It's much more accurate if you don't use a compass for the division. From point Q make lines as you did for line QB with the other numbers. That will give you the points on the circle dividing it much more precisely. Every second point is your main one while the others are your mid points. I found that this method is much more reliable for me because I don't have to pinpoint the exact point with compass every time while watching if the compass moved out of alignment or not.
This is a great and accurate approximation. One viewers comment pointed out that it’s only off by 2 degrees for a nonagon. Even with a spirograph you’d have to be careful of your margins for larger divisions.
Well done! My nephew and I are going to make decoder rings (ROT x) and I needed to know how to do this from scratch - manually. Going to give it a go now!
This is NOT an accurate method. You get a nonagon, yes - a 9-sided polygon, but it is NOT a regular nonagaon as claimed - a 9-sided polygon with all sides equal and all angles equal. The first 8 sides are all equal in length, but the 9th is different from the rest. It is definitively proven (long ago now) which regular polygons can be constructed via Euclidean geometry and which cannot. This is the content of the Gauss-Wantzel Theorem as has already been mentioned elsewhere in these comments. If you are interested to know more about this, you can look up "constructible polygons" in wikipedia. Pulling a quote from that article: "a regular n-gon is not constructible with compass and straightedge if n = 7, 9, 11, 13, 14, 18, 19 ..." Notice that the regular nonagon is not constructible. The method presented in this video is not a neusis construction, it's just wrong. There are neusis constructions that extend Euclidean geometry sensibly and allow solutions to some classically impossible problems - that's not what's going on here. We have a false and deceptive claim that is misleading people.
What a pity ! But Arthur is wrong with this construction ! First i thought i was messing arround with my compass, but then i tested it with a CAD program and now i understand, thats not my fault ;-)
@@andreash.6175 Not your fault at all. I applaud your use of a CAD program to check this out more carefully. It is one of the perrenial flaws in geometric "arguments" to rely upon the accuracy of manual drawings - the accuracy of such drawings degrades very quickly with the increasing number of drawing steps. It is this kind of flaw that allows people to believe that they have achieved something that they have not. CAD is far better, but every CAD "drawing" has its limitations also. There is no substitute for the rigor of mathematical proof, which Arthur's construction is not. As I noted already, it is difinitively proven which regular polygons can be constructed in Euclidean geometry and which cannot. The ones of many sides that are "interesting" have constructions that are quite complex. They are beautiful in their own way, but not simple and not achieved by any "general method". An interesting subject, but quite non-trivial.
It is an approximation and it has it's uses. It has reasonable precision, since the error is that it devides the circle in 40.3º instead of 40º, which is just as good as one can do with a protractor. And if want to be precise in the langugage as well as the drawing, although the method is accurate, it is not perfectly precise.
@@Alkis05 Yes, but it should be mentioned, thats only an approximation. IF using this way here, it is advisable not to use the compass measuring a side length around the circle, but the lines throu the diameter where the cros the circle... By the way: you always can also use the formula a = 2 * r * sin(180/n) by your pocket calculator and to measured and transferred as side length with your compass. This would be exact....
@@andreash.6175It wouldn't be exact because "sin" is a transcedental function. Shouldn't you mention that? No you shouldn't, because the people that don't know about it don't care for that degree of precision and the people that would need to know probably already does. Besides, this requires a calculator. There are some situations where you can't use one, most notably when you just don't want to. Also, you would need some kind of protractor too, which you might not have, at least one that is appropriate to the scale of the drawing.
Carl Friedrich Gauss (en.wikipedia.org/wiki/Carl_Friedrich_Gauss ) was so proud of having found a way to divide a circle into 17 (equal) parts (as in en.wikipedia.org/wiki/Heptadecagon ), "claiming" this to be his greatest discovery in the year 1801 as far as it's told, so he might used calculus, but this must have been a rather/mostly analog(ue) way.
i like drawing mandalas in M$paint (since my drawing skills suck) and find your methods wonderful. a little finagling to get them to work with no compass and they're not perfect, but they're fun. thx for all your work :D
Love this so much and thanks you for posting this. I’m about to put in a spiral staircase into an uneven semi circle one piece at a time and I believe this will answer all my troubles.
It must have been to divide the straight line into n parts equally. After getting the length from the intersect point to B, the parallel lines are no longer needed. They were just used to equally slice the line into 9 parts
I also wonder what the purpose of this is. The needed points seem to come from the center line, with the preceeding line not needed? Is this the most accurate way to divide the circumference of a circle with only a straight edge and a compass?
