@Thomas Klemm > CORDIC Article

05312014, 08:00 PM
Post: #1




@Thomas Klemm > CORDIC Article
Hi Thomas, thanks for your posting.
This was a huge discovery for me a few years ago thanks to the internet I finally understood the secrets of calculators. Before that I thought there was some tricky use of limited developments... This little algorithm is truly amazing, apparently the Prime still uses it today. Wonder if math coprocessors also rely on it. Could be a good idea to extend the article to all the possibilities of CORDIC? 

06012014, 02:27 AM
Post: #2




RE: @Thomas Klemm > CORDIC Article
(05312014 08:00 PM)Tugdual Wrote: Wonder if math coprocessors also rely on [CORDIC] Some of the early ones (Intel 8087, Motorola MC68881) did. It's my understanding that more recent systems, both hardware and software, tend to use other algorithms to get faster convergence. See _Elementary Functions: Algorithms and Implementation, 2nd Ed._ by JeanMichel Muller. 

06012014, 07:32 AM
Post: #3




RE: @Thomas Klemm > CORDIC Article
(05312014 08:00 PM)Tugdual Wrote: This little algorithm is truly amazing, apparently the Prime still uses it today. The WP34S however uses: Code: // Now Taylor series Quote:Could be a good idea to extend the article to all the possibilities of CORDIC? I left that as an exercise for the interested reader. Cheers Thomas 

06012014, 11:57 AM
Post: #4




RE: @Thomas Klemm > CORDIC Article
(06012014 07:32 AM)Thomas Klemm Wrote: The WP34S however uses:Interesting, I wonder what justified the choice. A matter of patent? What is the most efficient approach in terms of speed and accuracy between CORDIC and Taylor? Or may be CORDIC was the right choice for old calculators with little ROM? 

06012014, 12:12 PM
(This post was last modified: 06012014 12:14 PM by Paul Dale.)
Post: #5




RE: @Thomas Klemm > CORDIC Article
(06012014 11:57 AM)Tugdual Wrote: Interesting, I wonder what justified the choice. I honestly don't remember why I chose this approach over others. My guess would be a matter of expediency, I had a lot to implement quickly. A taylor expansion is easy to write and generally quite small. They aren't always the most numerically stable methods. There aren't patent issues for these series that I'm aware of  too well known to an expert in the field. Quote:What is the most efficient approach in terms of speed and accuracy between CORDIC and Taylor? Taylor series generally can be made as accurate as you want by adding additional terms  this being important early on when the working precision wasn't set in stone. CORDIC requires a bit more effort to increase its accuracy, more iterations and more constants. Speed wise, I doubt there is much difference a lot of the time  at the least, I don't have a good feel for the differences. However, remember the 34S CPU can do integer multiplies which helps a lot. CORDIC assumes only additions and shifts are possible and wouldn't directly benefit from multiplication. If I was going to go back and revisit these, I'd be looking harder at specially designed rational approximations that gave results roughly at the desired working precision. Quote:Or may be CORDIC was the right choice for old calculators with little ROM? CORDIC has the big advantage that is can produce trigonometric, inverse trigonometric, logarithmic, exponential, hyperbolic and interse hyperbolic functions using essentially the same algorithm. I.e. very code space efficient. This was vital for the older devices with tiny amounts of ROM. It really is difficult to foresee any other algorithms fitting into so few resources yet still providing such functionality. Pauli 

06012014, 07:32 PM
(This post was last modified: 06012014 07:37 PM by Thomas Klemm.)
Post: #6




RE: @Thomas Klemm > CORDIC Article
(06012014 12:12 PM)Paul Dale Wrote: CORDIC has the big advantage that is can produce trigonometric, inverse trigonometric, logarithmic, exponential, hyperbolic and inverse hyperbolic functions using essentially the same algorithm. In addition to that it can also produce the square root: Quote:\((w)^{1/2}=(x^2y^2)^{1/2}\) where \(x=w+\frac{1}{4}\) and \(y=w\frac{1}{4}\)It would never have occurred to my mind that this could be used. Solely for this idea it was worth reading the paper [1]. Cheers Thomas [1] A Unified Algorithm for Elementary Functions 

06012014, 07:48 PM
Post: #7




RE: @Thomas Klemm > CORDIC Article
I did a few checks here and there on the net. Cordic is indeed the right choice for its small foot print in memory and also very little CPU cost  some say it costs as much as a multiplication while other methods would require a lot of multiplications...


06012014, 08:28 PM
(This post was last modified: 06012014 10:15 PM by pito.)
Post: #8




RE: @Thomas Klemm > CORDIC Article
Quote:What is the most efficient approach in terms of speed and accuracy between CORDIC and Taylor? The cordic was the choice with early calculators which had 14kBytes of rom (and fully different architecture as it is today, ie. my HP25 with 2kx10bit of rom  see the disassembled rom at http://www.jacqueslaporte.org/Woodstock...s/hp25.txt). I did some benchmarks in past on cortex M3 (32bit cordic vs. single precision) where I set the cordic's Niterations such I get similar results as with single precision and the timing difference was not dramatic. The Taylor does not need too many terms to get required precision. You may try the 32bit cordic (ready code to run): http://www.dcs.gla.ac.uk/~jhw/cordic/ Today the cordic algorithms are mostly used in FPGA or ASIC designs  there are sources in VHDL/Verilog available  it is the implementation in hardware which is _very_ fast. Also mind the WP34s is using decNumber library with arbitrary lenght decimal floating point (set to maybe 34 digits or more for trigo), which is not the same as the IEEE double precision (or single precision). On the ARM a single precision (32bit, 67digits precision) calculation is typically twice faster than the double precision (64bit, 1415digits), and a 34digits decimal floating point is maybe 1015x slower than the double precision.. 

