Where do the radical expressions for the trig functions of various rational multiples of $pi$ come from?
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So if you look on the Wikipedia page for "Trigonometric constants expressed as real radicals", you will get a boatload of formulas for the trig functions of various rational multiples of $pi$.
My question is, how were all these formulas deduced and/or derived? What is the proof that these formulas are correct? And are there any more potential formulas like this that can be derived, but not found by a mathematician?
trigonometry
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add a comment |
$begingroup$
So if you look on the Wikipedia page for "Trigonometric constants expressed as real radicals", you will get a boatload of formulas for the trig functions of various rational multiples of $pi$.
My question is, how were all these formulas deduced and/or derived? What is the proof that these formulas are correct? And are there any more potential formulas like this that can be derived, but not found by a mathematician?
trigonometry
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2
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Can you link to the page or write a few of the formulas down? Usually a brief explanation is given as to how to the formulas are derived; regarding formulas that might exist undiscovered...probably, but if nobody has found it, we couldn’t know.
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– Clayton
Dec 9 '18 at 14:47
2
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The values are typically derived by taking the simplest cases (for, say, $pi/2$, $pi/3$, $pi/4$, and others that arise from various constructible regular polygons), hitting them with half-angle identities to get really small values, and then using multiple-angle identities. It's a pretty mechanical process, and more-or-less how trig tables were generated for centuries before we had calculators, so there's not much new to do in this space. However, finding "nice" forms and/or patterns, can be an interesting challenge. See this answer.
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– Blue
Dec 9 '18 at 14:59
$begingroup$
You can see from the banner that the "page might contain original research".
$endgroup$
– John Glenn
Dec 9 '18 at 15:09
add a comment |
$begingroup$
So if you look on the Wikipedia page for "Trigonometric constants expressed as real radicals", you will get a boatload of formulas for the trig functions of various rational multiples of $pi$.
My question is, how were all these formulas deduced and/or derived? What is the proof that these formulas are correct? And are there any more potential formulas like this that can be derived, but not found by a mathematician?
trigonometry
$endgroup$
So if you look on the Wikipedia page for "Trigonometric constants expressed as real radicals", you will get a boatload of formulas for the trig functions of various rational multiples of $pi$.
My question is, how were all these formulas deduced and/or derived? What is the proof that these formulas are correct? And are there any more potential formulas like this that can be derived, but not found by a mathematician?
trigonometry
trigonometry
edited Dec 9 '18 at 14:52
Blue
48.4k870154
48.4k870154
asked Dec 9 '18 at 14:44
Xavier StantonXavier Stanton
311211
311211
2
$begingroup$
Can you link to the page or write a few of the formulas down? Usually a brief explanation is given as to how to the formulas are derived; regarding formulas that might exist undiscovered...probably, but if nobody has found it, we couldn’t know.
$endgroup$
– Clayton
Dec 9 '18 at 14:47
2
$begingroup$
The values are typically derived by taking the simplest cases (for, say, $pi/2$, $pi/3$, $pi/4$, and others that arise from various constructible regular polygons), hitting them with half-angle identities to get really small values, and then using multiple-angle identities. It's a pretty mechanical process, and more-or-less how trig tables were generated for centuries before we had calculators, so there's not much new to do in this space. However, finding "nice" forms and/or patterns, can be an interesting challenge. See this answer.
$endgroup$
– Blue
Dec 9 '18 at 14:59
$begingroup$
You can see from the banner that the "page might contain original research".
$endgroup$
– John Glenn
Dec 9 '18 at 15:09
add a comment |
2
$begingroup$
Can you link to the page or write a few of the formulas down? Usually a brief explanation is given as to how to the formulas are derived; regarding formulas that might exist undiscovered...probably, but if nobody has found it, we couldn’t know.
$endgroup$
– Clayton
Dec 9 '18 at 14:47
2
$begingroup$
The values are typically derived by taking the simplest cases (for, say, $pi/2$, $pi/3$, $pi/4$, and others that arise from various constructible regular polygons), hitting them with half-angle identities to get really small values, and then using multiple-angle identities. It's a pretty mechanical process, and more-or-less how trig tables were generated for centuries before we had calculators, so there's not much new to do in this space. However, finding "nice" forms and/or patterns, can be an interesting challenge. See this answer.
$endgroup$
– Blue
Dec 9 '18 at 14:59
$begingroup$
You can see from the banner that the "page might contain original research".
$endgroup$
– John Glenn
Dec 9 '18 at 15:09
2
2
$begingroup$
Can you link to the page or write a few of the formulas down? Usually a brief explanation is given as to how to the formulas are derived; regarding formulas that might exist undiscovered...probably, but if nobody has found it, we couldn’t know.
$endgroup$
– Clayton
Dec 9 '18 at 14:47
$begingroup$
Can you link to the page or write a few of the formulas down? Usually a brief explanation is given as to how to the formulas are derived; regarding formulas that might exist undiscovered...probably, but if nobody has found it, we couldn’t know.
$endgroup$
– Clayton
Dec 9 '18 at 14:47
2
2
$begingroup$
The values are typically derived by taking the simplest cases (for, say, $pi/2$, $pi/3$, $pi/4$, and others that arise from various constructible regular polygons), hitting them with half-angle identities to get really small values, and then using multiple-angle identities. It's a pretty mechanical process, and more-or-less how trig tables were generated for centuries before we had calculators, so there's not much new to do in this space. However, finding "nice" forms and/or patterns, can be an interesting challenge. See this answer.
$endgroup$
– Blue
Dec 9 '18 at 14:59
$begingroup$
The values are typically derived by taking the simplest cases (for, say, $pi/2$, $pi/3$, $pi/4$, and others that arise from various constructible regular polygons), hitting them with half-angle identities to get really small values, and then using multiple-angle identities. It's a pretty mechanical process, and more-or-less how trig tables were generated for centuries before we had calculators, so there's not much new to do in this space. However, finding "nice" forms and/or patterns, can be an interesting challenge. See this answer.
$endgroup$
– Blue
Dec 9 '18 at 14:59
$begingroup$
You can see from the banner that the "page might contain original research".
$endgroup$
– John Glenn
Dec 9 '18 at 15:09
$begingroup$
You can see from the banner that the "page might contain original research".
$endgroup$
– John Glenn
Dec 9 '18 at 15:09
add a comment |
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Can you link to the page or write a few of the formulas down? Usually a brief explanation is given as to how to the formulas are derived; regarding formulas that might exist undiscovered...probably, but if nobody has found it, we couldn’t know.
$endgroup$
– Clayton
Dec 9 '18 at 14:47
2
$begingroup$
The values are typically derived by taking the simplest cases (for, say, $pi/2$, $pi/3$, $pi/4$, and others that arise from various constructible regular polygons), hitting them with half-angle identities to get really small values, and then using multiple-angle identities. It's a pretty mechanical process, and more-or-less how trig tables were generated for centuries before we had calculators, so there's not much new to do in this space. However, finding "nice" forms and/or patterns, can be an interesting challenge. See this answer.
$endgroup$
– Blue
Dec 9 '18 at 14:59
$begingroup$
You can see from the banner that the "page might contain original research".
$endgroup$
– John Glenn
Dec 9 '18 at 15:09