Talk:Straightedge and compass construction

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	A fact from this article appeared on Wikipedia's Main Page in the "Did you know?" column on March 20, 2004.

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And I quote from the first subsection "compass and straightedge tools", first bullet point:

Circles can only be drawn starting from two given points: the centre and a point on the circle. The compass may or may not collapse when it's not drawing a circle.

I think these two sentences are contradictory. The first seems to imply a collapsing compass, as you must pre-define the radius and center point in order to draw the circle there. If a rigid compass were permissible then you need only a center point in order to draw a circle whose radius youve already defined with the compass.

You could fix it however you like, possibly best to point to Compass equivalence theorem, they're completely equivalent. Dmcq (talk) 19:09, 13 July 2018 (UTC)[reply]

At some time in the past I Heard the commentators for professional wrestling refer to the ring in which activity takes place as the "squared circle". This is an excellent example of pseudo-science in the service of pseudo-sport. Eclecticology

We need more on doubling the cube and angle trisection. The Anome

Thanks, Pierre! The Anome

Mathematicians are notoriously incompetent historians. Gauss NEVER gave a proof of the necessity of the constructibility of the regular n-gon. WANTZEL proved this in 1837. If you read otherwise, it's because mathematicians are sloppy historians. Revolver

Or is it the historians who are sloppy, notoriously incompetent mathematicians?  ;-)

—Herbee 18:43, 2004 Mar 13 (UTC)

No, the people doing the history are mathematicians specialising in history of math, not the other way around. (True for most sciences...you have to have some understanding of the material.) Revolver 13:08, 14 Nov 2004 (UTC)

It is definitely the fault of mathematicians here. Some VERY famous names aided and abetted this myth, without checking into it themselves. You'd think being math people, they would question things. Revolver 13:09, 14 Nov 2004 (UTC)

The article mixes the two words compass and compasses with obviously the same meaning. Both words are acceptable according to Webster's, but for the sake of consistency I'm changing all to compass. Why not compasses? Because that way I don't have to move the article, and anyway "ruler and compasses construction" is less agreeable to the ear.
—Herbee 18:43, 2004 Mar 13 (UTC)

MERGE: This needs to be merged with Constructible number and all the other articles on specific impossibility proofs. These overlap a lot, yet none of them should try to cover every topic. Revolver 13:08, 14 Nov 2004 (UTC)

I think there's room for a lot of reorganization here. Some pages should be merged; some new ones should be split off. I just ran into a problem with Regular polytope; somebody got carried away with the difference between real and ideal construction. That's a whole subject in itself; but it's not math. John Reid 22:15, 27 March 2006 (UTC)[reply]

The regular polygon with the largest number of sides that was ever actually drawn with a ruler and compass had 1,024 sides. It was drawn by graduate student Mr. Sam Bronstein at the University of Kentucky in 1963, a feat that took him 33 days and a sheet of paper 9 meters square.

Is it really as imprtant to be here? Tosha 03:37, 18 October 2005 (UTC)[reply]

No, but it might go to Polygon. John Reid 23:33, 30 March 2006 (UTC)[reply]

technically, using a compass and a straightedge to draw a hexagon is impossible, since the circumference is 2Πr. not 2(3)r.

there is a slight distortion. the only true way to draw a real hexagon is to 1. bisect the circle at any point 1/2 way between the center[o] and an edge[e] to form point [a] 2. using point [a] as a center, draw a line [b] perpendicular to the angle formed between [e] and [o] 3. mark the two points where [b] intersects the circles radius 4. repeat 180 from [e] across [o]

above unsigned comment 17:39, 8 December 2005 Kargoneth

I'm not a mathematician, but I don't see why the hexagon construction doesn't work. Is it because pi is irrational? Can someone clarify this?

(Also, this proposed construction seems rather vague. How do you draw a line perpendicular to an angle? What does "180 from [e] across [o]" mean? It is decipherable, but it takes some work.) Imaginaryoctopus 05:30, 10 December 2005 (UTC)[reply]

Addition: I did a little research, and it seems to me that the hexagon construction is fine. From the "Constructible polygon" page:

"A regular n-gon can be constructed with compass and straightedge if n is the product of a power of 2 and any number of distinct Fermat primes."

We let n=6 (representing a hexagon). We know that 2^1=2 and that 3 is a Fermat prime, so we can say 3*2=6.

