7

I've found in 'addons/math/misc/brent.ijs' implementation of Brent's method as an adverb. I would like to build a Newton's method as an adverb too but it's much harder than building tacit verbs.

Here is a explicit version of Newton's iteration:

   newton_i =: 1 : '] - u % u d.1'

With such usage:

   2&o. newton_i^:_ (1) NB. (-: 1p1) must be found
1.5708
   2 o. 1.5708 NB. after substitution we get almost 0
_3.67321e_6

And of course, for convenience:

    newton =: 1 : 'u newton_i^:_'

What's a tacit equivalent?

  • I think d. prevents you from writing a tacit adverb in this case. – Eelvex Nov 1 '14 at 15:40
  • 2
    The short answer is n_i =: d.0 1 (%/@:) (-`) (]`) (`:6) and newton =: n_i (^:_). I'll come back and explain why later (I'm on a phone right now). – Dan Bron Nov 3 '14 at 12:56
  • @DanBron, Thank you very much! I've understood everything with help of your message link except why (-`) (]`) (`:6) not (]`) (-`) (`:6) for building ] - f fork. – Dan Oak Nov 3 '14 at 16:35
  • 1
    Danylo: because adverb trains are built up from left-to-right (i.e. LIFO); think of f (d.0 1) (%/@:) as a black-box that builds up (effectively) (f % f d.1); well then you've got black_box (`-) (`]), which, read in reverse (LIFO), reads ],-,black_box, which then gets executed into the train ] - black_box. No, the real sneaky trick here was using d.0 1 :) . Does that clear it up, or would you still like me to post a formal answer? – Dan Bron Nov 3 '14 at 18:16
  • Dan, I've completely understood f (d.0 1) (%/@:) trick :) - it's cool indeed: we calculate zeroth and first derivatives of f and then insert % between them. I've understood the order in which you've written these three adverbs as well. Thank you very much! – Dan Oak Nov 3 '14 at 18:44
6

TL;DR

Per the comments, a short answer; the tacit equivalent to the original, explicit newton_i and newton are, respectively:

n_i =: d.0 1 (%/@:) (]`-`) (`:6) 
newton =: n_i (^:_)

Some techniques for how such translations are obtained, in general, can be found on the J Forums.

Construction

The key insights here are that (a) that a function is identical to its own "zeroeth derivative", and that (b) we can calculate the "zeroeth" and first derivative of a function in J simultaneously, thanks to the language's array-oriented nature. The rest is mere stamp-collecting.

In an ideal world, given a function f, we'd like to produce a verb train like (] - f % f d. 1). The problem is that tacit adverbial programming in J constrains us to produce a verb which mentions the input function (f) once and only once.

So, instead, we use a sneaky trick: we calculate two derivatives of f at the same time: the "zeroth" derivative (which is an identity function) and the first derivative.

   load 'trig'
   sin              NB. Sine function (special case of the "circle functions", o.)
1&o.

   sin d. 1 f.      NB. First derivative of sine, sin'.
2&o.

   sin d. 0 f.      NB. "Zeroeth" derivative of sine, i.e. sine.
1&o."0

   sin d. 0 1 f.    NB.  Both, resulting in two outputs.
(1&o. , 2&o.)"0

   znfd =: d. 0 1   NB. Packaged up as a re-usable name.
   sin znfd f.
(1&o. , 2&o.)"0

Then we simply insert a division between them:

   dh =: znfd (%/@) NB. Quotient of first-derivative over 0th-derivattive

   sin dh
%/@(sin d.0 1)

   sin dh f.
%/@((1&o. , 2&o.)"0)

   sin dh 1p1  NB. 0
_1.22465e_16

   sin 1p1     NB. sin(pi) = 0
1.22465e_16
   sin d. 1 ] 1p1  NB. sin'(pi) = -1
_1
   sin dh 1p1  NB. sin(pi)/sin'(pi) = 0/-1 = 0
_1.22465e_16

The (%/@) comes to the right of the znfd because tacit adverbial programming in J is LIFO (i.e. left-to-right, where as "normal" J is right-to-left).

Stamp collecting

As I said, the remaining code is mere stamp collecting, using the standard tools to construct a verb-train which subtracts this quotient from the original input:

   ssub  =: (]`-`) (`:6)     NB. x - f(x)

   +: ssub                   NB. x - double(x)
] - +:
   -: ssub                   NB. x - halve(x)
] - -:

   -: ssub 16                NB. 16 - halve(16)
8
   +: ssub 16                NB. 16 - double(16)
_16
   *: ssub 16                NB. 16 - square(16)
_240
   %: ssub 16                NB. 16 - sqrt(16)
12

Thus:

    n_i =: znfd ssub         NB. x - f'(x)/f(x)

And, finally, using "apply until fixed point" feature of ^:_, we have:

    newton =: n_i (^:_)

Voila.

  • 1
    Very nice method and solution. – Eelvex Nov 4 '14 at 20:45
  • @DanBron, I have added to your answer my explanation as I've understood. Have you received it? – Dan Oak Nov 5 '14 at 15:55
  • @Danylo, I did not, maybe it was rejected by other users before I was notified? Do you want to add an answer that I can copy-paste from? – Dan Bron Nov 5 '14 at 18:00
  • @DanBron, no, I'm too lazy. Your explanation here is great. – Dan Oak Nov 7 '14 at 8:39
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    Also, note that this can quite easily extend to functions of more variables with: n_i =: D.0 1 (%./@:) (]`-`) (`:6) – jpjacobs Nov 18 '14 at 21:25
1
 newton_i =: 1 : '] - u % u d.1'

is semi-tacit, in that a tacit verb results when it is bound with a verb (the adverb disappears when bound).

 newton_i2 =: 1 : '(] - u % u d.1) y'

is full-explicit in that binding with a verb does not resolve the adverb.

 + 1 : 'u/'

+/

 + 1 : 'u/ y'

+ (1 : 'u/ y')

There is no huge importance to making semi-tacit adverbs fully tacit, as there may be no performance gains, and it has the same benefit of being resolved within the adverbs locale rather than in callers (the case for fully explicit adverbs).

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