(12C) log1p function
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01-31-2019, 01:10 AM
(This post was last modified: 02-01-2019 11:47 AM by Albert Chan.)
Post: #1
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(12C) log1p function
This trick is from John D Cook's Tricks for computing log(1+X)
I picked the formula from the comment section instead. The result is slightly more accurate, and no worry about divide by zero. log1p(X) = ln(1 + X) - (X + 1 - 1 - X) / (X + 1) Example: log1p(X = 1.23456789e-6) 1.23456789 [EEX] 6 [CHS] [Enter] ; X value [Enter] 1 + 1 - [X<>Y] - [CHS] ; epsilon => -4.3211e-10 [Lst-X] 1 + ÷ ; correction to epsilon => -4.321094e-10 [Lst-X] [LN] ; LN(1+X) => 1.234999237e-6 + ; log1p(X) => 1.234567128e-6 (all digits correct) |
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01-31-2019, 04:08 AM
Post: #2
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RE: (12C) log1p function
From HP-15C Advanced Functions Handbook
Level 1: Correctly Rounded, or Nearly So This trick is used e.g. in Accurate TVM for HP 35s and was adapted for the HP-15C and the HP-34C. Code: 01 ENTER Example: 1.23456789 EEX 6 CHS R/S 0.000001235 CLEAR PREFIX 1234567127 Cheers Thomas |
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01-31-2019, 05:48 AM
Post: #3
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RE: (12C) log1p function
This is how the WP 34S does this computation. One of Kahan's clever algorithms I believe.
- Pauli |
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01-31-2019, 08:45 AM
(This post was last modified: 01-31-2019 09:03 AM by Dieter.)
Post: #4
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RE: (12C) log1p function
(01-31-2019 01:10 AM)Albert Chan Wrote: This trick is from John D Cook's Tricks for computing log(1+X) What about this one: http://www.hpmuseum.org/forum/thread-1072.html But the key sequence you posted is not correct. There must be a second [ENTER] at the beginning and the end it's [LSTx] [LN] (without the "1"). Dieter |
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01-31-2019, 09:42 AM
Post: #5
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RE: (12C) log1p function
Hi, Dieter
Typo fixed. Thanks. A (quite) accurate ln1+x function, or "how close can you get" part II thread had the same formula. Was there a part I ? My rpn.exe confirmed +correction way much better, and avoided divide-by-0 test. Quote:>rpn |
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01-31-2019, 09:43 PM
(This post was last modified: 01-31-2019 09:46 PM by Dieter.)
Post: #6
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RE: (12C) log1p function
(01-31-2019 09:42 AM)Albert Chan Wrote: Typo fixed. Thanks. The second "Enter" at the beginning is still missing. Without it the code will not work. (01-31-2019 09:42 AM)Albert Chan Wrote: A (quite) accurate ln1+x function, or "how close can you get" part II thread had the same formula. Yes, but that was about Bernoulli numbers: http://www.hpmuseum.org/forum/thread-870.html But I also posted a similar method for the e^x–1 function: http://www.hpmuseum.org/forum/thread-5508.html (01-31-2019 09:42 AM)Albert Chan Wrote: My rpn.exe confirmed +correction way much better, and avoided divide-by-0 test. Please excuse me, Albert, but this is one more case where I see a lot of numbers and cryptic code, but I don't understand anything. Who may understand the meaning of "r 1+ =-10 s2 ? log s3 ? # 1+X, LN(1+X) value" ? Dieter |
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01-31-2019, 10:55 PM
(This post was last modified: 02-01-2019 01:02 PM by Albert Chan.)
