Π day
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03-20-2022, 07:28 PM
Post: #41
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RE: Π day | |||
03-21-2022, 07:24 AM
Post: #42
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RE: π day
Just stumbled upon this visual proof of Gregory’s Theorem:
Quote:Let \(I_k\) and \(C_k\) denote the areas of regular \(k\)-gons inscribed in and circumscribed around a given circle. So I thought I give it a try using the || operator of the WP-34S: Code: 001 RCL× Y Initialize the stack: 4 ENTER 2 RTN Calculate the sequence: R/S R/S R/S R/S … We end up with the same sequence as when using Vieta's formula. Hint: Select YDON in MODE to display both \(I_k\) and \(C_k\). 3.3137085 2.82842712475 3.18259788 3.06146745892 3.15172491 3.12144515226 3.14411839 3.13654849055 3.14222363 3.14033115695 3.14175037 3.14127725093 3.14163208 3.14151380114 3.14160251 3.14157294037 3.14159512 3.14158772528 3.14159327 3.14159142151 3.14159281 3.14159234557 3.14159269 3.14159257658 3.14159266 3.14159263434 3.14159266 3.14159264878 3.14159265 3.14159265239 3.14159265 3.14159265329 3.14159265 3.14159265351 3.14159265 3.14159265357 3.14159265 3.14159265359 3.14159265 3.14159265359 |
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03-21-2022, 04:03 PM
Post: #43
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RE: Π day | |||
03-21-2022, 05:27 PM
Post: #44
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RE: Π day
(03-21-2022 04:03 PM)Frido Bohn Wrote: How would the || operator translate into e.g., the HP41? It calculates the resistor if X and Y are in parallel: \( \begin{align} \frac{1}{R} = \frac{1}{X} + \frac{1}{Y} \end{align} \) Something like: Code: 1/X But if one of X or Y is 0 you might want to rather use: \( \begin{align} R = \frac{X \cdot Y}{X + Y} \end{align} \) Thus maybe: Code: RCL× Y However, you can't simply use this code snippet instead of || as register L won't contain the correct value. But I have no idea how the WP-34S calculates the result. |
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03-21-2022, 05:54 PM
Post: #45
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RE: π day
I came up with this for the HP-42S:
Code: 00 { 16-Byte Prgm } |
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03-21-2022, 06:33 PM
Post: #46
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RE: π day
(03-21-2022 05:27 PM)Thomas Klemm Wrote: But I have no idea how the WP-34S calculates the result. From xrom/parallel.wp34s: Code: /**************************************************************************/ Thus a bit shorter: Code: 00 { 6-Byte Prgm } |
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03-21-2022, 10:45 PM
Post: #47
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RE: Π day
(03-21-2022 07:24 AM)Thomas Klemm Wrote: We end up with the same sequence as when using Vieta's formula. Yes. For 2^n sided polygon, we have 2^(n+1) right triangles, with acute angle x = pi/2^n area(inscribled triangle) ≤ area(sector) ≤ area(circumscribed triangle) sin(x)*cos(x)/2 ≤ 1^2*x/2 ≤ 1*tan(x)/2 sin(2x)/(2x) ≤ 1 ≤ tan(x)/x I(2^n) = sin(2x)/(2x) * pi = sin(pi/2^(n-1)) / (pi/2^(n-1)) * pi = 2 / (cos(pi/4) * cos(pi/8) * ... * cos(pi/2^(n-1)) // Vieta's formula for pi Of course, the formula does not required 2^n sided polygons Example, we can start with hexagon: I(6) = 3/2*√3 ≈ 2.598, C(6) = 2*√3 ≈ 3.464 sin(2x)/(2x) = 1 - 2/3*x^2 + 2/15*x^4 + ... tan(x) / x = 1 + 1/3*x^2 + 2/15*x^4 + ... Circumscribed polygon area about twice as accurate as inscribed. (opposite sign) We can correct for this. Code: 10 N=6 @ A=SIN(PI/N*2)*N/2 @ B=TAN(PI/N)*N Code: >RUN We can apply Richardson extrapolation, to remove O(x^4) error >RES 3.14159268362 >RES + (RES-3.14159313412)/(2^4-1) 3.14159265359 For unit circle, circumscribed polygon perimeter = its area. Inscribed n-sided polygon perimeter = Inscribed 2n-sided polygon area. This make complicated polygon perimeter code un-necessary. |
