uses a compass to draw a circle instead of turning the whole rectangle:
	These are extraordinary images, but they are too complex for use in an article. The Platonic solids are wonderful and have many interesting properties, but this level of detail only makes sense after intense study. ] (]) 01:46, 21 March 2012 (UTC)
			:: ]
			:: –] ] 17:28, 27 March 2024 (UTC)

			== Link to Wikiquote ==
	An article is not a course page. In the current article, for example, what does everybody understand in the first image Actually, this current first image does not correspond to the first paragraph. And we cannot explain everything about an interesting 3D image.<br/>— ] (]) 11:00, 21 March 2012 (UTC)

			Please, let you add a link to ] at the bottom of the WP article ] (]) 11:44, 15 May 2024 (UTC)
	:The idea of illustrating the presence of the golden ratio in a platonic solid seems a good one, but how about starting with the simplest illustration of a single such relation for a single solid, rather than the superposition as in these figures? The icosahedron in the first figure seems to play almost no role in the relations. ] (]) 16:16, 21 March 2012 (UTC)

			:This appears to be a backdoor method of reinstating extremely dubious claims about the widespread use of the Golden ratio in classical art and architecture, unsupported by modern scholarship and correctly eradicated from this article. —] (]) 17:33, 15 May 2024 (UTC)
	::Through a of a Platonic dodecahedron, we build a Platonic icosahedron, and twelve stellated regular pentagons. Each face of the great dodecahedron is a duplicate of a face of the initial dodecahedron, {{Nowrap\|to scale φ<sup> 2</sup> or φ + 1. }} Two opposite edges of a great dodecahedron are the smaller sides of a golden rectangle.<br/>— ] (]) 18:47, 21 March 2012 (UTC)
			::The page ] is very strange. That page should probably be deleted, unless someone plans to fill it with proper quotations. I was expecting it to have stuff like Kepler "Geometry has two great treasures " etc., but instead it seems to be some incoherent book excerpts. It's not clear what the point is, but it seems like an abuse of Wikiquote. –] ] 19:20, 15 May 2024 (UTC)

			"Eradicated" seems an odd idea. I know I'm out on a limb here, but I think it would generally be regarded as a Good Thing if what WP said were actually true. It is important to note this historical obsession with the idea that creating something beautiful instinctively produces the GR, which is false, as opposed to the idea that someone might deliberately use it because of some mumbo-jumbo belief set. I think that the mumbo-jumbo is significant enough to be mentioned in the lead: after all, why is it called the "Golden Ratio", "Divine Proportion", etc. But it is also important to get the facts straight: the article includes a quote from a book by a professor with the word "mathematics" in his title: "The Golden Ratio is a standard feature of many modern designs, from postcards and credit cards to posters and light-switch plates." Perfectly supported quotation, proper printed book, what could go wrong? (Well, why do we instantly know from the "light-switch plates" that he is an American? Because he has no concept that "light-switch plates" might be a different shape entirely in other countries, if he even has a clear concept that there are other countries.) So I only know about credit cards and postcards. Credit cards are a universal size (I believe!): 86 by 64 mm. Their aspect ratio is 1.34 approx.; the ratio of the diagonal to the length is about 1.56; the GR is nowhere to be seen. Postcards vary somewhat: I selected the longest group from a bundle at hand, and got a typical 153x103 mm; AR = 1.48. So this book is not telling the truth, and we should not uncritically pass on lies. ] (]) 08:07, 16 May 2024 (UTC)
	:::Whew. Let's start with something simple. Let ''a'' denote the distance between two opposite edges of a dodecahedron. The first figure suggests that the edgelength is then <math>(2-\phi)a</math>. Is this correct? Something that can be stated in English rather than Coxeterish may be appropriate for this page. ] (]) 18:54, 21 March 2012 (UTC)

			== mvar template displaying variable name with odd line breaks in infobox on mobile ==
	::::<math>2\,-\,\varphi</math> is the multiplicative inverse of <math>\varphi^{\,2}.</math><br/>— ] (]) 19:14, 21 March 2012 (UTC)