Even if you don't buy this, the construction itself comes straight from Proposition 15 in Euclid's Elements, Book IV. Imaginaryoctopus 05:56, 10 December 2005 (UTC)[reply]

For the record, a regular hexagon is constructible. John Reid 23:36, 30 March 2006 (UTC)[reply]

A ruler is commonly understood to be marked; this type of construction specifically forbids markings. John Reid 19:18, 26 March 2006 (UTC)[reply]

As you say most people commonly think of a ruler as being a "marked" one (technically called a "measure"). However a ruler can also be unmarked. See ruler) for a fuller discussion of all this. Paul August ☎ 16:47, 28 March 2006 (UTC)[reply]

A ruler is a marked straightedge; this is explicitly forbidden in compass and straightedge construction. For practical purposes the ruler is the more generally useful tool, certainly the more popular; thus it's not hard to see why the term is also more popular. But this is one of those times that the Google test gives a false indication.

To the quibble: Yes, strictly speaking, a "ruler" is a straightedge only, a tool for ruling (drawing straight lines). A tool for measuring is a "scale"; thus the commonplace object found in home and office is truly a ruler with a scale printed upon it -- a dual-purpose tool. It is, however, ambiguously called a ruler; and the less-common "straightedge" is clearly and unambiguously unmarked. John Reid 23:55, 28 March 2006 (UTC)[reply]

Being a quibbler by nature, I cannot resist pointing out that the "unambiguous umarkedness" of the straightedge may not be straightforward: [1][2][3]. Lambiam^Talk 05:29, 9 April 2006 (UTC)[reply]

The verb "rule" is sometimes synonymous with "measure" or "judge". Therefore, I suggest that all wording in this article be changed to "straightedge" instead of "ruler". SharkD (talk) 07:39, 18 December 2007 (UTC)[reply]

Does it actually matter if a ruler is marked or not. It is a trivial matter to produce a marked straight edge from an un marked straight edge and a compass. Step 1: draw a small circle, call the radius of the circle your unit. Next draw a straight line with the ruler, pick some point on the line to be zero, using the compass set to the unit radius mark off one unit from zero. Move the point of the compass to the first unit, mark of the second unit, .... The same procedure can be repeated for any straight edge in the diagram, effectivly giving the same construction possible as with a marked streight edge and compass. --Salix alba (talk) 00:09, 29 March 2006 (UTC)[reply]

See Doubling the cube for a "ruler (straightedge with two marks)" and compass construction which cannot be simulated by a "ruler and compass" construction. — Arthur Rubin | (talk) 00:46, 29 March 2006 (UTC)[reply]

One can indeed create a Cartesian grid (as described in the article) with equally spaced out points along the axes. However, although it may look like you've effectively constructed a replacement for a marked straightedge, the point is that you are still only allowed certain operations with your straightedge and compass. So you are still restricted as to how you can use elements of this "grid" and you will not be able to double the cube, etc. Now if you were to actually violate the rules for a Euclidean construction somehow, you can double the cube. For example, see the particular example Arthur gave. In that example, one creates a point of intersection between two lines by measuring along a marked straightedge, which is disallowed under the normal rules. --C S (Talk) 09:10, 30 March 2006 (UTC)[reply]

The distinction is essential, which is why I am involved. You can, indeed, create a scale of any constructible numbers along a line. If you were to look at that, it would appear to be a ruler, in common speech. In order to use it as a new tool, though, you would have to cut it out from the paper on which it was drawn and translate it. If translation by a non-constructible distance is permitted -- and we generally understand that two objects may be offset, relative to one another, by any real-number distance -- then this opens the door to all three classic forbidden constructions.

If cut-and-translate is permitted, then it's not even necessary to produce a scale. See Tomahawk.

The issue of the marked straightedge is of a class distinct from that of the non-collapsing compass. Euclid I.2 and .3 justify the non-collapsing compass and show that any construction possible with the non-collapsing compass can be performed with the collapsing. The definition of the compass never changes throughout Euclid; but later constructions are simplified. It is understood that any of them could be expanded on demand. This is important; the actual process of duplicating a given line segment is hellishly complex compared to the ease of simply drawing a new circle with the old radius held in the compass. But the latter operation is only justified by the proof of the former.

It is exactly this kind of subtle distinction between permitted and forbidden operations that invites so many cranks to waste their lives on fallacy. And this is why I feel so strongly about the issue of term used to describe this subject. John Reid 23:32, 30 March 2006 (UTC)[reply]

One of the biggest issues I have with a marked ruler - beyond the fact that it is capable of extending constructibilty - is the simple fact that it introduces measure, a metric, into the plane. This turns geometry from something more abstract and geometric, to something more algebraic. 134.204.1.226 (talk) 16:57, 11 January 2024 (UTC)[reply]

At the end of the move discussion, Elroch wrote (in part): Hopefully...all redirects (of which a large number are needed) will be changed to being direct. By the way, I hope my slightly more formal section on the interpretation of geometric constructions as operations in the complex field is helpful. Further work needed includes removing some of the repetitions in other sections, and a description with a diagram (or alternatively a link) for the geometric construction for each arithmetic operation.

