Yet another π formula
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11-25-2024, 01:47 PM
(This post was last modified: 11-25-2024 06:50 PM by Albert Chan.)
Post: #21
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RE: Yet another π formula
(11-24-2024 08:17 PM)Gerson W. Barbosa Wrote: Mine is slower: ~ 1'33" Not really. It is comparing apples and oranges. Your calculations sum 5 terms (ignored the 1/2), and correct with CF factor 6 levels deep. Summation of infinite alternative series do 0 .. (n=10) = 11 terms, and 0 .. (d=7) = 8 (Δk/2k+1) terms. To match same number of 'terms', we set n = 5-1 = 4 , d = 6-1 = 5 Note: S=S1-S2 because n is even, otherwise it would be S=S1+S2 lua> S1 = 1/(1*3) - 1/(3*5) + 1/(5*7) - 1/(7*9) + 1/(9*11) lua> S2 = 0.5/(11*13) * (1 + 2/15*(1 + 3/17*(1 + 4/19*(1 + 5/21*(1 + 6/23))))) lua> (S1-S2)*4 + 2 3.1415943802536885 This is only half as many good digits as your 5 terms + correction pi estimate. Even with n=10, d=7, getting pi estimate ≈ 3.141592654 is still not as good. lua> n = 10 lua> S1 = 0 lua> for i=n,0,-1 do S1=1/((2*i+2)^2-1) - S1 end lua> S1 0.28633982191661556 For S2, we can do calculations inside out, but I rather do this left to right. We can Euler-transform it as continued fraction, and do convergents of continued fraction. Code: function dfc2f_euler(b0) -- b0 + a0*(1+a1*(1+a2*(1+a3*(... lua> f = dfc2f_euler(0) -- euler-transform S2 as CF lua> S2 = f(0.5/((2*n+3)*(2*n+5))) -- 0th term lua> for k=1,7 do S2 = f( (k+1) / (2*(n+k)+5) ) end lua> S2 0.000941658270090828 lua> (S1-S2)*4 + 2 3.141592654586099 We would need to push S2 d from 7 to 20 to reach full precision lua> for i=8,20 do S2 = f( (i+1) / (2*(n+i)+5) ) end lua> S2 0.0009416585191672306 lua> (S1-S2)*4 + 2 3.141592653589793 |
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11-25-2024, 04:45 PM
Post: #22
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RE: Yet another π formula
(11-25-2024 01:47 PM)Albert Chan Wrote:(11-24-2024 08:17 PM)Gerson W. Barbosa Wrote: Mine is slower: ~ 1'33" Indeed apples and apples (or oranges and oranges). 1'33" is the time it took for Thomas Klemm’s program to run on my HP-15C. I only meant my HP-15C is slower than his. I thought of writing an HP-15C program to compare both methods, but I didn’t. Sorry for the confusion! |
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11-25-2024, 06:47 PM
Post: #23
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RE: Yet another π formula
(11-25-2024 04:45 PM)Gerson W. Barbosa Wrote: I only meant my HP-15C is slower than his. To be honest, I was using the following emulator: Quote:HP-15C I had assumed that it was running at the same time as the original. It is apparently running a bit faster, but still in the same ballpark. |
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11-25-2024, 10:01 PM
Post: #24
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RE: Yet another π formula
Σ((-1)^k/(2k+1), k=0..inf) = atan(1) = pi/4
Σ((-1)^k/(2k+1)/(2k+3), k=0..inf) = (pi/4 - 0.5/(1)) / 1 = pi/4 - 1/2 Σ((-1)^k/(2k+1)/(2k+3)/(2k+5), k=0..inf) = ((pi/4 - 1/2) - 0.5/(1*3)) / 2 = pi/8 - 1/3 ... With this pattern, we can build formula for left hand side, S = pi / c1 - c2 lua> N = 40 -- number of consecutive odd numbers for LHS denominator lua> c1, c2, t = 4, 0, 1 -- start from atan(1) = pi/4 lua> for i=2,N do c1=c1*(i-1); c2=(c2+0.5/t)/(i-1); t=t*(2*i-1) end pi = c1*c2 + c1*S lua> c1*c2 -- close enough to pi, we only need tiny correction. 3.141592653588783 lua> c1*c2 + c1 * (1-1/(2*N+1))/t -- 2 terms for S 3.141592653589793 |
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11-26-2024, 01:32 AM
(This post was last modified: 11-26-2024 11:54 AM by Albert Chan.)
Post: #25
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RE: Yet another π formula
From previous post, if we ignore S correction, with goal of c1 * c2 = pi, we get this.