	~~:::::Very~~ ~~good~~ ~~then~~, we ~~see~~ ~~that~~ ~~phi^2~~ ~~appears~~ as ~~the~~ ~~ratio~~ of ~~the~~ ~~edge~~ to the ~~distance~~ ~~between~~ ~~opposite~~ ~~edges~~ of a ~~dodecahedron.~~ ~~That~~ ~~seems~~ ~~like~~ an ~~English~~ ~~sentence~~ ~~that~~ ~~could~~ be ~~added~~ ~~here.~~ ~~Any~~ ~~comment,~~ ~~David~~? ] (]) 15:14, 22 ~~March~~ ~~2012~~ (UTC)		On my android mobile device, the title of the initial infobox takes up three lines because of what seems to be some odd behavior of the mvar template, adding line breaks within the parentheses for the variable name. Can anyone replicate this and figure out how to fix it? It displays perfectly on a computer browser... ] (]) 03:11, 27 August 2024 (UTC)

			== Semi-protected edit request on 7 September 2024 ==
	::::::How to yield a geometric sequence with common ratio φ from two consecutive terms? From (1, φ), for example, we can yield {{Nowrap\|(2 φ – 3, 2 – φ, φ – 1, 1, φ, 1 + φ, 2 φ + 1), }} through a few additions and subtractions. More generally, given two values ''a'' and ''b'' that fulfill <math>\tfrac{\,a\,}{\,b\,}\,=\,\varphi</math>, we can yield a geometric sequence from (''b'', ''a'' ), either through successive additions or through successive subtractions, depending on the sense of the extending, right or left. Is it an article or a book that we are trying to write?<br/>— ] (]) 17:26, 22 March 2012 (UTC)

			{{edit semi-protected\|Golden ratio\|answered=yes}}
	<br/>If two opposite faces of a Platonic dodecahedron are not distorted under an the outline of the regular polyhedron is a regular Through a stellation of a Platonic dodecahedron and such a projection, we obtain that are the common center of regular decagons and their ten common vertices: ten images of ten vertices of a Platonic icosahedron. Five of these ten vertices are in the upper horizontal face plane, represented by five thick black crosses.
			In the "Music" section of the article it talks about Debussy's "Reflets dans l'eau" which actually translates to "reflections in the water" instead of just "reflections in water" This is a very small change so I apologize for the inconvenience. ] (]) 10:41, 7 September 2024 (UTC)

			:"reflections in water" is the correct translation: English and French grammars are not the same, and it is without "the" that the meaning is kept. However, I fixed the capitalization. ] (]) 16:46, 7 September 2024 (UTC)
	The current rubric presents the only occurrence of "decagon" in the article. Someone that plays with can discover some properties of regular pentagons and decagons, notably that {{Nowrap\|1= ''<sup>r </sup>/<sub> a</sub>'' = φ and ''<sup>d </sup>/<sub> a</sub>'' = φ + 1, }} by denoting {{Nowrap\|''a'', ''d'' and ''r'' }} three lengths in a convex regular decagon: sides, some diagonals, and radius of circumcircle.<br/>— ] (]) 09:29, 23 March 2012 (UTC)
			::By the way, would ''reflets '''en''' eau'' also be correct? ] (]) 02:44, 17 December 2024 (UTC)

			== Semi-protected edit request on 16 December 2024 ==

			{{edit semi-protected\|Golden ratio\|answered=yes}}
	]
			Above the definition of Rogers-Ramanujan function R(q) change "For , let" to "For example, let". ] (]) 16:48, 16 December 2024 (UTC)
			:{{fixed}}: This was a format error resulting that a fomula was not displayed before the comma. ] (]) 18:21, 16 December 2024 (UTC)

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Short description

There appears to be an idea that the "short description" is strictly limited by character count, for something to do with the technologically handicapped who can't see a full screen. In which case I can't get too worked up about it, but fwiw... I don't think a proper description could be shorter than the first sentence of the lead. The "symbolic version" ((a + b) : a :: a : b) is not very transparent to the non-mathematical, but any very condensed prose version is unlikely to be understood by anyone who couldn't understand the symbolic version. I suggest another possibility, which is something like "A ratio (approx. 1.618) which has been ascribed mystic properties." The point is that the purpose of the short description has to be (I think) to confirm to those who have heard of it that it is indeed what they are thinking of, or to hint to those who haven't why this article exists; the purpose is not to give a mathematical definition of its value.