I went around to all linking articles and fixed all links to point directly to Compass and straightedge. I'll take a look and check to see that all are still correct and all rds direct and single.

Before the move discussion, I'd intended to finish up my work with a rewrite of this article. Now that the page is "hot", there have been plenty of edits so I'll hold off on a comprehensive rewrite; it may not be necessary with many hands on the page.

One particular plan of mine for this field is to deal with Trisecting the angle. Like Doubling the cube and Squaring the circle, this is one of the 3 classic impossible constructions. I think either one article Impossible constructions? should stand for all or each should have its own page. I intend to slim down description of these subjects in the main article, in proportion.

I can provide good graphics for any construction if someone will kindly indicate what's required. Let's get together in a corner and thrash it out. John Reid 05:00, 4 April 2006 (UTC)[reply]

Ref proof of impossibility - this article is probably a good enough place to refer in general to all three. 131.107.0.106 00:21, 13 April 2006 (UTC)[reply]

Great job to everyone who has been working on all the article. I will try to get some time to help out also. --C S (Talk) 16:34, 4 April 2006 (UTC)[reply]

Currently the intro mentions that the proofs of impossibility of the famous classical constructions rely on Galois theory; even the Galois theory article makes this assertion. However, the proofs just rely on basic field theory with no need of Galois groups, etc. The current phrasing would even seem to take credit away from Pierre Wantzel, giving it to Galois. I think a change is needed. --C S (Talk) 16:42, 4 April 2006 (UTC)[reply]

Ok, I fixed it. Hopefully it is acceptable. The page on Galois theory though now needs to be fixed. --C S (Talk) 08:29, 7 April 2006 (UTC)[reply]

It might be worth mentioning that it _is possible to solve these problems to arbitrary accuracy (just not exactly). Simlply draw a cartesian grid of whatever scale is required (if you make it fine/big enough you can get any desired level of accuracy). Only mathematicians make a distiction between "as close as you like" and exact. --Pog 15:21, 25 April 2006 (UTC)[reply]

Firstly, this is an article about a topic in mathematics, not about practical drafting methods. That should really be clear from the article. Secondly, it is true but rather a minor point that approximate constructions for squaring the circle, etc, exist: approximate constructions exist for every single point in the plane, since the constructible points are dense in the plane (I have added a statement to this effect). Hence adding this note would be like adding a note in the article Rational number to say that Pi could be approximated as accurately as one wished with a rational number. This is true, but also true of all other real numbers and that wouldn't be the right place for it. Elroch 21:42, 25 April 2006 (UTC)[reply]

I disagree - I think there should be some mention of this, to inform the casual reader, (without being overly technical) that compass and straight edge are at least as powerful as the rational numbers, and can be used to solve any problem to arbitrary precision. The important point is that they cannot represent all of the real numbers - so one can produce an infinitely good approximation, given infinite time, but can never produce an exact answer in the strictly mathematical sense (because they lack the expressive power in the same way as the rational numbers cannot express the exact solution).

Shouldn't this be moved to the "Constructible Number" article, since they have little to do with compass and straightedge directly?

Whether moved or not, the second sentence in the section on marked rulers is completely obtuse. Someone who understands it in detail should just yank this particular sentence and rewrite it wherever it belongs. "This would permit them, for example, to take a line segment, two lines (or circles), and a point; and then draw a line which passes through the given point and intersects both lines, and such that the distance between the points of intersection equals the given segment." Between which points of intersection -- all three? How does a distance "equal" a segment? Can we stop jamming "for example" appositives everywhere they are grammatically legal? (140.232.0.70 (talk) 21:47, 14 January 2011 (UTC))[reply]

Shouldn't this define what is meant by an angle of finite order or link to a definition? --OinkOink 13:52, 18 July 2006 (UTC)[reply]

A further generalisation of this theorem (due to K. Venkatachala Iyengar) gives constructions using only a ruler given a point and five distinct points equidistant from it.

This is false - for example, given (0,0), (0,1), (0,-1), (1,0), (-1,0), and (1/√2,1/√2), the points that can be constructed with only a straightedge have coordinates in Q[√2]. Even supposing specific special points (x1,y1), ..., (x6,y6) (rather than arbitrary points), all points constructible with only a straightedge would have coordinates in Q[x1,y1,...,x6,y6], which cannot capture the closure of Q under square roots (which is what ruler and compass can construct).

