Programming Exercise (HP-15C, 15C LE - and others)
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04-15-2014, 04:41 PM
(This post was last modified: 04-15-2014 04:49 PM by Gerson W. Barbosa.)
Post: #101
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RE: Programming Exercise (HP-15C, 15C LE - and others)
(04-06-2014 06:24 AM)Thomas Klemm Wrote: Now we have 3 different ways to calculate the same thing: Isn't this the same method used by Valentin in his original problem, only in continued fraction format? Anyway, the formula appears to hold, even when we have only two terms of the series, albeit converging very slowly in this case: \[\ln (2)= 1-\frac{1}{2}+\frac{1}{3}-\frac{1}{4}+\cdots +\frac{1}{n-1}-\frac{1}{n}+\frac{1}{2n+1+\frac{1^{2}}{2n+1+\frac{2^{2}}{2n+1+\frac{3^{2}}{2n+1+\frac{4^{2}}{2n+1+... }}}}}\] ...ln(2) = 0.6931471805599453094172321214581766 0001e000 2 0.6923076923076923076923076923076923 0001e001 2 0.6931477851289172043889025021100493 0001e002 2 0.6931471805715443422837621214224286 0001e003 2 0.6931471805599454334834722951537730 0001e004 2 0.6931471805599453094184811843330782 0001e005 2 0.6931471805599453094172321339572391 0001e006 2 0.6931471805599453094172321214583016 0001e007 2 0.6931471805599453094172321214581766 Here is a similar formula for π/4: \[\frac{\pi }{4}= 1-\frac{1}{3}+\frac{1}{5}-\frac{1}{7}+\cdots +\frac{1}{2n-3}-\frac{1}{2n-1}+\frac{1}{4n+\frac{1^{2}}{n+\frac{2^{2}}{4n+\frac{3^{2}}{n+\frac{4^{2}}{4n+... }}}}}\] .......π = 3.141592653589793238462643383279503 00000009 2 3.141574838064079287182344939989334 00000099 2 3.141592651424974945646180479799372 00000999 2 3.141592653589572786959492672266442 00009999 2 3.141592653589793216377737847078192 00099999 2 3.141592653589793238460434495123538 00999999 2 3.141592653589793238462643162386710 09999999 2 3.141592653589793238462643383257414 99999999 2 3.141592653589793238462643383279500 About 2d/3 terms of the series and of the continued fraction, where d is the number of desired correct decimal places, appear to suffice: 0000010 10 0.6931471805599454035014297564573935 0000022 22 0.6931471805599453094172321214581766 0000011 10 3.141592653589793130085240933000310 0000021 22 3.141592653589793238462643383279502 This is the program to compute π: Code:
Again, the second parameter has to be even. Also, due to a program limitation the first parameter has to be odd. Cheers, Gerson. |
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04-15-2014, 06:25 PM
Post: #102
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RE: Programming Exercise (HP-15C, 15C LE - and others)
(04-15-2014 04:41 PM)Gerson W. Barbosa Wrote: Isn't this the same method used by Valentin in his original problem, only in continued fraction format?It appears to be the same but I was just curious how Euler's transformation is related to your continued fraction. Quote:Here is a similar formula for π/4: Very nice! Thanks for being so persistent. Cheers Thomas |
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04-20-2014, 03:17 AM
(This post was last modified: 04-21-2014 08:43 PM by Gerson W. Barbosa.)