Aside: a lot of good work has been done on these number articles, but I cannot help feeling that a problem is that while there is more than enough mathematical expertise (which is needed of course) there is a slight shortage of sensitivity to the English language. Imaginatorium (talk) 07:54, 25 December 2023 (UTC)

The "mystic properties" part is bullshit though (as the article takes pains to explain). Any such "mystic properties" are not really of special mathematical or cultural significance.

The most important and characteristic feature of this ratio is that it is the ratio of the diagonal to the side of the regular pentagon, which is why it features prominently everywhere that 5-fold symmetry appears. Because of the strong law of small numbers (in this case meaning small algebraic numbers based on a polynomial of low degree with small integer coefficients), it also appears in other places, e.g. the solution to various combinatorial problems, which don't at first glance have a direct relation to 5-fold symmetry (but can usually be explained/interpreted that way with some effort). –jacobolus (t) 08:06, 25 December 2023 (UTC)

We really shouldn't be trying to find short descriptions that take mathematical understanding to decode or that point to the most salient properties of the topic. That is not what short descriptions are for. They're mainly for things like: in mobile, you search for something, and you get multiple results that match your search. Which one do you want to read? So they should be short, and they should disambiguate the topic, without just repeating the title, but they are not intended to be a rigorous and completely unambiguous description of the topic. I think "Number, approximately 1.618" is better for this than either trying to spell out the extreme and mean ratio or trying to describe some geometric property that fits the golden ratio. —David Eppstein (talk) 08:13, 25 December 2023 (UTC)

Correct. I just used the Misplaced Pages app on a phone to search for "golden". It showed "Golden ratio / Number, approximately 1.618" with the image from the infobox. That is perfect for finding the correct article to read. The short description is for disambiguation. It is not a Google snippet or an alternative to reading the article. Johnuniq (talk) 08:30, 25 December 2023 (UTC)

I think "Number, approximately 1.618" is good enough for the purposes of a short description. (I also think that "short description" might not be the best short description of what a short description is supposed to do.) XOR'easter (talk) 16:20, 25 December 2023 (UTC)

Just to comment briefly again: I said "ascribed" magic properties; that is true and notable, even though of course the magic properties are nonsense. Imaginatorium (talk) 08:11, 16 May 2024 (UTC)

Semi-protected edit request on 25 January 2024

This edit request has been answered. Set the |answered= or |ans= parameter to no to reactivate your request.

Pleas add the hexadecimal form to the infobox. More specifically, add |hexadecimal=1.9E37 79B9 7F4A 7C15..., which will fit well and produce

Hexadecimal 1.9E37 79B9 7F4A 7C15...

The digits are the result of a routine WP:CALCulation with the dc commands 16 o 50 k 1 5 v + 2 / p, which produces 1.9E3779B97F4A7C15F39CC0605CEDC8341082276BF2 (the last digit isn't trustworthy). MOS:HEX appears to prefer upper-case letters A–F.

The hexadecimal form is useful in software development because it's used by various hashing functions as the "most irrational" number. See RC5#Key_expansion,

Providing 64 bits after the decimal place helpfully matches the largest common numeric data type. This is one more digit than is provided in decimal, compensated by saving one space due to grouping the digits in fours rather than threes. 97.102.205.224 (talk) 03:01, 25 January 2024 (UTC)

I'm looking at the articles in which the infobox is also used: Square root of 2, Apéry's constant, Square root of 3, Square root of 5, Lieb's square ice constant, etc and it seems the hexadecimal is not provided on any of these entries. – The Grid (talk) 14:31, 25 January 2024 (UTC)

It was recently removed from a bunch of these (including this article at special:diff/1190623333), because it is not considered important enough to focus attention on. There was some meta discussion at WT:WPM (2023 Dec) § Mathematical constant infobox. –jacobolus (t) 15:53, 25 January 2024 (UTC)

97.102.205.224: If you are putting this in software, you should probably write it in as (1 + sqrt(5))/2, which is much more legible than a string of hexadecimal digits and should be correctly rounded if you can trust sqrt. In most contexts your programming language will be smart enough to just do this computation once (e.g. at compile time). If you are concerned with fibonacci hashing, the appropriate place to include a hexadecimal string is there, not in the infobox here. –jacobolus (t) 16:03, 25 January 2024 (UTC)

@Jacobolus and The Grid: Er, except that the computation you suggest will generally be done in IEEE double precision (1+52 bits of mantissa) rather than in 64-bit integer math. There's a reason I did my computation in an arbitrary-precision math package.