I suspect that this false generalisation is due to a misinterpretation of another result - given those 6 points, one can construct arbitrarily many points of the circle given by those 5 equidistant points, as well as its center. If one actually had the circle and its center, that would be enough, but having arbitrarily many points on it isn't.

David.applegate 18:33, 9 August 2006 (UTC)[reply]

The brief plug to Mathematics of paper folding under impossible constructions is poorly worded. It needs to be brought up to the level normally present on Wikipedia. --Whiteknox 01:39, 17 November 2006 (UTC)[reply]

Obsessed as he was with a belief that gravity was known to the ancients, Isaac Newton used a compass and straightedge construction to illustrate his theory of gravitation, rather than the fluxions he had invented (differential equations), which would have been more natural. He chose this more awkward method so as to demonstrate that the theory would have been accessible to the ancient pythagorans, unaware that Archimedes had infact known of greatly more advanced analytical geometric methods.

Unsourced; and largely false. Archimedes' more "advanced analytical method" was the Method of exhaustion, which Newton knew about, and used; it's in Euclid. Newton published his results with Euclidean proofs because these proofs were, and were understood to be, rigorous; Newton's fluxions were not, and would become so for another two centuries. Septentrionalis PMAnderson 19:03, 20 February 2007 (UTC)[reply]

In my long-lost undergraduate days, I came across a sourcebook with an interesting letter from Newton in which he defined what we now know as the derivative with *exactly* the "modern" notion of a limit (given verbally, but precisely). It's bizarre that this took centuries to be rediscovered.--OinkOink 21:22, 20 February 2007 (UTC)[reply]

Do you think that the article is ready to become a featured article? Tomer T 18:44, 23 March 2007 (UTC)[reply]

These two section appear to have almost identical content. Should they be merged? --Salix alba (talk) 23:37, 10 May 2007 (UTC)[reply]

I absolutely agree that they should be merged. Compass and straightedge constructions as complex arithmetic seems a touch more understandable to me, BTW. Root⁴(one) 16:13, 15 May 2007 (UTC)[reply]

IMO, this article spends most of its time reviewing (a) what can't be done and (b) complicated proofs of this and complicated proofs of some thinghs that can be done. It appears to lack almost completey a review of what can be done and of how to do (some) of these constructions. I was tempted to add the following (next para) but thought I'd put it here for comment first.

"An example of a simple achievable construction is to divide a line into two sections of ratio 1 : N (integer). First construct perpendicular lines at each end of the target line, next construct, with the compass, one target line length 'down' on the 'left' and N target line lengths 'up' on the 'right'. Join the two resultant points for a 1:N intersection."

-- SGBailey (talk) 23:10, 31 May 2008 (UTC)[reply]

"Infinite in length and only having one side." Isn't that physically impossible? 207.62.186.233 (talk) 02:59, 3 June 2008 (UTC)[reply]

The fourth paragraph of the introductory section reads as follows:

"The most famous ruler-and-compass problems have been proven impossible in several cases by Pierre Wantzel, using the mathematical theory of fields. In spite of these impossibility proofs, some mathematical novices persist in trying to solve these problems. Many of them fail to understand that many of these problems are trivially solvable provided that other geometric transformations are allowed: for example, doubling the cube is possible using geometric constructions, but not possible using ruler and compass alone.."

Regarding the end of this last sentence: If an example is offered, it should be given, not withheld. Doubling the cube is "possible" using what geometric constructions?Daqu (talk) 23:01, 26 March 2009 (UTC)[reply]

Do you see how the text "doubling the cube" in that sentence appears in blue, perhaps with an underline? That means that you can click on it, and read in detail about the problem of doubling the cube. In that article there is a section titled "Solutions" that answers your question. —Dominus (talk) 06:36, 28 March 2009 (UTC)[reply]

The discussion on moving the article seems to have stalled a while ago with no decision. As a purely practical matter, it's usually much easier to make a link to the article when the article name is singular.--RDBury (talk) 05:40, 27 June 2009 (UTC)[reply]

Moved this here from the article:

Suppose an algorithm that gives you a point as a result. The point will always be given by intersection of two lines (or line and circle or two circles. See previous elemental operations), but there are infinite points in a classical euclidean space.

