Small RPN exponential routine
|
01-27-2015, 08:52 PM
(This post was last modified: 12-27-2023 12:51 AM by Thomas Klemm.)
Post: #21
|
|||
|
|||
RE: Small RPN exponential routine
(01-27-2015 12:56 PM)Eddie W. Shore Wrote: Is this the origin for the LPN1 function? (I need to be here more often) Not sure if you mean LN1+X for the HP-41C or log1p in Python: Quote: log1p(x) At least in case of HP-calculators the CORDIC algorithm is used and not the Taylor Series of \(\ln(1+x)\): Thus I might disappoint you: these are not the same. Cheers Thomas |
|||
01-30-2019, 07:21 PM
(This post was last modified: 01-30-2019 07:56 PM by Albert Chan.)
Post: #22
|
|||
|
|||
RE: Small RPN exponential routine
(01-27-2015 08:52 PM)Thomas Klemm Wrote: At least in case of HP-calculators the CORDIC algorithm is used and not the Taylor Series of \(\ln(1+x)\): There is a faster series for ln(1+x), let y = x/(x+2), thus |y| < 1 ln(1+x) = ln( ((x+2)+x) / ((x+2)-x) ) = ln( (1 + y) / (1 - y) ) = 2 * (y + y^3/3 + y^5/5 + y^7/7 + ...) Using post 4 example of ln(0.52) : For 12 digits accuracy, original ln(1+x) series required 33 terms, y transformed series only 12. x = 0.52-1 = -0.48 y = -0.48/1.52 = -0.315789473684 ln(0.52) = -0.653926467406 (sumed 12 terms, upto y^21/21) But, we can do better! |y| can be reduced furthur by scaling. With 1+x between 1 and exp(1), worst case is if scaling does not help. -> 1+x <= 2/(1+exp(-1)) = 1.46212 ->|y| <= (exp(1)-1)/(3*exp(1)+1) = 0.187691 -> For 12 digits accuracy, term y^15/15 and beyond can be ignored. Redo above with scaling, sum maximum of 6 terms: Scaled argument = [1/1.46212, 1.46212) = [0.68394, 1.46212) ln(0.52) = ln(0.52 * exp(1)) - 1 = ln(1.41350655080) - 1 x = 0.41350655080 y = x/(x+2) = 0.171330196167 ln(0.52) = 2*y + correction - 1 = 0.342660392334 + 0.00341314025930 - 1 = -0.653926467407 |
|||
« Next Oldest | Next Newest »
|
User(s) browsing this thread: 2 Guest(s)