The value is used is numerous integer arithmetic contexts (see the four links provided in the original request, or do your own web searches for "9E3779B9" and "61C88647") where it's implicitly divided by 2 or 2. And such applications often require, for compatibility, a bit-exact value; rounding error is not acceptable. A hex literal plus a comment is an easier way to get the exact value desired. (This is also the reason that Hexadecimal#Hexadecimal exponential notation was added to C99, IEEE 754-2008, and POSIX.)

(Tangent: In general, adding an exact integer to an already-rounded square root risks double rounding if the addition increases the exponent and shifts lsbits off the mantissa. For φ and binary floating-point specifically, this will not happen because 2 < √5 < 1+√5 < 4, so both have the same exponent and no such shift will take place. Division by 2 is an exponent adjustment with no additional rounding.)

One simple application is low-discrepancy sequences. It turns out that the additive sequence k×i mod 1, for i = 1, 2, 3, ... achieves the lowest possible discrepancy (most uniform possible distribution on the unit interval) if k = φ. This can, and often is, done in integer arithmetic by scaling by 2 and taking advantage of the automatic modulo-2 operation of integer arithmetic.

This is the basis of Hash function#Fibonacci hashing.

However, you have to be sure to round to an odd value when converting to integer form (so that the multiplication by k is invertible modulo-2; see Weyl sequence), an operation which is not easily achieved in a compile-time computable expression. If you don't allow for this, you might get φ = 0x0.9E37 79B9 7F4A 7C15 F... rounded to ...7C16, which wouldn't do at all. And if you are using 64-bit words, not even IEEE double will provide enough precision.

This property also makes it a good multiplier for hashing purposes. (TAOCP vol. 3 2nd ed. pp. 517–518 & Ex. 9 p. 550).

The binary form of this particular value does come up surprisingly often, which is why I thought it worth including. Ultimately it's an m:Inclusionism judgement. The nice thing about an infobox is that it's easy to skim and ignore irrelevant details; you're not reading it linearly like main article prose. I do note that Special:Search/0x9E3779B9 already shows seven existing appearances in Misplaced Pages (plus one I just added to Fibonacci hashing). And Knuth judges it useful enough to include a table of the binary (octal, actually) forms of numerous mathematical constants in TAOCP (vol. 3 2nd ed. pp. 748 et seq.).

(The linked debates as to whether mathematical constants should even have infoboxes is a larger issue I prefer not to get dragged into. My edit request is assuming an infobox exists. If people would like a larger edit request, I could rework the above application examples into a new subsection of § Applications and observations, as I see it's not mentioned at present. But to do a good job would be a wider-ranging edit; e.g. the name "most irrational number" is best mentioned in § Continued fraction and square root near the discussion of the Hurwitz inequality.)

97.102.205.224 (talk) 20:11, 25 January 2024 (UTC)

such applications often require, for compatibility, a bit-exact value; rounding error is not acceptable – if you have a "reliable source" claiming this, that would be a good argument for including it as part of the section Hash function § Fibonacci hashing. Some of the people chatting at the stack exchange links you posted earlier claim that the precise constant is largely irrelevant as long as it is sufficiently mixed up.

Low-discrepancy sequences like your link are calculated in floating point and are not sensitive to slight roundoff error in the 16th decimal place. I liked that blog post, tried to promote it, recommended it to many people, and corresponded with the author, but it's not a reliable source by Misplaced Pages standards. If you can find peer-reviewed sources about that, it would perhaps be worth adding a new subsection to low discrepancy sequence § Construction of low-discrepancy sequences (edit: it's discussed at Low-discrepancy sequence § Additive recurrence, though would benefit from a source other than a blog post). The n-dimensional generalization is out of scope for this article, but the 1-dimensional version based on the golden ratio is discussed at Golden ratio § Golden angle and Golden angle.