Post: #103
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RE: Programming Exercise (HP-15C, 15C LE - and others)
(04-15-2014 06:25 PM)Thomas Klemm Wrote:(04-15-2014 04:41 PM)Gerson W. Barbosa Wrote: Isn't this the same method used by Valentin in his original problem, only in continued fraction format?It appears to be the same but I was just curious how Euler's transformation is related to your continued fraction. If we take only one term of the series then the continued fraction becomes \[\frac \pi 4 = 1-\cfrac{1}{4+\cfrac{1^2}{1+\cfrac{2^2}{4+\cfrac{3^2}{1+\cfrac{4^2}{4+\cfrac{5^2}{1+\ddots}}}}}}\] which resembles Brouncker's formula: \[\frac 4 \pi = 1+\cfrac{1^2}{2+\cfrac{3^2}{2+\cfrac{5^2}{2+\cfrac{7^2}{2+\cfrac{9^2}{2+\ddots}}}}}\] The latter, equivalent to the Gregory series, doesn't include even squares and converges more slowly: ...........n .....result................n .....result 000000000001 3.00000000000000000000000001 2.66666666666667 000000000010 3.14513671429771000000000010 3.23231580940559 000000000100 3.14163153155977000000000100 3.15149340107099 000000001000 3.14159304589625000000001000 3.14259165433954 000000010000 3.14159265751639000000010000 3.14169264359054 000000100000 3.14159265362906000000100000 3.14160265348979 000001000000 3.14159265359019000001000000 3.14159365358879 000010000000 3.14159265358980000010000000 3.14159275358978 00000000000000000000000000000000100000000 3.14159266358979 00000000000000000000000000000001000000000 3.14159265458979 But what has intrigued me is this part of an article on William Brouncker's biography, which reads: "This result, written up in around ten pages, was added by Wallis to his treatise Arithmetica Infinitorum and probably first discovered by Brouncker in 1654. Wallis told Huygens of this result and Huygens expressed strong doubts that it was true. However after Brouncker correctly computed the first 10 places in the decimal expansion of π using his continued fraction expansion, Huygens accepted the result." From the table above, we know this would have required the computation of 10^9 terms of the continued fraction, an impossible task to do by hand. However, one hundred and twenty terms could well have been computed in a week or less. Then a simple weighted mean, the weights being two successive number of terms, might have given about 10 decimal places, provided, of course, he was able to explain why this apparently works - I am not :-) Code:
...n .........p1 = p(n-1)............p2 = p(n)......pi~((n-1)*p1+n*p2)/(2*n-1) 00010.....3.0418396189294022.....3.2323158094055927.....3.1416128615597877 00020.....3.0916238066678386.....3.1891847822775947.....3.1415940624679576 00030.....3.1082685666989461.....3.1738423371907494.....3.1415929418669117 00040.....3.1165965567938323.....3.1659792728432150.....3.1415927463990754 00050.....3.1215946525910105.....3.1611986129870501.....3.1415926919989117 00060.....3.1249271439289964.....3.1579849951686658.....3.1415926722399041 00070.....3.1273076679812339.....3.1556764623074750.....3.1415926637057950 00080.....3.1290931417757212.....3.1539378622726156.....3.1415926595412395 00090.....3.1304818853613080.....3.1525813328751202.....3.1415926573157661 00100.....3.1315929035585528.....3.1514934010709906.....3.1415926560399270 00110.....3.1325019323081855.....3.1506014798194977.....3.1415926552663559 00120.....3.1332594649198298.....3.1498569752932738.....3.1415926547753764 00130.....3.1339004596806044.....3.1492261301786887.....3.1415926544516736 00140.....3.1344498875489983.....3.1486847629938381.....3.1415926542312845 00150.....3.1349260609930860.....3.1482150975379365.....3.1415926540770475 Madhava's correction terms (14th century), might as well have been used. This appears to be quite an ancient game! Regarding the generic continued fraction for Ln(2), if no term of the original series is taken, that is, if n = 0, then the resulting continued fraction will be equivalent to the original series itself. A WP 34S program takes about 20 seconds to evaluate all 10000 terms though. Cheers, Gerson. Edited to fix a couple of typos. P.S.: As shown above, the very slowly convergent Brouncker's formula (equivalent to the Gregory series) can be sped up by a simple weighted mean, although not nearly as effectively as the other methods. Anyway, 3000 terms would give 15 correct digits. The plain series or continued fraction would require 10^14 terms to yield the same accuracy. Code:
This is a GW BASIC version of the Turbo Pascal code above. RUN 1000...3.140592653839793...3.142591654339543...3.141592653590043 1125...3.142481542303099...3.140704554297768...3.141592653589638 1250...3.140792653717793...3.142392013973691...3.141592653589896 1375...3.142319926220898...3.140865909499706...3.141592653589724 1500...3.140925986997201...3.142258876034188...3.141592653589843 1625...3.142208038146917...3.140977647497886...3.141592653589757 1750...3.141021225065012...3.142163755770525...3.141592653589820 1875...3.142125986885201...3.141059604587147...3.141592653589773 2000...3.141092653621043...3.142092403683528...3.141592653589809 2125...3.142063241799034...3.141122286729639...3.141592653589781 2250...3.141148209167297...3.142036900569207...3.141592653589803 2375...3.142013706202711...3.141171778187556...3.141592653589785 2500...3.141192653605793...3.141992493637787...3.141592653589800 2625...3.141973605956924...3.141211846292098...3.141592653589788 2750...3.141229017238178...3.141956157758083...3.141592653589798 2875...3.141940479666230...3.141244948454266...3.141592653589790 3000...3.141259320265719...3.141925875839790...3.141592653589796 Ok PRINT TAB(47) 4*ATN(1#) ...............................................3.141592653589793 Ok |
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