@@M05tly that is a geometric trick to make equi-distance divisions on a line. in this case, just trust the geometry and you really only need that location of the second division on the vertical diameter. then follow the steps as described. so if you want to draw a clock, ie twelve division. use this trick to mark out 1/6th of the vertical diameter line. draw the line from Q and this point to the edge of the circle. use that compass trick to mark out the other 10 divisions to get 12 lines of the clock. easy peasy
@@borislum1998 I don't understand on first reading but looking at my comment it's been over a year since I watched the video. I'll rewatch it and let you know when it's clicked. Thanks for the info.
I am stuck, I’ve been trying to use this method and I’m always slightly out ie when I measure around using the compass it doesn’t return to the origin it’s off -I’m measuring and remeasuring in fact it’s more accurate if I just measure 36 with a protractor (I’m dividing the circle into 10 equal parts) I’ve even tried drawing from QB every 2nd point instead of a compass and it’s still slightly out!!!
1:50 this doesn't seem to jive. What is the second reference point when connecting the diagonal lines to centerline? Especially if done by hand these could be all over the place. And the placement of the second diagonal line seems critical. 3:07
looks good to what you have done, but how did you come up with using the number 2 and what are all the other numbers for so why is it needed to draw al the other divisions Please explain :)
I think this method relies a lot on being really accurate. I tried this for 13 points and the first time ended up with exactly 12! The second time I got 13 but the final gap was smaller than the rest. I shall persevere, but any hints on doing this by hand would be appreciated. My ultimate goal is to make a massive circular calendar with 365 or 366 divisions... has anyone tried this before? I wanted something about 1 meter diameter.
Why did we divide AB line by the number of spaces we want and not use it? Also, Thales's theorem requires a 90-degree angle if I'm not mistaken. Why did you use cm's? I've tried this to make a 26-part circle 5 times, and it hasn't worked. It seems like you're leaving something out.
Yes there is: ___________________ ╱ ╱ ⎛ ⎛2 ⋅ π⎞⎞ L = R ⋅ ╱ 2 ⎜1 - cos ⎜───⎟⎟ ╲╱ ⎝ ⎝ n ⎠⎠ L is the side of the n-polygon inscribed in a circle with radius R
actually there is (sort of) : "chord length" = 2 x R x Sin (theta / 2) where 'R' is the radius of the circle and 'theta' is the angle subtended at the center of the circle by the chord. This is useful when you are dividing a circle into N equal segments: the formula simplifies to "chord length" = D x Sin (180 / N). So here you'd set your compass to "chord length" in order to mark off N equal segments of a circle with diameter = D.
It's clear that this method is only approximate, since it's famously impossible to construct a regular 7-gon using only a compass and straightedge. However, I can't seem to find a resource that discusses this approximation in more detail (e.g. how approximate is it? When is it no longer wise to use it?). Is there a particular name for this approximation that I can search?
It's not an approximate method, however the accuracy does depend upon how accurately you draw points, arcs and lines etc. The method is based on "Thales theorem ".
Gurpreet Singh but if it weren’t an approximation, then all polygons would be constructible polygons, and that would contradict the Gauss-Wantzel theorem, no?
For those also interested in this question, this method seems to be referred to as "the Bion method", and is mentioned in Chapter 1, Use 17 of 'The Construction and Principal Uses of Mathematical Instruments' by Nicolas Bion, though he refers there to Johann Christophorus Sturm's 'Mathesis Juvenilis' as a source for the method. He also discusses the (very small) error fundamental to the method.
@@keithwiley7122 thanks Keith! I intended to say that theoretically this method is not an approximation but as the number of sides will increase, the manual error accumulated may become appreciable enough.
I always thought it was called the Neusis construction, and that's what the Wikipedia on this topic is called but even then I'm asking the same question about the method...
For some reason I can't find it anywhere but in Portuguese-language sites and videos, but the method is known as the "Rinaldini Method", and I believe this to be the name of the guy who invented it. Link in Portuguese Language Wikipedia: pt.wikipedia.org/wiki/Divisão_da_circunferência_em_partes_iguais_(processo_geral) I have found references to the Bion method, and the Tempier method, which seem to be the same thing, somehow.