The nice thing about an infobox is that it's easy to skim – the bad thing about an infobox is that it's a magnet for heaps of marginally relevant trivia. –jacobolus (t) 20:26, 25 January 2024 (UTC)

@Jacobolus: Er, yes, for strictly internal hashing, the exact constant is not too critical, although there are arguments (Knuth has the most thorough treatment) that 1/φ or its negative are the best values. There have been some notable failures due to oversimplified constants chosen to be easier to multiply by. (ISTR this happened in the Linux kernel history... aha, see https://git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git/commit/include/linux/hash.h?id=689de1d6ca95b3b5bd8ee446863bf81a4883ea25 )

However, some hashing is part of an externally-visible interface, e.g. the symbol table hash in Executable and Linkable Format or some serialization formats. The former don't happen to use φ internally, but there exist rigidly-defined hash functions using φ which could be used in an external-facing application; Boost (C++ libraries)'s hash_combine() function comes to mind, but I don't have a specific application example where that hash value is exported. It's certainly plausible that one exists.

(The crypto applications of course require bit-exact values, but they're random-looking nothing-up-my-sleeve numbers rather than caring about the numeric value.)

A semi-crypto application is the Java SplitMix64 PRNG. Is uses a Weyl sequence with 2/φ as the increment, and officially supports portable deterministic-seeded applications, where the same seed is expected to produce the same output on different systems.

One thing that's annoying about the somewhat deliberate pace of Misplaced Pages discussions is that I forget things between rounds. I know this whole thing started when I came to this page expecting to find the hex value for some reason, but I've since forgotten what it was!

I will claim that the scaled integer form of φ is used in computer software more than any other irrational mathematical constant. In floating point, of course, π and 2π win hands-down.

(Trivia found as part of my research for this discussion: https://www.guinnessworldrecords.com/world-records/100485-most-irrational-number )

97.102.205.224 (talk) 22:48, 25 January 2024 (UTC)

Fair enough, but if a bit-exact value is needed and it has to be rounded to an error in the last place because of extra constraints, then someone who needs to know this should be finding it in a specification, not copying it out of a loosely related Misplaced Pages article. Indeed, the latter is certain to cause an error in this instance! It seems like a decent argument for adding a more specific section about the application to hashing though, and perhaps including 1 or 2 of these hexadecimal values there. –jacobolus (t) 22:55, 25 January 2024 (UTC)

@Jacobolus: As I mentioned, I could adapt the preceding discussion into a whole new subsection (two, actually) under the applications section. It would, however, be a lot more work to cut and paste in. Also, I'd very much like to introduce the phrase "most irrational number", as it combines a fairly lay-accessible concept with a mathematically interesting property.

The issue is already referred to in § Continued fraction and square root and § Golden angle, but I'm not sure if I should expand one or the other, or pull some of it out to a separate section. Since it would come up again in any discussion of Fibonacci hashing, a separate section seems appropriate, but moving text around at much makes posing an edit-request diff to a talk page a real PITA.

Aha! Special:Diff will accept revision IDs for two separate articles! The syntax is "Special:Diff/1181263486/1194109625" (not linked because that's not a useful example). So I can come up with something in the Draft namespace. There don't appear to be any good patch/merge tools in Misplaced Pages, but at least the common ancestor would be clearly labelled.

Given that, do you have any suggestions for organization? I'm inclined to introduce the phrase, without references, in a summary in the lead section, and then fill in the details in the later sections, with § Continued fraction and square root containing the formal details, while § Golden angle, (not yet written) § Fibonacci hashing and § Low-discrepancy sequence will describe themselves as applications of the principle.

The big question is, should I go for it? (If you say yes, you're volunteering to be nagged to review it when it's finished.) 97.102.205.224 (talk) 00:39, 26 January 2024 (UTC)

I don't really like the "most irrational number" label, since I think it easily leads to misconceptions about what it really means. As you noticed, the article already says "The consistently small terms in its continued fraction explain why the approximants converge so slowly." This could be elaborated but is precise and not misleading, and doesn't overhype the observation. (A different way to look at the same observation is to notice that any rational number is extremely hard to approximate by rational numbers other than itself; the golden ratio is the irrational number closest to sharing this property, so in this sense it is the "least irrational number"!) @David Eppstein what do you think? –jacobolus (t) 00:45, 26 January 2024 (UTC)

As for the annoyance of making edit requests: sorry about the semi-protected status of this article. It got that way because this otherwise is a magnet for vandals and cranks. I made a page at Talk:Golden ratio/sandbox that you are welcome to use for whatever chunks of draft text you like: copy whole sections there, move them around, rewrite them, etc. Or you could also consider making an account; once you have had it for 4 days and made 10 edits, you can freely edit semi-protected pages, make new pages, etc. –jacobolus (t) 01:14, 26 January 2024 (UTC)