Regardless of the algorithm we use, we can only perform a finite number of steps. Therefore, no matter what algorithm we use to determine them, there will always be points that we cannot mark by crossing of two lines (same holds if we mark the point as intersection of a line and a circle, or of two circles)

This sounds nonsensical to me. A finite (but unbounded) number of operations can certainly produce an infinite number of possible points. All rational points on the plane can be constructed, even though there are infinitely many of them. The real impossibility proof is that the number of constructible points is countably infinite but there are uncountably infinitely many reals. If anyone wants to write it up, go for it. Arvindn (talk) 18:17, 1 September 2009 (UTC)[reply]

Is it mentioned anywhere how to construct 60 degree angles? It is one of the simpler constructions. SharkD  Talk  04:03, 28 November 2009 (UTC)[reply]

thumbnail doesn't seem to animate, tho the gif itself does. --Arkelweis (talk) 07:54, 28 February 2011 (UTC)[reply]

I would like to call into question the value of this section. First, the paper referred to is now 14 years old ... not particularly recent in my mind, so I find the section title a bit misleading. The section has been in the article since Sept. 2002, with no change in content (but there have been minor changes in how the reference is given). The single sentence is pure hype and does not add anything to the article. On the basis of Wikipedia:Notability I would say that the section should be struck. In support of this I note that according to Math Reviews, the paper that this section references has never been cited by any other mathematical article. As a Wikipedia editor I should not be commenting on the quality of referenced sources, but as a working mathematician I feel the need to point out that there are professional standards for published mathematical works and the paper being talked about fails to meet those standards in many ways. The fact that the author of the paper is also a founding editor of the journal in which this paper appears may explain how it got published in the first place. Comments? Bill Cherowitzo (talk) 03:33, 1 April 2012 (UTC)[reply]

Is there any analogous model where instead of limiting the compass and straightedge constructions to a single 2D plane, that we instead use them on a number of intersecting 2D planes in 3 dimensional space?siNkarma86—Expert Sectioneer of Wikipedia
^{86 = 19+9+14 + karma = 19+9+14 + talk} 05:25, 19 December 2012 (UTC)[reply]

Replacing circles with spheres so you look at points where lines or spheres intersect is the obvious extension. However you still don't get anything beyond doing square roots. Dmcq (talk) 10:51, 19 December 2012 (UTC)[reply]

I've checked Google books and only found two instances of the name with hyphens in instead of spaces. Therefore this new hyphens name is not a common name and the article should be move back to its old title. Dmcq (talk) 22:43, 23 May 2013 (UTC)[reply]

I did the checking by putting "compass-and-straightedge" with the quotes into Google Books. I did not do any special checking that hyphens were inappropriate and therefore an entry should be ignored. If some demonstration can be made that there is some criteria I should use which is better and changes the statistics enough to favour the hyphens from the 2% I found I'd like to see it. Dmcq (talk) 14:52, 24 May 2013 (UTC)[reply]

I just did a check using "straightedge-and-compass construction" on Google Books and that did bring up the hyphens somewhat. There were six without hyphens and four with on the first page, the first five did not have a hyphen. It was 9 hyphens and 20 without and one I couldn't tell on the first three pages. Dmcq (talk) 16:14, 24 May 2013 (UTC)[reply]

Just noticed I used "straightedge and compass construction" instead of "compass and straightedge construction". In fact straightedge and compass construction came up 1560 times on Google books but compass and straightedge construction only came up 900 times.

I think on this evidence the article should be titled "Straightedge and compass construction" rather than "Compass-and-straightedge construction". Dmcq (talk) 16:22, 24 May 2013 (UTC)[reply]

I was also jarred by this move and did a little investigation myself. I have certainly seen the hypenated version but only rarely and a quick pass through my bookshelf did not turn up any instances of it. I also looked for the ruler and compass version with or without hyphens. The variations may be due to some grammatical rules (and I am no expert on those). The hyphens make straightedge-and-compass a compound noun, denoting a class of constructions, but one can also refer to the tools used in such a construction, in which case the hyphens should not appear. In using the compound noun, one can say that construction X is a straightedge-and-compass construction, but this article is concerned with straightedge-and-compass constructions. When the move was made, there were two changes, the hyphens were added and constructions was singularized. I think that the title should either be hyphenated with constructions, or no hyphens with construction. Bill Cherowitzo (talk) 18:11, 24 May 2013 (UTC)[reply]

Well I think we should just follow WP:COMMONNAME unless it comes up wit something really stupid. Dmcq (talk) 19:33, 24 May 2013 (UTC)[reply]

The usual rule for hyphens is to include them between words that together form a single adjective for something else in the sentence, and to leave them out when the words form a noun phrase that's not functioning as an adjective. For example, "a high-school opera" ("high-school" functions as an adjective for "opera") but "an opera performed in high school" ("high school" is a noun, the object of "in"). Similarly, "compass-and-straightedge constructions" but "constructions made with compass and straightedge". —Ben Kovitz (talk) 14:48, 25 May 2013 (UTC)[reply]