06022014, 06:39 PM
Post: #9




RE: @Thomas Klemm > CORDIC Article
(05312014 08:00 PM)Tugdual Wrote: Could be a good idea to extend the article to all the possibilities of CORDIC? Due to your request I have attached a Python program with examples from the paper to the article. Cheers Thomas 

06022014, 08:47 PM
Post: #10




RE: @Thomas Klemm > CORDIC Article
(06012014 08:28 PM)pito Wrote: Also mind the WP34s is using decNumber library with arbitrary lenght decimal floating point (set to maybe 34 digits or more for trigo), which is not the same as the IEEE double precision (or single precision). We're using 39 digits as the standard internal precision, and, as you correctly point out, many more digits for some modulo operations used in trig functions. XROM code (internal key stroke programs) are limited to 34 digits. Marcus von Cube Wehrheim, Germany http://www.mvcsys.de http://wp34s.sf.net http://mvcsys.de/doc/basiccompare.html 

06022014, 10:13 PM
(This post was last modified: 06022014 10:14 PM by pito.)
Post: #11




RE: @Thomas Klemm > CORDIC Article
Quote:We're using 39 digits as the standard internal precision..Therefore I've ordered the 30b today  I've always been interested to have a pocket calculator which returns 9.0 with the 9 degree trigo test 

06022014, 10:26 PM
(This post was last modified: 06022014 10:26 PM by Paul Dale.)
Post: #12




RE: @Thomas Klemm > CORDIC Article
(06022014 10:13 PM)pito Wrote: Therefore I've ordered the 30b today  I've always been interested to have a pocket calculator which returns 9.0 with the 9 degree trigo test The 34S returns 9.000000000029361 in single precision mode which is the proper correctly rounded result. It returns 8.999999999999999999999999999937535 in double precision, I don't know if this is correctly rounded or not.  Pauli 

06022014, 10:53 PM
Post: #13




RE: @Thomas Klemm > CORDIC Article
As seen on Wikipedia
Quote:For most numerical calculations involving π, a handful of digits provide sufficient precision. According to Jörg Arndt and Christoph Haenel, thirtynine digits are sufficient to perform most cosmological calculations, because that is the accuracy necessary to calculate the volume of the known universe with a precision of one atom.We're still missing 5 digits to rule the universe with the 34s :( 

06022014, 10:58 PM
(This post was last modified: 06022014 11:09 PM by pito.)
Post: #14




RE: @Thomas Klemm > CORDIC Article
You have to be able to calculate the volume of the visible Universe with a precision of the Planck lenght, I would say.. Or better..


06022014, 11:05 PM
Post: #15




RE: @Thomas Klemm > CORDIC Article
Quote:It returns 8.999 999 999 999 999 999 999 999 999 937 535 in double precision, I don't know if this is correctly rounded or not.With 3439digits (or more with trigo) precision set in decNumber library you have to get better result with 9deg test. 

06022014, 11:08 PM
Post: #16




RE: @Thomas Klemm > CORDIC Article
(06022014 11:05 PM)pito Wrote: With 3439digits (or more with trigo) precision set in decNumber library you have to get better result with 9deg test. Why? Rounding in this case is to 34 digits at each step. Feel free to recode the 34S trigonometric functions if you think you can do better. We accept code donations  Pauli 

06022014, 11:13 PM
Post: #17




RE: @Thomas Klemm > CORDIC Article
(06022014 11:08 PM)Paul Dale Wrote:So you accept code but not PDF donation?(06022014 11:05 PM)pito Wrote: With 3439digits (or more with trigo) precision set in decNumber library you have to get better result with 9deg test. OOps sorry, I stop before Katie bans me :) 

06022014, 11:20 PM
Post: #18




RE: @Thomas Klemm > CORDIC Article
Maybe it depends on how you calculate the trig functions  do you iterate Taylor against an epsilon smaller than set precision? I did it that way with decNumber (long time back though) and afaik the results were precise to the last digit.


06022014, 11:42 PM
Post: #19




RE: @Thomas Klemm > CORDIC Article
(06022014 11:20 PM)pito Wrote: Maybe it depends on how you calculate the trig functions  do you iterate Taylor against an epsilon smaller than set precision? I did it that way with decNumber (long time back though) and afaik the results were precise to the last digit. Yes, this is what is used for SIN, COS. I will change this in the 43S, naïve Taylor series expansions aren't ideal for fixed precision results. It won't necessarily be precise to the last digit however. Consider COS(PI/2ULP). The Taylor series for COS(x) starts 1  x^2/2 + ... The import thing is the leading 1. Since COS(PI/2ULP) is very very close to zero, the Taylor expansion is subtracting almost 1 from 1 which causes quite a number of lost digits. This can be mitigated of course but you have to realise it is happening.  Pauli 

06032014, 02:02 PM
(This post was last modified: 06032014 02:03 PM by pito.)
Post: #20




RE: @Thomas Klemm > CORDIC Article
I've flashed my CM3 with the old stuff I've found  when running below code with 34digits I get (I've added your result for comparison):
Code: TRIG9 Code: #define _PI "3.1415926535897932384626433832795028841971693993751" But I've learned you do rounding after each calculation so maybe that is what makes the diff.. 

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