Great video!! So well explained! Could I ask you for a formula, or a written source like if n*6 x(distance)=… . My question is coming for a musical purpose. From Geometry and music theorised my EUCLID, in music we call them euclidian beats or patterns. The idea is, no matter the number of beats/hits they are always spread evenly around a circle. So I was looking around but never found a formula to put it in code form. Thanks in advance!
@@elleeo1495 Yes. It simply can't be done for anything other than 2^n number of arcs (i.e., 2, 4, 8, 16, etc.) or 3 x 2^n number of arcs (i.e. 3, 6, 12, 24, 48, etc.), and certain other specific numbers including 5 x 2^n, 15x 2^n, 17 x 2^n, etc. or p x 2^n where p is the base number of sides of known constructible polygons.
you have to be very accurate with hand drawn compass lines. here is a tip. draw with a bigger circle. your error in the angles will be smaller. good luck. or use a CAD or computer aided drawing program
HELP. HELP HELP,,,,A normal circle has 360 degrees,,,,,,how can i create a circle with 147 equal arcs of degree. Or to put it another way, How can i create a 360 degree circle, with a 260 mm diameter, divided into 147 segments of arc, each with an angle of 2.4489795 of a degree. Any help will stop me breaking down, regards Jim
With the following formula _________________ ╱ ╱ ⎛ ⎛2 ⋅ π⎞⎞ L = R ⋅ ╱ 2 ⎜1 - cos ⎜───⎟⎟ ╲╱ ⎝ ⎝ n ⎠⎠ L is the side of the n-polygon inscribed in a circle with radius R. That being said, unless you are using a computer, it is very hard to make a polygon with so many sides by hand.
YES THIS GOOD, BECAUSE, STUDENT WISE FOR KNOWLEDGE NEED TO HAVE THAOUGHT, HOW TO MAKE DRAW CIRCLE AT ANY ANGLE OF DIGREE , LIKE 5 DEGREES , LIKE 10 DEGREES, LIKE 45 DEGREES, LIKE 90 DEGREES. IS THIS GOOD GIVEN KNOWLEDGE.
I believe 2 is always used because the person drawing already knows the first point as 'A'. Since they're trying to find the second point on the circumference, they walk the line from Q through the second point on diameter to the circumference to find where the next point is for even sides. After 1 is 2 so they always pass the line through 2. Hope this helps.
because the metered line represents the WHOLE circumference... but your mark is only for half that circumference... as you are projecting the points out only to one side of the circle
It's much more accurate if you don't use a compass for the division. From point Q make lines as you did for line QB with the other numbers. That will give you the points on the circle dividing it much more precisely. Every second point is your main one while the others are your mid points. I found that this method is much more reliable for me because I don't have to pinpoint the exact point with compass every time while watching if the compass moved out of alignment or not.
You would have to of course make a second point Q on the other side
Yes, BUT to only use the even numbers
Sir should i always use 2nd point as intersecting point?
And why only sir 2nd point not any other?
This is a great and accurate approximation. One viewers comment pointed out that it’s only off by 2 degrees for a nonagon. Even with a spirograph you’d have to be careful of your margins for larger divisions.
Appreciate your timing to make this video, just like I learned in drawing school
Beautiful!!
Using my 40 years old compass, it's pure joy
This is the best explanation I have ever seen, I love drawing mandalas and sacred geometry and this is most helpful! Thank you so much!
... thanks, and now I know what Mandalas are! these rabbit burrows on youtube ....!
I'm into mandalas as well and this is a very thorough and helpful explanation. Thanks for sharing.
Beautifully done, crystal clear, superb graphics. Just thoroughly sensible.
Thank you very much
Well done! My nephew and I are going to make decoder rings (ROT x) and I needed to know how to do this from scratch - manually. Going to give it a go now!
I thought i was smart untill i saw this video.Thank you so much.
This is NOT an accurate method. You get a nonagon, yes - a 9-sided polygon, but it is NOT a regular nonagaon as claimed - a 9-sided polygon with all sides equal and all angles equal. The first 8 sides are all equal in length, but the 9th is different from the rest.
It is definitively proven (long ago now) which regular polygons can be constructed via Euclidean geometry and which cannot. This is the content of the Gauss-Wantzel Theorem as has already been mentioned elsewhere in these comments. If you are interested to know more about this, you can look up "constructible polygons" in wikipedia. Pulling a quote from that article:
"a regular n-gon is not constructible with compass and straightedge if n = 7, 9, 11, 13, 14, 18, 19 ..."