Maybe but it doesn't follow WP:COMMONNAME that I can see and that is part of a Wikipedia policy. Is there a good reason to prefer grammar to common name in this instance? Also straightedge and compass construction is more common in books than compass and straighterdge construction. Dmcq (talk) 16:09, 25 May 2013 (UTC)[reply]

I think including the hyphens follows the ordinary rules for punctuation, and forms the common name. Or am I misunderstanding you? I don't have an opinion (yet) on whether "compass" or "straightedge" customarily comes first. I'll do a little googling and see if my results agree with yours. —Ben Kovitz (talk) 16:21, 25 May 2013 (UTC)[reply]

Googling books is what I did so please go ahead and check for yourself. I understand common name as meaning the name that is more common as written down in the major reliable sources rather than the name that follows grammar or is otherwise official in some way. Dmcq (talk) 16:27, 25 May 2013 (UTC)[reply]

"compass and straightedge constructions" came up with 2250 books, and "straightedge and compass constructions" came up with 2,660. The books in the first couple pages of the latter seem more authoritative than the former: Springer-Verlag, etc. In the first 19 books in the straightedge-and-compass group, about a third had hyphens and two-thirds didn't. —Ben Kovitz (talk) 19:03, 25 May 2013 (UTC)[reply]

More results from Google books: "compass and straightedge construction": 832 books, 4 out of the first 20 with hyphens. "straightedge and compass construction": 1,560 books, earliest hits from more-authoritative publishers, 6 out of the first 19 with hyphens.

Here's what I think is going on regarding the hyphens: While the hyphenated version clearly follows standard English punctuation for compound attributive nouns, sometimes copyeditors omit the hyphens when they seem unwieldy and there's no real ambiguity. This happens especially often in titles.

Personally, I find the version without hyphens jarring because it leads to a "garden-path" interpretation after "compass and". I'd prefer to stay with the hyphens. —Ben Kovitz (talk) 05:44, 29 May 2013 (UTC)[reply]

Well I think that established 'Straightedge and compass construction' as a preferable title for Wikipedia, but should we even include the 'construction' bit? It seems a bit unnecessary to me and people more often just say something like 'using straightedge and compass'. Dmcq (talk) 13:38, 27 May 2013 (UTC)[reply]

I think "construction" is definitely necessary in the title. It's part of the standard terminology of geometry, which distinguishes constructions from proofs. —Ben Kovitz (talk) 05:21, 29 May 2013 (UTC)[reply]

An alternate method for constructing polygons is by taking any two sides of a right-angle triangle as radii of a circle & its sectors,some of the results will be apeiroga,but most give good results.AptitudeDesign (talk) 08:53, 21 April 2014 (UTC)[reply]

Unless I missed something, the article currently contains no history prior to Gauss, except a brief mention that a proposition of Euclid's implies that it doesn't matter whether a compass is collapsible, a brief statement that the requirements can be expressed in terms of Euclid's first three postulates, and the dubious statement

The following three construction problems, whose origins date from Greek antiquity, were considered impossible in the sense that they could not be solved using only the compass and straightedge.

(I thought they kept trying rather than assuming impossibility--is that not right? The above assertion needs a citation.)

I think it would be worthwhile to have a history section that answers:

• Did the ancient Greeks come up with the requirements of a straightedge and compass construction? In what context?

• What lengths, angles, and figures could they construct? (E.g., could they do the regular pentagon? Did they think that all regular polygons ought to be constructible?)

• What did they say about squaring the circle, doubling the cube, and trisecting the general angle? Did they think that these could be solved? Which trisectible angles did they know how to trisect?

• How much of the above shows up in Euclid, and where?

Loraof (talk) 19:17, 11 January 2015 (UTC)[reply]

I found a source and got a good start on a history section, but it needs to be beefed up with more material and more sources. Loraof (talk) 22:40, 11 January 2015 (UTC)[reply]

Could we make a section with much used constructions, so that readers have some directory linking to much used (but not bascic) constructions, I know the list should not be to long or maybe a seperate page for a longer list. but on this page a list refering to "midpoint of segment", "angle bisector" , "mirror point in line" and maybe 7 more is in order.WillemienH (talk) 08:55, 8 June 2015 (UTC)[reply]