I think "most irrational" is misleading. Many people would think of it as some kind of qualitative distinction; that transcendental numbers are more irrational than algebraic numbers and that somehow this is the most transcendental among the transcendental numbers (obviously untrue). And "hardest to approximate" is also misleading, because there is no computational difficulty in approximating it. Instead I would prefer phrasing like "least accurately approximated by rationals". —David Eppstein (talk) 01:47, 26 January 2024 (UTC)

H'm... I agree that just by itself, the moniker "most irrational number" is easy to misinterpret (as David Eppstein has noted), but with an appropriate explanation (which obviously this article would have) it's always been a useful mnemonic for me. I think jacobolus's example comparing the best rational approximation of an irrational number with the second-best approximation of a rational number is starting out biased. Saying that "exact isn't an approximation" is basically arguing that "zero isn't a number", and I thought we'd put that to bed at least a sesquimillenium ago.

Even if you think it's misleading, it is a widely-used phrase, and should be addressed for that reason alone. I'll definitely keep the phrase "least accurately approximated by rationals" in mind!

Anyway, it's the wee hours here and I'm for bed. I'll have to pause my side of this discussion for a while. 97.102.205.224 (talk) 02:29, 26 January 2024 (UTC)

It's unfortunate that the more accurate phrasing is also significantly less catchy. —David Eppstein (talk) 07:20, 26 January 2024 (UTC)

What I'm thinking about is not "second best approximation", but instead something like: if you start plotting rational numbers, there is something like a "hole" around every integer where no other rational numbers can fit until they start to have very big denominators; to a lesser extent there is a similar "hole" around every rational number; the simpler the number, the bigger the hole (Ford circles give one visual explanation for this phenomenon). The number which creates the next biggest kind of hole around itself, besides integers and rational numbers, is the golden ratio. The denominators of rational approximations to the golden ratio at any particular level of approximation grow more quickly than for any other irrational number, while still growing less quickly than for the "second best" approximation to any rational number. So in a certain sense the golden ratio is balanced on the edge between "rational" and "irrational", just on the irrational side. This is why it might be in a certain sense called the "least irrational". A related idea: the golden ratio is the algebraic irrational number with by some definition the simplest minimal polynomial; it can't get any simpler without being rational. –jacobolus (t) 08:07, 26 January 2024 (UTC)

Not done for now: please establish a consensus for this alteration before using the {{Edit semi-protected}} template. Clearly this is not an uncontroversial edit. PianoDan (talk) 18:22, 25 January 2024 (UTC)

@PianoDan: Yes, clearly. Didn't expect that, but it appears to be a good discussion. 97.102.205.224 (talk) 20:11, 25 January 2024 (UTC)

Does anyone else have thoughts about this? –jacobolus (t) 23:01, 25 January 2024 (UTC)

Yes, I don't think this sort of thing belongs. WP is supposed to be an encyclopedia, not a geeks' handbook; if we put in a hex approximation, why not add octal and binary? This is all stuff that can be calculated easily if required, and no sensible programmer would rely on a value in WP anyway. Imaginatorium (talk) 03:56, 26 January 2024 (UTC)

Negative Reciprocal of Golden Ratio

The golden ratio can be calculated from "(1+√5)/2." Using the positive value for √5 gives 1.6180. Using the negative value for √5 gives the negative of the reciprocal of 1.6180, -0.6180. Is this just a coincidence? Does this have any significance? 2601:18E:C700:4B7F:9592:6C05:1FCC:C6FA (talk) 16:52, 20 February 2024 (UTC)

It is not a coincidence. These are the roots of a quadratic equation. The sum of the roots is 1 which is the negative of the linear term's coefficient. The product of the roots is −1 which is the constant term. So the equation is x −x −1 = 0. Just what we need. JRSpriggs (talk) 02:19, 21 February 2024 (UTC)

To put it another way, the golden number is the unique number with this "coincidence"; that is what makes it special. Kinda like asking whether it is a coincidence that the Equator is the one latitude where the duration of daylight never varies. —Tamfang (talk) 17:16, 27 March 2024 (UTC)

Simple Construction of a Golden Rectangle using two 2x1 Rectangles:

Constructing a golden rectangle using two 2x1 rectangles. Width = 2, Height = 1 +√5.