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03-24-2022, 01:36 AM
Post: #48
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RE: Π day
(03-21-2022 10:45 PM)Albert Chan Wrote: Code:
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03-26-2022, 03:59 PM
Post: #49
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RE: Π day
(03-24-2022 01:36 AM)Gerson W. Barbosa Wrote: How is formula derived ? With angle x = pi/n, it has error of O(x^10) All dimensionless variables relative to size of pi (closer to 1 the better) XCAS> a,b := sin(x)/x, tan(x)/x; XCAS> c,d := a(x=x/2), b(x=x/2); XCAS> f := (640*c*(28*c-139*a)/(c-4*a) + 4*b*(3737+14256*b/(d-4*b)) +1056*d - 2568*a - 6453*(a^2*b)^(1/3)) / 11655 :; XCAS> float(series(f,x,0,13)) 1 + 4.42801658079e-05*x^10 + 3.58291832057e-05*x^12 + x^14*order_size(x) --- Another way to get pi, via asin(). r = (b-a)/(b+b) = (1-a/b)/2 = (1-cos(x))/2 = sin(x/2)^2 x/2 = asin(sqrt(r)) pi = 2n * asin(sqrt(r)) The problem with above is tiny errors of asin() get magnified by 2n. A better way is to start with good pi estimate, then correct to pi. A = sin(x)/x * pi pi = A * (2*x/2) / (2*sin(x/2)*cos(x/2)) = A/sqrt(1-r) * asin(sqrt(r)) / sqrt(r) = A/sqrt(1-r) * (1 + r/6 * (1 + r*3^2/(4*5) * (1 + r*5^2/(6*7) * (1 + r*7^2/(8*9) + ... XCAS> r := (b-a)/(b+b) :; XCAS> float(series(a/sqrt(1-r)*(1+r/6*(1+r*9/20*(1+r*25/42*(1+r*49/72)))),x,0,13)) 1.0 - 2.18478116122e-05*x^10 + 5.77706557054e-06*x^12 + x^14*order_size(x) With the terms shown, we already get relative error of pi to O(x^10) And, it is trivial to extend for more precisions. Tested with 48-sided polygon perimeter, inscribed and circumscribed. lua> n, A, B = 48, 3.1393502030468672, 3.1460862151314350 lua> r = (B-A)/(B+B) lua> A/sqrt(1-r) * (1+r/6*(1+r*9/20*(1+r*25/42*(1+r*49/72)))) 3.141592653589793 |
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03-26-2022, 05:37 PM
Post: #50
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RE: Π day
(03-26-2022 03:59 PM)Albert Chan Wrote:(03-24-2022 01:36 AM)Gerson W. Barbosa Wrote: The hard way: https://www.hpmuseum.org/cgi-sys/cgiwrap...ead=188443 Glad to know there are easier and better ways. Thank you very much! |
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03-26-2022, 11:24 PM
Post: #51
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RE: Π day
(03-26-2022 03:59 PM)Albert Chan Wrote: r = (b-a)/(b+b) = (1-a/b)/2 = (1-cos(x))/2 = sin(x/2)^2 Above is for n-sided polygon perimeter For n-sided polygon area, except for defintion of r, formula is exactly the same. A = sin(2x)/(2x) * pi = sin(x)*cos(x)/x * pi B = tan(x)/x * pi = sin(x)/cos(x)/x * pi r = (B-A)/B = 1-A/B = 1-cos(x)^2 = sin(x)^2 • n-sided inscribed polygon perimeter = 2n-side inscribed polygon area • (r for n-sided polygon perimeter) = (r for 2n-sided polygon area) Proof for n-sided polygon perimeters implied proof of 2n-sided polygon area. QED Note: we do not have to worry about odd-sided polygon area. Geometrically, n required to be positive integer. But, algebraically, it does not. From above defined A, B, this showed x = pi/n can be anything. In other words, formula for doubling of polygon sides does not require integer sides. A2 = sqrt(A*B) = sin(x)/x * pi B2 = 2/(1/A2 + 1/B) = 2*A2 / (1 + A2/B) = 2*sin(x)/x * pi / (1+cos(x)) = sin(x)/(1+cos(x)) / (x/2) * pi = tan(x/2) / (x/2) * pi |
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03-27-2022, 01:44 PM
(This post was last modified: 03-30-2022 01:20 AM by Albert Chan.)