I have just removed an addition dealing with unit distance graphs. The quoted result says that for any algebraic number there is a graph (in the Euclidean plane) with a pair of vertices at this distance for any unit distance graph representation. If this was related to compass and straightedge constructions, it would be saying that all algebraic numbers are constructible - which is clearly false. If I am somehow mistaken, the section would have to indicate how it is related to the topic of this article before being replaced. Bill Cherowitzo (talk) 04:01, 26 November 2015 (UTC)[reply]

Yes all algebraic numbers are constructable using unit-distance-graph constuructins. And yes unit-distance-graph constuructins is a type of geometric constructions (not worse that origami-constructions). --Tosha (talk) 12:54, 27 November 2015 (UTC)[reply]

Then this is not constructible using straightedge and compass and so doesn't belong in this article. Perhaps Constructible number would be a better place for it. Bill Cherowitzo (talk) 13:25, 27 November 2015 (UTC)[reply]

Yes that doesn't belong here, it is too general and unrelated, but a construction using linkages with no sliders would and that is practically the same thing. See [5]. I like the name isoklinostat too :) Dmcq (talk) 13:57, 27 November 2015 (UTC)[reply]

F. Klein described another linkage machine in his "Famous problems of Elementary Geometry" (? - not sure I got that right, I'm not at home) that can do this as well, and we already have a page on it (sorry, don't remember the name). Perhaps we can extend this section to include these and the unit graph result. My earlier suggestion was made without looking at that page and I didn't realize that it was so limited. Bill Cherowitzo (talk) 19:39, 27 November 2015 (UTC)[reply]

The difference with origami is there is an explicit construction for trisecting an angle at the article pointed at as an important part of the whole business, see Mathematics of paper folding#Trisecting an angle. The straightforward axioms can deal with cubics but not more complex polynomials. Dmcq (talk) 14:20, 27 November 2015 (UTC)[reply]

It is mentioned in "Extended constructions", and it is an extended constructions. Yes it is related and yes it is quite general. By the way, if one consider multiple folds in origami constructions then you also get all algebraic numbers. I will undo your edits. Next time please discuss first. --Tosha (talk) 11:27, 28 November 2015 (UTC)[reply]

You do not get all algebraic numbers with the Huzita–Hatori axioms for origami. The original research policy WP:OR says says in its nutshell "Articles may not contain any new analysis or synthesis of published material that serves to reach or imply a conclusion not clearly stated by the sources themselves." For the origami trisection there is a citation in the Mathematics of paper folding article explicitly talking about trisecting angles in origami and giving the construction and there's other citations which could be given giving the connection to the axioms if you'd like citations here. The linkage constructions I and Bill Cherowitzo mentioned above talk explicitly about trisecting and they do everything necessary and relevant as far as this article is concerned compared to that general paper. And it is normal to not put things back in but discuss it first when you are in a minority about the insertion. Dmcq (talk) 13:44, 28 November 2015 (UTC)[reply]

1. you should read carefully what I wrote (I did not say that get all algebraic numbers with the Huzita–Hatori axioms for origami). See for example Theorem 1 in One-, Two-, and Multi-Fold Origami Axioms by Alperin and Lang.(In particular this is not original research) 2. I asked you to discuss before making changes, I think you should do it next time. (Note that it is not me who started this "war".) 3. For the rest I gave the answers already --- I will wait couple of days and undo you changes. I am 100% sure think this type of construction worth to be mentioned here. --Tosha (talk) 17:00, 29 November 2015 (UTC)[reply]

I was aware you could get the further shapes if you extend those origami axioms but it isn't so easy to do them and there is no straightforward connection to trisecting. The basic axioms do that fine and there are citations for it. The thing you have to do to get any further here is get a citation directly linking unit graphs and trisection. And really I can't see why you are going on about that here, the linkages do the job straightforwardly and pretty much equivalent in idea and more to the point there are citations showing the link. No we don't leave things in if it is obvious they don't belong and there is consensus about that.Dmcq (talk) 18:25, 29 November 2015 (UTC)[reply]

Dmcq Could you provide some reasons, why you object to include the linkage-construction? So far I did not see any. Please make it clear, maybe number them and either I will agree or I could explain what is wrong with them. (At the moment our discussion goes nowhere). --Tosha (talk) 22:38, 2 December 2015 (UTC)[reply]

I do not object to a trisection linkage which has a good relevant citation. The classical impossible constructions are an important part of the article and there are citations talking about compass and ruler and the classical problems and directly connecting linkages with those. I do object to putting in things which don't mention a direct connection, that paper doesn't mention compass or ruler or anything like that. The WP:OR policy says we should not put things like that into articles. You should not be trying to push things like that in here unless somebody in the world at large has thought it worthwhile to publish a connection. I have explained this before, you seem to deny that is a real reason but it is pretty fundamental to Wikipedia.