Align the diagonal (√5) of one of these rectangles (A) with the short side of the other rectangle (B) such that the sum of these two elements is now = 1 + √5. This line together with the long side of rectangle (B) form two sides of a Golden Rectangle.

This practical method was developed at a local MenzShed for use by woodworkers with no maths.

We have a diagram which we can't seem to upload. HoneAtHome (talk) 01:55, 14 March 2024 (UTC)

It's not new, but I agree a diagram would be appropriate. —Tamfang (talk) 16:32, 27 March 2024 (UTC)

This is roughly the same idea as this diagram from the article, except this one uses a compass to draw a circle instead of turning the whole rectangle:

–jacobolus (t) 17:28, 27 March 2024 (UTC)

Link to Wikiquote

Please, let you add a link to q:Golden ratio at the bottom of the WP article 2.196.177.65 (talk) 11:44, 15 May 2024 (UTC)

This appears to be a backdoor method of reinstating extremely dubious claims about the widespread use of the Golden ratio in classical art and architecture, unsupported by modern scholarship and correctly eradicated from this article. —David Eppstein (talk) 17:33, 15 May 2024 (UTC)

The page q:Golden ratio is very strange. That page should probably be deleted, unless someone plans to fill it with proper quotations. I was expecting it to have stuff like Kepler "Geometry has two great treasures " etc., but instead it seems to be some incoherent book excerpts. It's not clear what the point is, but it seems like an abuse of Wikiquote. –jacobolus (t) 19:20, 15 May 2024 (UTC)

"Eradicated" seems an odd idea. I know I'm out on a limb here, but I think it would generally be regarded as a Good Thing if what WP said were actually true. It is important to note this historical obsession with the idea that creating something beautiful instinctively produces the GR, which is false, as opposed to the idea that someone might deliberately use it because of some mumbo-jumbo belief set. I think that the mumbo-jumbo is significant enough to be mentioned in the lead: after all, *why* is it called the "Golden Ratio", "Divine Proportion", etc. But it is also important to get the facts straight: the article includes a quote from a book by a professor with the word "mathematics" in his title: "The Golden Ratio is a standard feature of many modern designs, from postcards and credit cards to posters and light-switch plates." Perfectly supported quotation, proper printed book, what could go wrong? (Well, why do we instantly know from the "light-switch plates" that he is an American? Because he has no concept that "light-switch plates" might be a different shape entirely in other countries, if he even has a clear concept that there are other countries.) So I only know about credit cards and postcards. Credit cards are a universal size (I believe!): 86 by 64 mm. Their aspect ratio is 1.34 approx.; the ratio of the diagonal to the length is about 1.56; the GR is nowhere to be seen. Postcards vary somewhat: I selected the longest group from a bundle at hand, and got a typical 153x103 mm; AR = 1.48. So this book is not telling the truth, and we should not uncritically pass on lies. Imaginatorium (talk) 08:07, 16 May 2024 (UTC)

mvar template displaying variable name with odd line breaks in infobox on mobile

On my android mobile device, the title of the initial infobox takes up three lines because of what seems to be some odd behavior of the mvar template, adding line breaks within the parentheses for the variable name. Can anyone replicate this and figure out how to fix it? It displays perfectly on a computer browser... Willmskinner (talk) 03:11, 27 August 2024 (UTC)

Semi-protected edit request on 7 September 2024

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In the "Music" section of the article it talks about Debussy's "Reflets dans l'eau" which actually translates to "reflections in the water" instead of just "reflections in water" This is a very small change so I apologize for the inconvenience. 2A02:A58:8291:BC00:C82B:18DC:E9C4:DB34 (talk) 10:41, 7 September 2024 (UTC)

"reflections in water" is the correct translation: English and French grammars are not the same, and it is without "the" that the meaning is kept. However, I fixed the capitalization. D.Lazard (talk) 16:46, 7 September 2024 (UTC)

By the way, would reflets en eau also be correct? —Tamfang (talk) 02:44, 17 December 2024 (UTC)

Semi-protected edit request on 16 December 2024

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Above the definition of Rogers-Ramanujan function R(q) change "For , let" to "For example, let". 2A00:1028:8388:6446:AD6C:8E02:2C5A:FBD4 (talk) 16:48, 16 December 2024 (UTC)

Fixed: This was a format error resulting that a fomula was not displayed before the comma. D.Lazard (talk) 18:21, 16 December 2024 (UTC)

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