Post: #7
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RE: (12C) log1p function
Hi, Dieter
2 Enters are there, but on 2 lines. First one after value entered. Regarding the cryptic commands, it was for my own toy rpn program. s for save memory, default to 0 r for recall memory, default to 0 = is round to digits, minus sign meant only for this number, otherwise globally # is starting comment, and ignored until end-of-line ? is display top of stack, default round to globally set digits (default 40) Code: RPN.EXE command HP-12C keys (approx.) |
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01-31-2019, 11:13 PM
Post: #8
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RE: (12C) log1p function
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Hi, Dieter: (01-31-2019 09:43 PM)Dieter Wrote: [...]I don't understand anything. Who may understand the meaning of "r 1+ =-10 s2 ? log s3 ? # 1+X, LN(1+X) value" ? Probably the same people who understands "UNROT OVER SWAP * DUP OBJ\-> DROP2 / 4. ROLL" ... (actual code, not made up) Regards. V. . All My Articles & other Materials here: Valentin Albillo's HP Collection |
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02-01-2019, 07:07 AM
Post: #9
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RE: (12C) log1p function
(01-31-2019 01:10 AM)Albert Chan Wrote: log1p(X) = ln(1 + X) + (X + 1 - 1 - X) / (X + 1) That should be ln(1 + X) - (X + 1 - 1 - X) / (X + 1) as the [CHS] in your instructions indicate, and then it's the same formula as Dieter's. Cheers, Werner 41CV†,42S,48GX,49G,DM42,DM41X,17BII,15CE,DM15L,12C,16CE |
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02-01-2019, 12:30 PM
(This post was last modified: 02-03-2019 02:28 AM by Albert Chan.)
Post: #10
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RE: (12C) log1p function
Hi Werner
Typo fixed. Thanks Y = 1+X, approximately eps = -(Y - 1 - X) Z = eps / Y ; correction to eps correction = LN(1+X, exactly) - LN(1+X, approximately) = LN(Y + eps) - LN(Y) = LN(1 + eps/Y) = LN(1 + Z) = Z - Z²/2 + Z³/3 ... -> log1p(X) ~ LN(Y) - (Y-1-X)/Y |
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02-02-2019, 12:28 PM
Post: #11
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RE: (12C) log1p function
(01-31-2019 11:13 PM)Valentin Albillo Wrote: Probably the same people who understands "UNROT OVER SWAP * DUP OBJ\-> DROP2 / 4. ROLL" ... (actual code, not made up) That's from DavidM's solution in your recent thread [VA] SRC#003- New Year 2019 Special: (01-17-2019 06:04 PM)DavidM Wrote: A similar approach using Thomas' first optimization: As always the context makes it easier to understand what a program does. Using a local variable M for the constant matrix might help as well: Code: « → M But nah, I didn't understand Albert Chan's cryptic commands until he explained them. Cheers Thomas |
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02-10-2019, 09:08 AM
(This post was last modified: 04-19-2022 01:27 AM by Albert Chan.)
Post: #12
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RE: (12C) log1p function
Dieter's asinh formula look very nice: log1p(x) = asinh ( (x²+2x)/(2x+2) ) = asinh(x - x/(2+2/x))
We can create "half angle" version, using symmetrical relation: atanh(sin(z)) = asinh(tan(z)) log1p(x) = 2 atanh( x/(x+2) ) = 2 asinh( x/ √((x+2)² - x²) ) log1p(x) = 2 asinh ( x/√(4x+4) ) Comment: it may be easier to derive relation with Arc SOHCAHTOA method, for hyperbolics atanhq(x²/(x+2)²) // TOA, O=x², A=(x+2)² = asinhq(x²/(4x+4)) // SOH, H = A-O = 4x+4 |
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02-10-2019, 02:19 PM
(This post was last modified: 02-11-2019 02:48 AM by Albert Chan.)
Post: #13
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RE: (12C) log1p function
Using relation again: atanh(sin(z)) = asinh(tan(z))
Assume x positive, but close to 0 atanh( 1-x ) = asinh( (1-x) / √(2x-x²) ) atanh( x-1 ) = -atanh( 1-x ) Example, x = 1.2345678e-9, using Casio FX-115MS, showing internal digits: atanh( 1-x ) = atanh(0.999999998766) = 10.6030760457 asinh( (1-x) / √(2x-x²) ) = asinh(20124.612604) = 10.6028460338 (all digits correct) Edit: another way, also very good: atanh( 1-x ) = ½ ln(2/x - 1) |
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