If you really feel the need to stick that citation into some article you should find an appropriate article or set one up. An article on the various types of points that can be constructed using different axioms would be a notable topic I think - for instance subsets of Hilbert's axioms of Geometry allow one to generate various interesting subsets of the ones that can be constructed using compass and ruler and there's other constructions that lead to wider fields like the one with unit distances you found. I can't find an appropriate article on a quick search but there probably is one or one could be set up easily. It could include for instance the ones where ${\displaystyle {\sqrt {a^{2}+b^{2}}}}$ can be got but not ${\displaystyle {\sqrt {a^{2}-b^{2}}}}$ and such an article would be fine for a unit distance graph. Dmcq (talk) 02:24, 3 December 2015 (UTC)[reply]

I did like the link to [www.euclidea.xyz/game] Euclidea an online compass and straightedge construction game that was added 18 march 2016, but was removed soon after with as reason (revert - rm promotional link; this is not a web directory) I did like the link and would like it reinstated, because it is related , I like it (but that is personal and is not within the scope of Wikipedia:NOTDIRECTORY. Also I would like to add a link to [6] but that would have I guess the same result. WillemienH (talk) 18:36, 18 March 2016 (UTC)[reply]

Doesn't seem to be add anything to the topic, it is just a nice game. Unfortunately I agree it comes under not a directory. Dmcq (talk) 00:06, 19 March 2016 (UTC)[reply]

Euclid seems to have had a broader view of what a "construction" is than this. For example, proposition 3.1 constructs the center of a circle from the circle. That can't be done with the basic constructions because there are no intersections to make a point from and no points to make a line or circle from. However, Euclid does it by drawing a chord through the circle at random, relying on the fact that the construction works no matter which chord one draws. Perhaps the definition of construction has changed? — Preceding unsigned comment added by Mrperson59 (talk • contribs) 23:04, 7 September 2018 (UTC)[reply]

While there are certainly problems with Euclid's "proof" in III.1, I don't see where your objection is coming from. The circle has to be given (determined) in some manner, and Euclid does this by talking about the circle through the three points, A, B, C. Yes, that choice is arbitrary, but it is not part of the construction, rather it is part of the given. There is no aspect of the construction that uses random elements. --Bill Cherowitzo (talk) 03:53, 8 September 2018 (UTC)[reply]

The other possibility is that the circle is determined by a center and a radius - but in that case one already has the center and so here is no need to construct it. Dmcq (talk) 09:17, 8 September 2018 (UTC)[reply]

No move was done after the discussion at #Bad move where it seems 'Straightedge and compass construction' is more common. Also the version without hyphens seems more common but seems to occur about a third of the time. Any objections to a move now? Prefer hyphens? Dmcq (talk) 09:54, 8 September 2018 (UTC)[reply]

I'd favor the move to "Straightedge and compass construction" (no hyphens). In analogy with the technically incorrect, but still common, ruler and compass construction, there are no hyphens and putting compass first is somehow jarring. I believe that this is a case where the rules of grammar are being ignored in favor of common practice, and we should follow suit. --Bill Cherowitzo (talk) 18:34, 8 September 2018 (UTC)[reply]

The History section doesn't explain the origins of the compass and straightedge restriction, nor does it distinguish between eras in which the restriction was considered absolute and eras where constructions using other tools were considered legitimate but less aesthetic, less fundamental or otherwise second class. Shmuel (Seymour J.) Metz Username:Chatul (talk) 13:35, 20 May 2021 (UTC)[reply]

== Regarding Doubling the cube: Is it still impossible? ==

This is the first time I have contributed anything to Wikipedia besides donations, so I'm not sure what exactly I'm doing here. And I am not a mathematician for sure, but I wanted to at least point out something in this article that may no longer reflect current knowledge. The latest Scientific American Magazine (October 2021 Volume 325, Issue 4 [7]) features an article on math entitled "Infinity Category Theory Offers a Bird's-Eye View of Mathematics"] [8] by Emily Riehl which seems to indicate that it is now possible to construct "with an imaginary straightedge and compass, of a cube with a volume twice that of a different, given cube".

Just trying to make Wikipedia better in my own diminutive way. I'll check back to see which part of subterranean garbage this post has been banished to bc that's how I learn. Thanks. Glenn Wiens GAWiens (talk) 06:25, 20 October 2021 (UTC) [reply]

Please disregard my entry as it isn't relevant to the matter at hand. My bad - I'll stick with conventional contributions in the future. GAWiens (talk) 00:48, 22 October 2021 (UTC)[reply]