Notice that the regular nonagon is not constructible. The method presented in this video is not a neusis construction, it's just wrong. There are neusis constructions that extend Euclidean geometry sensibly and allow solutions to some classically impossible problems - that's not what's going on here. We have a false and deceptive claim that is misleading people.
What a pity ! But Arthur is wrong with this construction ! First i thought i was messing arround with my compass, but then i tested it with a CAD program and now i understand, thats not my fault ;-)
@@andreash.6175 Not your fault at all. I applaud your use of a CAD program to check this out more carefully. It is one of the perrenial flaws in geometric "arguments" to rely upon the accuracy of manual drawings - the accuracy of such drawings degrades very quickly with the increasing number of drawing steps. It is this kind of flaw that allows people to believe that they have achieved something that they have not. CAD is far better, but every CAD "drawing" has its limitations also. There is no substitute for the rigor of mathematical proof, which Arthur's construction is not.
As I noted already, it is difinitively proven which regular polygons can be constructed in Euclidean geometry and which cannot. The ones of many sides that are "interesting" have constructions that are quite complex. They are beautiful in their own way, but not simple and not achieved by any "general method".
An interesting subject, but quite non-trivial.
It is an approximation and it has it's uses. It has reasonable precision, since the error is that it devides the circle in 40.3º instead of 40º, which is just as good as one can do with a protractor.
And if want to be precise in the langugage as well as the drawing, although the method is accurate, it is not perfectly precise.
@@Alkis05 Yes, but it should be mentioned, thats only an approximation.
IF using this way here, it is advisable not to use the compass measuring a side length around the circle, but the lines throu the diameter where the cros the circle...
By the way: you always can also use the formula a = 2 * r * sin(180/n) by your pocket calculator and to measured and transferred as side length with your compass. This would be exact....
@@andreash.6175It wouldn't be exact because "sin" is a transcedental function. Shouldn't you mention that? No you shouldn't, because the people that don't know about it don't care for that degree of precision and the people that would need to know probably already does.
Besides, this requires a calculator. There are some situations where you can't use one, most notably when you just don't want to. Also, you would need some kind of protractor too, which you might not have, at least one that is appropriate to the scale of the drawing.
Carl Friedrich Gauss (en.wikipedia.org/wiki/Carl_Friedrich_Gauss ) was so proud of having found a way to divide a circle into 17 (equal) parts (as in en.wikipedia.org/wiki/Heptadecagon ), "claiming" this to be his greatest discovery in the year 1801 as far as it's told, so he might used calculus, but this must have been a rather/mostly analog(ue) way.
i like drawing mandalas in M$paint (since my drawing skills suck) and find your methods wonderful. a little finagling to get them to work with no compass and they're not perfect, but they're fun. thx for all your work :D
Try using the software called "gimp", has more tools.
@@Drew_Hurst can you tell me which software the author has used in the video?
This is great - no use for it currently but good to know and I will try to work out the maths behind it
Absolutely amazing. Loved it dude !!!!!!!
Awesome, and truly appreciated!
Love this so much and thanks you for posting this. I’m about to put in a spiral staircase into an uneven semi circle one piece at a time and I believe this will answer all my troubles.
So whats the point of drawing ALL 9 parallel lines after drawing the 2nd line which intersects "Q"?
Did you ever find out?
It must have been to divide the straight line into n parts equally. After getting the length from the intersect point to B, the parallel lines are no longer needed. They were just used to equally slice the line into 9 parts
I also wonder what the purpose of this is. The needed points seem to come from the center line, with the preceeding line not needed?
Is this the most accurate way to divide the circumference of a circle with only a straight edge and a compass?
@@M05tly that is a geometric trick to make equi-distance divisions on a line. in this case, just trust the geometry and you really only need that location of the second division on the vertical diameter. then follow the steps as described. so if you want to draw a clock, ie twelve division. use this trick to mark out 1/6th of the vertical diameter line. draw the line from Q and this point to the edge of the circle. use that compass trick to mark out the other 10 divisions to get 12 lines of the clock. easy peasy
@@borislum1998 I don't understand on first reading but looking at my comment it's been over a year since I watched the video. I'll rewatch it and let you know when it's clicked. Thanks for the info.
Very good video.