Post: #52
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RE: Π day
If arugment for asin is big, taylor series take a long time to converge.
Ratio of coefficient = (2k+1)^2 / ((2k+2)*(2k+3)), approach 1 when k is huge. For asin(1), this implied dropped term is almost same size as the last kept term. We can use the "half-angle" formula for asin() (05-31-2021 07:30 PM)Albert Chan Wrote: \(\displaystyle\arcsin(x) = 2\arcsin\left( {x \over \sqrt{2\sqrt{1-x^2}+2}} \right)\) Code: function asinq(x) -- = asin(sqrt(x)) lua> asinq(1/4), pi/6 0.5235987755982989 0.5235987755982988 lua> asinq(2/4), pi/4 0.7853981633974483 0.7853981633974483 lua> asinq(3/4), pi/3 1.0471975511965979 1.0471975511965976 lua> asinq(4/4), pi/2 1.5707963267948966 1.5707963267948966 Another way is to use Carlson Elliptic Integrals: RC(1-x,1) = asin(√x)/(√x) Code: function RC(x,y, verbose) -- RC(1-x,1) = asin(sqrt(x))/sqrt(x) This is a simplified version of RF, RC(x,y) = RF(x,y,y) see https://www.hpmuseum.org/forum/thread-17...#pid148498 It has no problem getting asin(1)/1 = pi/2, 1 sqrt per iteration lua> RC(1-1, 1, true) 1.7320508075688772 1.5764775210064272 1.5711174700143078 1.5708159330462599 1.5707975451380392 1.570796402832061 1.5707963315455151 1.5707963270917837 1.5707963268134517 1.5707963267960565 1.5707963267949692 1.5707963267949012 1.570796326794897 1.5707963267948968 1.5707963267948968 Another example, from area of inscribed and circumsribed square, for pi lua> A, B = 2, 4 lua> r = (B-A)/B -- = 1/2 lua> c = RC(1-r, 1, true) -- = asin(sqrt(1/2)) / sqrt(1/2) = pi/4 * sqrt(2) 1.1147379454918027 1.1109478170877694 1.1107345982528842 1.1107215960382895 1.1107207883059862 1.110720737898786 1.1107207347495225 1.110720734552712 1.1107207345404118 1.1107207345396428 1.1107207345395949 1.1107207345395917 1.1107207345395915 lua> A * c/sqrt(1-r) 3.141592653589793 lua> A * asinq(r)/sqrt(r-r*r) 3.141592653589793 |
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03-27-2022, 04:00 PM
Post: #53
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RE: Π day
Here is getting C(x) = asin(√x)/(√x), using "half-angle" formula for asin
Code: function C(x) -- = asin(sqrt(x)) / sqrt(x) Redo both previous examples in 1 go, with less calculations (2 sqrt per recursion) Code: lua> C(1) |
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03-31-2022, 02:04 AM
Post: #54
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RE: Π day
This (new) paper has some nice error estimates for various summation orders.
As a bonus, there's also a nice skeleton code of each method. |
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04-02-2022, 03:14 AM
Post: #55
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RE: Π day
(03-19-2022 11:18 AM)Ángel Martin Wrote: Heresy or new truth? I have eaten pie, I'm not even sure what I would bring to share with cow-orkers on June 28th to celebrate Tau Day. 10B, 10BII, 10C, 11C, 12C, 14B, 15C, 16C, 17B, 18C, 19BII, 20b, 22, 25, 29C, 35, 38G, 39G, 39gs, 41CV, 48G, 97 |
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04-02-2022, 11:12 AM
(This post was last modified: 04-02-2022 11:14 AM by floppy.)
Post: #56
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RE: Π day
(03-14-2022 11:06 PM)ttw Wrote: One can often apply various sequence transformations to speed up these series. A couple of new methods are given here.Interesting. When I see PI, I am remembering of page 51 of the "exact" PI formula http://semjonadlaj.com/SP/Computer+Algeb..._37-56.pdf we have there an highspeed-convergency HP71B 4TH/ASM/Multimod, HP41CV/X/Y & Nov64d, PILBOX, HP-IL 821.62A & 64A & 66A, Deb11 64b-PC & PI2 3 4 w/ ILPER, VIDEO80, V41 & EMU71, DM41X |
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