\(\displaystyle \frac{\pi}{2} = \sum _{k=0}^∞ \frac {k!}{(2k+1)!!}\) Formula approximately doubled its accuracy after each sum. This explained why previous post, with N=40, c1*c2 get about 40 bits accuracy of pi. To speed up convergence, we can "double" the last term. pi/2 = 1 + 1/3 + 2/15 + 6/105 + 24/945 + ... = (2-1) + (2/3-1/3) + (4/15-2/15) + (12/105-6/105) + (48/945-24/945) + ... = 2 - (1-2/3) - (1/3-4/15) - (2/15-12/105) - (6/105-48/945) - ... k!/(2k+1)!! - 2*(k+1)!/(2k+3)!! = k!/(2k+3)!! Again, we have a pattern here Code: pi/2 = 0 + sum(k!/(2k+1)!!, k=0..inf) Ignore the sum part, we goes full circle pi/2 = 2/1 - 2/3 + 2/5 - 2/7 + ... = 2 * atan(1) |
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11-26-2024, 01:28 PM
(This post was last modified: 11-26-2024 02:18 PM by Albert Chan.)
Post: #26
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RE: Yet another π formula
(11-25-2024 01:47 PM)Albert Chan Wrote: To match same number of 'terms', we set n = 5-1 = 4 , d = 6-1 = 5 FYI, above convergence acceleration scheme is EXACTLY the same as my previous post. pi/2 = (2 - 2/3 + 2/5 - 2/7 + 2/9) - 9!! * sum(k!/(2k+11)!!, k=0..inf) lua> s1 = (2 - 2/3 + 2/5 - 2/7 + 2/9) lua> s2 = 1/11*(1 + 1/13*(1 + 2/15*(1 + 3/17*(1 + 4/19*(1 + 5/21*(1 + 6/23)))))) lua> (s1-s2)*2 3.141594380253689 |
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11-26-2024, 02:09 PM
Post: #27
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RE: Yet another π formula
I like this double factorial approach. Here it is in BBC Basic:
Code: PRINT "Calculate Pi with double factorial" |
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11-26-2024, 02:19 PM
Post: #28
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RE: Yet another π formula
Or just use 3 (close enough for most real-life applications) or see
https://www.piday.org/million/ A1 HP-15C (2234A02xxx), HP-16C (2403A02xxx), HP-15C CE (9CJ323-03xxx), HP-20S (2844A16xxx), HP-12C+ (9CJ251) |
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11-26-2024, 03:42 PM
Post: #29
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RE: Yet another π formula
(11-26-2024 02:19 PM)AnnoyedOne Wrote: https://www.piday.org/million/Thank you for the link! I just found my date of birth in the decimal of PI. Does that mean anything? How do I find my date of death? |
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11-26-2024, 05:37 PM
Post: #30
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RE: Yet another π formula
(11-26-2024 03:42 PM)C.Ret Wrote: How do I find my date of death? No idea. But you might be eating pi(e) at the time A1 HP-15C (2234A02xxx), HP-16C (2403A02xxx), HP-15C CE (9CJ323-03xxx), HP-20S (2844A16xxx), HP-12C+ (9CJ251) |
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11-26-2024, 05:57 PM
(This post was last modified: 11-26-2024 08:02 PM by Albert Chan.)
Post: #31
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RE: Yet another π formula
Hi, EdS2
Here are improvements over your BBC Basic code. 1. k! / (2k+1)!!, numerator and denominator get huge very quickly We can let T = N/D, eliminate possible overflow issue. 2. 2k+1 replaced by 2k+p with p=1, for usage flexibility (see example below) 3. Instead of add last term for better pi estimate, I use Aitken extrapolated result. 4. Added plain 2*S pi estimate for comparison Code: 10 print "Calculate Pi with double factorial" BTW, my original Aitken code is this. Code: 40 T0=T:T=T*K/(2*K+P):S=S+T But I like D = 2+P/K ≈ 2 version better. It clearly showed T=T/D shrink to about half, thus sum accuaracy doubled per step. Also, it showed why add last term T to S improve estimate. Correction T/(D-1) ≈ T (11-26-2024 01:28 PM)Albert Chan Wrote: pi/2 = (2 - 2/3 + 2/5 - 2/7 + 2/9) - 9!! * sum(k!/(2k+11)!!, k=0..inf) For this example, we change 1 line (run on DOS ubasic) Note: we start from k=1, thus k=0 correction goes to S. 20 L=6:P=11:T=-1/P:S=2-2/3+2/5-2/7+2/9+T run Calculate Pi with double factorial 3.1427128427128427129 3.1438783438783438784 3.1417266494189571114 3.1420135420135420136 3.1416139416139416141 3.1416844593315181551 3.1415967039496451264 3.1416151787668815534 3.1415935285904326155 3.1415986833943490292 3.1415928614981610796 3.1415943802536883708 OK |
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Yesterday, 09:14 AM
Post: #32
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RE: Yet another π formula
Nice, thanks!
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