I am stuck, I’ve been trying to use this method and I’m always slightly out ie when I measure around using the compass it doesn’t return to the origin it’s off -I’m measuring and remeasuring in fact it’s more accurate if I just measure 36 with a protractor (I’m dividing the circle into 10 equal parts) I’ve even tried drawing from QB every 2nd point instead of a compass and it’s still slightly out!!!
Great video-thank you
1:50 this doesn't seem to jive. What is the second reference point when connecting the diagonal lines to centerline? Especially if done by hand these could be all over the place. And the placement of the second diagonal line seems critical. 3:07
Very helpful thank you
If you search "set square" in RUclips, you will find videos on how to draw parallel lines (which is useful for finishing this diagram.)
How do you demonstrate, rigorously, that the point B is *exactly* at 1/9 th of the circumference ? (Angle AOB exactly equal to 2 * *π* / 9 ?)
looks good to what you have done,
but how did you come up with using the number 2 and what are all the other numbers for
so why is it needed to draw al the other divisions
Please explain :)
I think this method relies a lot on being really accurate. I tried this for 13 points and the first time ended up with exactly 12!
The second time I got 13 but the final gap was smaller than the rest. I shall persevere, but any hints on doing this by hand would be appreciated.
My ultimate goal is to make a massive circular calendar with 365 or 366 divisions... has anyone tried this before? I wanted something about 1 meter diameter.
I had the same results when trying to divide into 13.
Is there a proof to this somewhere? I am really interested
Brilliant!!!☘
Omg. That's just blown my mind box.
Is this how they did the 56 Aubrey Holes at Stonehenge perhaps?
Why did we divide AB line by the number of spaces we want and not use it? Also, Thales's theorem requires a 90-degree angle if I'm not mistaken.
Why did you use cm's? I've tried this to make a 26-part circle 5 times, and it hasn't worked. It seems like you're leaving something out.
thank you so much sir
if we needn360 divisions then?
I tried to divide 13 parts. This method did not work there...
Hello, I have a question
Is there a formula to divide a circle into n equal parts? Like using pi or sin or cos
Something like that?
No there is not
Yes there is:
___________________
╱
╱ ⎛ ⎛2 ⋅ π⎞⎞
L = R ⋅ ╱ 2 ⎜1 - cos ⎜───⎟⎟
╲╱
⎝ ⎝ n ⎠⎠
L is the side of the n-polygon inscribed in a circle with radius R
actually there is (sort of) : "chord length" = 2 x R x Sin (theta / 2) where 'R' is the radius of the circle and 'theta' is the angle subtended at the center of the circle by the chord. This is useful when you are dividing a circle into N equal segments: the formula simplifies to "chord length" = D x Sin (180 / N). So here you'd set your compass to "chord length" in order to mark off N equal segments of a circle with diameter = D.
is this an approximation? is there any 'imperceptible warpage'?
There is approximation. The magnitude of error will be revealed in the last arc and the error will be magnified by increasing the size of the circle!
It's clear that this method is only approximate, since it's famously impossible to construct a regular 7-gon using only a compass and straightedge. However, I can't seem to find a resource that discusses this approximation in more detail (e.g. how approximate is it? When is it no longer wise to use it?). Is there a particular name for this approximation that I can search?
It's not an approximate method, however the accuracy does depend upon how accurately you draw points, arcs and lines etc.
The method is based on "Thales theorem ".
Gurpreet Singh but if it weren’t an approximation, then all polygons would be constructible polygons, and that would contradict the Gauss-Wantzel theorem, no?
For those also interested in this question, this method seems to be referred to as "the Bion method", and is mentioned in Chapter 1, Use 17 of 'The Construction and Principal Uses of Mathematical Instruments' by Nicolas Bion, though he refers there to Johann Christophorus Sturm's 'Mathesis Juvenilis' as a source for the method. He also discusses the (very small) error fundamental to the method.
@@keithwiley7122 thanks Keith! I intended to say that theoretically this method is not an approximation but as the number of sides will increase, the manual error accumulated may become appreciable enough.
I always thought it was called the Neusis construction, and that's what the Wikipedia on this topic is called but even then I'm asking the same question about the method...
Whoever figured this out first had to be a genius
For some reason I can't find it anywhere but in Portuguese-language sites and videos, but the method is known as the "Rinaldini Method", and I believe this to be the name of the guy who invented it. Link in Portuguese Language Wikipedia: pt.wikipedia.org/wiki/Divisão_da_circunferência_em_partes_iguais_(processo_geral)
I have found references to the Bion method, and the Tempier method, which seem to be the same thing, somehow.
If you only used the second marker, what was the point of drawing the other segments?
Great Video!But i still don't now how it work😃
mark the inclined line as many times as you want divisions
Using this for building a roulette
I am trying dividing the circle into 11 equal parts with this method and I am not succesfull. One division is much smaller.
Why is not working?
This didn't work well with n=7 either. So off to try something else...
Why use 2 if you want 9 segments?
Great video!! So well explained! Could I ask you for a formula, or a written source like if n*6 x(distance)=… . My question is coming for a musical purpose. From Geometry and music theorised my EUCLID, in music we call them euclidian beats or patterns. The idea is, no matter the number of beats/hits they are always spread evenly around a circle. So I was looking around but never found a formula to put it in code form. Thanks in advance!
You would need to do that mathematically. It is not possible to divide a circle by any given number. Look up "constructible polygons" for proof.
@@elleeo1495 Yes. It simply can't be done for anything other than 2^n number of arcs (i.e., 2, 4, 8, 16, etc.) or 3 x 2^n number of arcs (i.e. 3, 6, 12, 24, 48, etc.), and certain other specific numbers including 5 x 2^n, 15x 2^n, 17 x 2^n, etc. or p x 2^n where p is the base number of sides of known constructible polygons.
Wow man ,
How to solve across flat if only diameter is available?
What am I doing wrong? My hash marks don't meet up at the apex of the circle, and they are skewed by a few degrees.
You expect correct results while using incorrect method. That is what you are doing wrong. Use trigonometry, you will see.
you have to be very accurate with hand drawn compass lines. here is a tip. draw with a bigger circle. your error in the angles will be smaller. good luck. or use a CAD or computer aided drawing program
HELP. HELP HELP,,,,A normal circle has 360 degrees,,,,,,how can i create a circle with 147 equal arcs of degree. Or to put it another way, How can i create a 360 degree circle, with a 260 mm diameter, divided into 147 segments of arc, each with an angle of 2.4489795 of a degree. Any help will stop me breaking down, regards Jim
With the following formula
_________________
╱
╱ ⎛ ⎛2 ⋅ π⎞⎞
L = R ⋅ ╱ 2 ⎜1 - cos ⎜───⎟⎟
╲╱
⎝ ⎝ n ⎠⎠
L is the side of the n-polygon inscribed in a circle with radius R.
That being said, unless you are using a computer, it is very hard to make a polygon with so many sides by hand.
Remember that 40 years ago in school. ^^ but why do you use Nr2 not 3 or 1? explaination is missing
Errors accumulate! ---- on a 13 division exercise, a 0.5 mm error on the first division leads to a 5mm error on the last one!
YES THIS GOOD, BECAUSE, STUDENT WISE FOR KNOWLEDGE NEED TO HAVE THAOUGHT, HOW TO MAKE DRAW CIRCLE AT ANY ANGLE OF DIGREE , LIKE 5 DEGREES , LIKE 10 DEGREES, LIKE 45 DEGREES, LIKE 90 DEGREES. IS THIS GOOD GIVEN KNOWLEDGE.
✌👌
Random width parallel lines, yeah good luck wit dat.
Better use your 45º and 30 set-squares
Why did I get ten divisions?
ruclips.net/video/vbdhPW1atu4/видео.html
Why we have to join Q to 2 only, why not any other point ???
Same question
Any idea?
Or any ratio is this?
Can this possible for other polygons?
I believe 2 is always used because the person drawing already knows the first point as 'A'. Since they're trying to find the second point on the circumference, they walk the line from Q through the second point on diameter to the circumference to find where the next point is for even sides. After 1 is 2 so they always pass the line through 2. Hope this helps.
because the metered line represents the WHOLE circumference... but your mark is only for half that circumference... as you are projecting the points out only to one side of the circle
No its notworing. I tried taking 25 parts but it didnot.
Followed your instructions and it didn’t work.
T
Highly inaccurate if you wish to divide your circle into anything above 10 sections.
Totally agree, for 10 better use this one
ruclips.net/video/vbdhPW1atu4/видео.html
Rfje
Let's see you draw those parallel lines by hand using that triangle...
Yes😭😭😭